Welding Manual Nov 2010

February 14, 2017 | Author: Sumit Chaurasia | Category: N/A
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2

INDEX Sl.No. 01 02 03 04 05 06 07 A-1 A-2 A-3 A-4 A-5 A-6 A-7

B-1 B-2

Description Cover Sheet Index Preface Foreword Approval Sheet Important Note Status of Amendments Welding - General Base Materials Welding Material Specification and Control Procedure for Welder Qualification Inspection of Welding Repair Welding Safe Practices in Welding Pre-Assembly & Welding of Ceiling Girders Pre-Assembly of High Crown Plates Erection Welding Practice for SA 335 P91 Material

Page No. 01 02 03 04 05 06 07 08 15 24 49 66 70 72 78 94 95

Argon Purity Level Use of resistance heating for PWHT of P-91 pipes General Tolerances for welding structures - (Form and position) (Doc. Ref. : AA0621105) Welding of pipes and pipes shaped connections in Steam Turbines, Turbo-Generators and Heat Exchangers (HW0620599) Instructions for carrying out condenser plate and neck welding Repair procedure of arresting the leakage of strength welds on tube to tube sheet joints of „U‟ tube HP heater Repair procedure of grey cast iron castings Special Instructions for the repair of Steam Turbine Casings Gas Metal Arc Welding Orbital Welding Edge Preparation Details Erection Procedure for Rear Water box and Rear water Chamber in condenser

115 117 121

B-13

Welding & HT details of thermo couple pads & clamps for SH & RH

170

B-14 B-15

Welding and PWHT sequence for lower ring header Demagnetization Procedure

172 174

B-16

Erection Welding Practice for SA 213 T91 Material

175

B-17

Selection Chart for Dummy end Covers for Hydraulic test / Nipples Free end Details (BHEL-Trichy)

182

B-18

Schedule of Pipes

185

B-3 B-4 B-5 B-6 B-7 B-8 B-9 B-10 B-11 B-12

125 128 132 135 139 146 150 161 164

3

5

6

IMPORTANT THIS WELDING MANUAL PROVIDES BROAD BASED GUIDELINES FOR WELDING WORK AT SITES. HOWEVER, SITES MUST ENSURE ADHERENCE TO THE PRIMARY DOCUMENTS LIKE CONTRACT DRAWINGS, ERECTION WELDING SCHEDULE, STATUTORY

PLANT

/

CORPORATE

DOCUMENTS,

STANDARDS,

WELDING

WHEREVER

PROCEDURE

SUPPLIED,

SPECIFICATIONS,

CONTRACTUAL OBLIGATIONS, IF ANY AND SPECIAL INSTRUCTIONS ISSUED BY RESPECTIVE MANUFACTURING UNITS SPECIFIC TO THE PROJECT.

WELDING MANUAL

A1. WELDING-GENERAL

STATUS OF AMENDMENTS

Sl.No.

Reference of Sheet(s) Amended

Amendment No. & Date

Remarks

7

WELDING MANUAL

A1. WELDING-GENERAL

CHAPTER – A1 WELDING - GENERAL

8

WELDING MANUAL

A1. WELDING-GENERAL

9

WELDING-GENERAL 1.0

SCOPE: This manual deals with activities and information related to welding for site operations including P91 material. Where specific documents are supplied by the manufacturers, the same shall be adopted.

2.

DOCUMENTS REFERRED:

2.1 The following documents are referred in preparation of this manual.

3.

1.

AWS D1.1

2.

ASME sections I, II (A&C), V & IX

3.

ASME B31.1

4.

IBR

5.

BHEL Manufacturing Units‟ Standards & practices

PROCEDURE:

3.1 The following documents shall be referred as primary documents -

Contract drawings

-

Erection Welding Schedule or equivalent

-

Plant / Corporate standards, where supplied

-

Statutory documents

-

Welding Procedure Specifications

-

Contractual obligations, if any.

3.2

Welder Qualification:

3.2.1

Ensure, personnel qualified as per statutory requirements are engaged, where required.

3.2.2

For welding not under the purview of statutory requirements, qualification of welders shall be as in this manual.

3.3

Monitor performance of qualified butt welders as in this manual.

3.4

3.4.1

Ensure selection, procurement, storage, drying & issue of welding consumables, as detailed in this manual. List of approved vendors of general purpose welding electrodes as provided by BHEL, Tiruchy Unit shall be used for selection of brands at sites . Alternatively specific contractual requirements, if any may be followed.

WELDING MANUAL

A1. WELDING-GENERAL

10

3.4.1.1 Where Tiruchy list does not cover site requirements, such specific cases may be referred

to concerned unit and Head(Qly) of the region. 3.5

Welding in-charge shall assign a unique identification for all the butt welds coming under the purview of statutory regulations. Such identification may be traceable through documents like drawings, sketches etc.

3.5.1

A welding “job card” incorporating the welding parameters and heat treatment requirements is recommended to be issued for all critical welds like pressure part welds, piping welds, ceiling girder welds. A format of the job card is enclosed for illustration.

3.6

Heat Treatment:

3.6.1

Preheat, inter pass, post heat and Post Weld Heat Treatment (PWHT) requirements shall be as per applicable documents; where these are not supplied, reference may be made to Welding / Heat Treatment Manual.

3.6.2

Prior to PWHT operation, a “job card” containing material specification, weld reference, size, rate of heating, soaking temperature, soaking time and rate of cooling shall be prepared referring to applicable documents, and issued.

3.6.3

The PWHT chart shall contain the chart number, Weld Joint No., Temperature recorder details (like Sl.No., make, range, chart speed) , date of PWHT, start and end time of operation .

3.6.4

The chart shall be evaluated and results recorded on the PWHT job card. Refer Heat Treatment Manual (Document No. PSQ-HTM-COM) for details.

3.7

Equipment & Instruments:

3.7.1

Equipment/accessories used shall be assessed for fitness prior to use.

3.7.2

Use calibrated temperature recorders.

3.7.3

Thermal chalks shall be batch tested prior to use.

3.8

Inspection:

3.8.1

Inspection of welding may be done as per Chapter A5 and records maintained as appropriate.

WELDING MANUAL

3.8.2

A1. WELDING-GENERAL

11

Weld log containing the following information shall be prepared for all completed systems. -

Project / Unit reference

-

Drawing No.

-

Weld Joint No.

-

EWS / Equivalent

-

Material specification

-

Welder code

-

Date of welding

-

NDE report No. and results (including repair details)

-

PWHT Chart No. and results

-

Remarks, if any.

3.9

Safety:

3.9.1

Safe access to weld area shall be provided.

3.9.2

Adequate protection shall be provided against excessive wind and rain water entry during welding.

3.10

Records:

3.10.1 All records, as required, shall be maintained by welding in-charge.

A1. WELDING-GENERAL

WELDING MANUAL

WELDING JOB CARD WELDING JOB CARD Page 1 of 2 Project

:

Unit No.

:

Area: Boiler / TG / PCP

Job Card No.

:

Date:

Joint No.

:

Drawing No.

:

System Description

:

Size (Dia. x thick)

:

Material Specification

:

Welder No.(s)

:

Date of welding

:

Filler wire Specification

:

Electrode Specification

:

Preheat temperature

:

Inter pass temperature

:

Post Heat temperature

:

PWHT temperature

: Welding Engineer Page 2 of 2

FILLER WIRE / ELECTRODE CONSUMPTION GTAW Filler wire

:

SMAW  2.5 mm

:

 3.15 mm

:

 4.0 mm

:

Date of LPI for RG Plug

:

Remarks

:

Date of Return

:

12

13

A1. WELDING-GENERAL

WELDING MANUAL

JOB CARD (WELDING, HEAT TREATMENT & ND EXAMINATION) FOR P91 WELDS Card No.: Project : System:

Date: Unit No. Contractor: Drawing No.

PGMA: Material Specification: Filler GTAW metal: Joint fit-up:

+

Joint No.:

OD (mm):

Thick(mm)

SMAW Root gap:

Min. WT:

No. of T/Cs:

DU No.:

Location :

Root mismatch:

Log sheet filled:

Distance from EP edge:

Welders‟ ID: C Minimum Litres / min.

Purging time:

 C Maximum

Holding Temp.:

 C for min. 1 hour. for post heating

PWHT:

C

Soaking time

Minutes (2.5 minutes per mm) Cooling to:

Preheating started at

Hrs. on

Litres / min. for GTAW

Root welding started at

Distance bet. dams:

Metres C per hour C per hour

Rate of heating / cooling:

Interpass temp. maintained between

Hrs.

Hrs.

Welding completed at

Hrs.

C

Holding completed at

.

Hrs.

Root welding completed at C and

Hrs.

Hrs. on

300 C

Preheating completed at

Hrs.

Soaking completed at

Minutes

Rate of cooling:

Hrs.

Holding temp. reached at Location No. of T/Cs: :

C per hour

Rate of heating:

Purging flow rate: Shielding flow rate: Interpass Temp.:

PWHT started at

mm

M/c No.:

Preheat Temp.:

Welding started at

Y/N

Soaking started at . 300C reached at

UT Equipment used:

Calibration validity:

UT carried out on

Result : OK / Not OK

MPI Equipment used:

Calibration validity:

MPI carried out on

Result: OK / Not OK

Hardness test Equipment used:

Calibration validity:

Hardness test carried out on

Value:

Hrs.

Hrs. Hrs.

History of interruption if any, with time: Contractor

BHEL

Customer

14

A1. WELDING-GENERAL

WELDING MANUAL

JOB CARD (WELDING, HEAT TREATMENT & ND EXAMINATION) FOR T91 WELDS Date: Unit No. Contractor: Drawing No.

Card No.: Project :System: PGMA:

Material Specification: Filler GTAW metal: Joint fit-up:

+

Joint No.:

OD (mm):

Thick(mm)

SMAW Root gap:

Min. t:

No. of T/Cs:

DU No.:

Location :

Root mismatch:

Log sheet filled:

Distance from EP edge:

Welders‟ ID: C Minimum Litres / min.

Purging time:

 C Maximum

Holding Temp.:

 C for min. 1 hour. for post heating

PWHT:

C

Soaking time

Minutes (2.5 minutes per mm) Cooling to:

Preheating started at

Hrs. on

Litres / min. for GTAW

Root welding started at

Distance bet. dams:

Metres C per hour C per hour

Rate of heating / cooling:

Interpass temp. maintained between

Hrs.

Hrs.

Welding completed at

Hrs.

C

Holding completed at

.

Hrs.

Root welding completed at C and

Hrs.

Hrs. on

300 C

Preheating completed at

Hrs.

Soaking completed at

Minutes

Rate of cooling:

Hrs.

Holding temp. reached at Location No. of T/Cs: :

C per hour

Rate of heating:

Purging flow rate: Shielding flow rate: Interpass Temp.:

PWHT started at

mm

M/c No.:

Preheat Temp.:

Welding started at

Y/N

Soaking started at . 300C reached at

UT Equipment used:

Calibration validity:

UT carried out on

Result : OK / Not OK

MPI Equipment used:

Calibration validity:

MPI carried out on

Result: OK / Not OK

Hardness test Equipment used:

Calibration validity:

Hardness test carried out on

Value:

Hrs.

Hrs. Hrs.

History of interruption if any, with time: Contractor

BHEL

Customer

WELDING MANUAL

A2 BASE MATERIALS

CHAPTER – A2 BASE MATERIALS

15

WELDING MANUAL

A2 BASE MATERIALS

BASE MATERIALS 1.0

SCOPE:

1.1 This chapter contains tabulations of chemical compositions and mechanical properties of various materials generally used in BHEL sites. 2.0

CONTENTS: CHEMICAL COMPOSITION AND MECHANICAL PROPERTIES Table A2.1 -

Pipes (ASME)

Table A2.2 -

Tubes (ASME)

Table A2.3 -

Forgings (ASME)

Table A2.4 -

Castings (ASME)

Table A2.5 -

Plates / Sheets (ASME)

Table A2.6 -

Pipes (Other specifications)

Table A2.7 -

Tubes (Other specifications)

3.0

The data are for general information purposes. The corresponding P numbers are also indicated.

4.0

For materials not covered in this chapter, the supplier shall be contacted.

16

WELDING MANUAL

17

Table- A2.1 Pipes Chemical Composition (%) Sl. P.No. / No. Group No.

Material Specification

SA 106 Gr. B (Remarks: Carbon 1 P1/1 restricted to CHEMICAL COMPOSITION 0.25% Max.)

Mechanical Properties (Min.) T.S Y.S Kg / Kg / %E mm2 mm2 Min. (MPa) (MPa)

C

Mn

P

S

Si

Ni

Cr

Mo

V

0.30 Max.

0.29-1.06

0.035 Max.

0.035 Max.

0.10 Min.

0.40 Max.

0.40 Max.

0.15 Max.

0.08 Max

42(415)

25(240)

30

AND MECHANICAL PROPERTIES

SA 106 Gr. C (Remarks: Carbon restricted to 0.25% Max.)

0.35 Max.

0.291.06

0.035 Max.

0.035 Max.

0.10 Min.

0.40 Max.

0.40

0.15 Max.

-

49(485)

28(275)

30

SA 335 P 12

0.15 Max.

0.300.61

0.025 Max.

0.025 Max.

0.50 Max.

-

0.801.25

0.440.65

-

42(415)

21(220)

30

P 5A / 1

SA 335 P 22

0.15 Max.

0.300.60

0.025 Max.

0.025 Max.

0.50 Max.

-

1.902.60

0.871.13

-

42(415)

21(205)

30

P 15E /1

SA 335 P91

0.080.12

0.300.60

0.02 Max.

0.01 Max.

0.200.50

0.40 Max.

8.009.50

0.851.05

0.18-0.25

60(585)

42(415)

20

2

P1/2

3

P4/1

4 5

WELDING MANUAL

18

Table-A2.2 Tubes Chemical Composition (%)

Mechanical Properties (Min.) T.S Y.S %E Kg / mm2 Kg / mm2 Min. (MPa) (MPa)

Sl. No.

P.No. / Group No.

Material Specification (ASME)

C

Mn

P

S

Si

Ni

Cr

Mo

1

P1/1

SA 192

0.06-0.18

0.27-0.63

0.035 Max.

0.035 Max.

0.25 Max.

-

-

-

33(325)

18(180)

35

2

P1/1

(Remarks: Carbon restricted to 0.25% Max.)

0.27 Max.

0.93 Max.

0.035 Max.

0.035 Max.

0.10 Max.

-

-

-

42(415)

26(255)

30

3

P1/1

SA 179

0.06-0.18

0.27-0.63

0.035 Max.

0.035 Max.

-

-

-

-

33(325)

18(180)

35

4

P1/2

(Remarks: Carbon restricted to 0.30% Max.)

0.35 Max.

0.29- 1.06

0.035 Max.

0.035 Max.

0.10 Max.

-

-

-

49(485)

28(275)

30

5

P3/1

SA 209 T1

0.10- 0.20

0.30- 0.80

0.025 Max.

0.025 Max.

0.10- 0.50

-

-

0.44-0.65

39(380)

21(205)

30

6

P4/1

SA 213 T11

0.05-0.15

0.30-0.60

0.025 Max.

0.025 Max.

0.50-1.00

-

1.001.50

0.44-0.65

42(415)

21(205)

30

7

P4/1

SA 213 T12

0.05-0.15

0.30-0.61

-

0.44- 0.65

42(415)

22(220)

30

P5A/1

SA 213 T22

0.05-0.15

0.30-0.60

0.025 Max. 0.025 Max.

0.50 Max.

8

0.025 Max. 0.025 Max.

0.50 Max.

-

0.87- 1.13

42(415)

21(205)

30

9

P5B/1

SA 213 T5

0.15 Max.

0.30-0.60

0.025 Max.

0.025 Max.

0.50 Max.

-

4.006.00

0.45- 0.65

42(415)

21(205)

30

10

P5B/1

SA 213 T9

0.15 Max.

0.30-0.60

0.025 Max.

0.025 Max.

0.25-1.00

-

8.0010.00

0.90- 1.10

-

42(415)

21(205)

30

11

P15E/1

SA 213 T91

0.07- 0.14

0.30- 0.60

0.02 Max.

0.01 Max.

0.20- 0.50

0.40 Max.

8.009.50

0.85- 1.05

0.180.25

60(585)

42(415)

20

12

P8/1

SA 213 TP 304 H

0.04- 0.10

2.00 Max.

0.045 Max.

0.03 Max.

1.00 Max.

8.0011.00

18.00 20.00

-

-

53(515)

21(205)

35

13

P8/1

SA 213 TP 347 H (Cb + Ta Stabilised)

0.04- 0.10

2.00 Max.

0.045 Max.

0.03 Max.

1.00 Max.

9.0013.00

17.00 19.00

-

-

53(515)

21(205)

35

SA 210 Gr A1

SA 210 Gr C

0.801.25 1.902.60

V

WELDING MANUAL

19

Table A2.3 Forgings Chemical Composition (%) Sl. No.

P.No. / Group No.

1

P1/2

2

P4/1

3

P4/1

4

P5A/1

5

P15E/1

Material Specification SA 105 (Remarks: Carbon restricted to 0.25% Max.) SA 182 F11 Class 3 SA 182 F 12 Class 2 SA 182 F 22 Class 3 SA 182 F91

Mechanical Properties (Min.) T.S Y.S %E Kg / mm2 Kg / mm2 Min. (MPa) (MPa)

C

Mn

P

S

Si

Ni

Cr

Mo

V

0.35 Max.

0.601.05

0.035 Max.

0.04 Max.

0.10.35.

0.40 Max.

0.30 Max.

0.12 Max.

0.08 Max

49(485)

25(250)

30

0.100.20

0.300.80

-

1.001.50

0.44-0.65

-

49(515)

28(310)

20

0.30-0.80

0.10-0.60

-

0.80-1.25

0.44-0.65

-

49(485)

28(275)

20

0.15 Max.

0.30-0.60

0.50 Max.

-

2.00-2.50

0.87-1.13

-

53(515)

32(310)

20

0.08-0.12

0.30-0.60

0.04 Max. 0.04 Max. 0.04 Max. 0.01 Max.

0.501.00

0.10-0.20

0.04 Max. 0.04 Max. 0.04 Max. 0.02 Max.

0.20-0.50

0.40 Max.

8.00-9.50

0.85-1.05

0.18-0.25

60(585)

42(415)

20

WELDING MANUAL

20

Table A2.4 Castings Chemical Composition (%) Sl. No.

P.No. / Group No.

Material Specification (ASME)

1

Mechanical Properties (Min.) T.S Y.S %E Kg / mm2 Kg / mm2 Min. (MPa) (MPa)

C

Mn

P

S

Si

Ni

Cr

Mo

P1/2

SA 216 WCB (Remarks: Carbon restricted to 0.25% Max.)

0.30 Max.

1.00 Max.

0.04 Max.

0.045 Max.

0.60 Max.

0.50 Max.

0.50 Max.

0.20 Max.

49(485)

25(250)

22

2

P1/2

SA 216 WCC

0.25 Max.

1.20 Max.

0.04 Max.

0.60 Max.

0.50 Max.

0.50 Max.

0.20 Max.

49(485)

28(275)

22

3

P4/1

SA 217 WC6

0.20 Max.

0.50-0.80

0.04 Max.

0.60 Max.

-

1.00-1.50

0.45-0.65

49(485)

4

P5A/1

SA 217 WC 9

0.18 Max.

0.40-0.70

0.04 Max.

0.60 Max.

-

2.00-2.75

0.90-1.20

49(485)

28(275)

20

5

P8/1

SA 351 CF 8

0.08 Max.

1.50 Max.

0.04 Max.

0.04 Max.

2.00 Max.

49(485)

21(205)

35

P8/1

SA 351 CF 8M

0.08 Max.

1.50 Max.

0.04 Max.

0.04 Max.

1.50 Max.

2.00- 3.00

49(485)

21(205)

30

7

P8/1

SA 351 CF 8C

0.08 Max.

1.50 Max.

0.04 Max.

0.04 Max.

2.00 Max.

0.50 Max.

49(485)

21(205)

30

8

P8/2

SA 351 CH 20

0.04-0.20

1.50 Max.

0.04 Max.

0.04 Max.

2.00 Max.

18.0021.00 18.0021.00 18.0021.00 22.0026.00

0.50 Max.

6

8.0011.00 9.0012.00 9.0012.00 12.0015.00

0.50 Max.

49(485)

21(205)

30

0.045 Max. 0.045 Max. 0.045 Max.

28(275)

20

WELDING MANUAL

21

Table A2.5 Plates / Sheets Chemical Composition (%) Sl. No.

P.No. / Group No.

Material Specification

1

P1/1

2

Mechanical Properties (Min.) T.S Y.S %E Kg / mm2 Kg / mm2 Min. (MPa) (MPa)

C

Mn

P

S

Si

Ni

Cr

Mo

V

SA 36

0.25-0.29

0.80-1.20

0.04

0.05

0.40 Max.

-

-

-

-

-

-

-

P1/1

SA 516 Gr 60

0.21-0.27

0.55-1.30

0.13-0.45

-

-

-

-

53(415)

21(220)

25

3

P1/2

SA 516 Gr 70

0.13-0.45

-

-

-

-

49(485)

27(260)

21

4

P1/2

SA 299

0.13-0.45

-

-

-

-

53(515)

5

P1/2

SA 515 Gr 70

0.13-0.45

-

-

-

-

49(485)

27(260)

21

6

P4/1

0.13-0.45

-

0.74-1.21

0.40-0.65

-

46(450)

28(275)

22

7

P5A/1

0.50 Max.

-

1.88-2.62

0.85-1.15

-

52(515)

32(310)

18

8

7.90-9.60

0.80-1.10

0.16-0.27

60(585)

42(415)

18

9

0.035 Max. 0.035 Max. 0.035 Max. 0.035 Max. 0.035 Max. 0.035 Max. 0.012 Max. 0.03 Max. 0.050 Max. 0.045 Max. 0.040 Max. 0.045 Max.

18.0020.00

-

-

53(515)

21(205)

40

0.025 Max.

SA 387 Gr 12 Class 2 SA 387 Gr 22 Class 2

0.31 Max. 0.30 Max. 0.35 Max. 0.17 Max. 0.15 Max.

P15E/1

SA 387 Gr 91

0.06-0.15

0.25-0.66

P8/1

SA 240 TYPE 304

0.08 Max. 0.23 Max. 0.22 Max. 0.20 Max. 0.20 Max.

2.00 Max. 1.50 Max. 1.50 Max. 1.50 Max. 1.60 Max.

0.035 Max. 0.035 Max. 0.035 Max. 0.035 Max. 0.035 Max. 0.035 Max. 0.025 Max. 0.045 Max. 0.050 Max. 0.045 Max. 0.040 Max. 0.045 Max.

0.20 Max.

1.0-1.7

0.03 Max

10

IS 2062 Gr.A

11

IS 2062 Gr.B

12

IS 2062 Gr.C

13

IS 8500-540

14

BSEN10025Gr 420N

0.79-1.30 0.84-1.62 1.30 Max. 0.35-0.73 0.25-0.66

29(275)

19

0.75 Max.

0.43 Max. 8.0010.50

-

-

-

-

-

42

25

23

-

-

-

-

42

25

23

-

-

-

-

42

25

23

-

-

-

-

55

40

20

0.80 Max.

0.30 Max.

0.10 Max.

0.20 Max.

(500-650

320-420

1819

0.18-0.56

0.40 Max. 0.40 Max. 0.45 Max. 0.60 Max.

WELDING MANUAL

22

Table-A2.6 Pipes (Other Specifications) Sl. No.

P.No. / Group No.

Material Specification

1

P1/1

DIN St. 35.8

2

P1/1

DIN St. 45.8

3

P1/1

BS 3602 / 410

4

P1/1

BS 3602 / 460

5

P4/1

6

P5/1

7

-

8

P5B / 2

BS 3604 620-460 HFS or CDS 620-440 BS 3604 622 HFS or CDS BS 3604 HFS 660 Or CDS 660 X20CrMoV121 DIN17175

Chemical Composition (%) C

Mn

P

S

0.17 Max. 0.21 Max. 0.21 Max. 0.22 Max.

0.400.80

0.04 Max. 0.04 Max. 0.045 Max. 0.045 Max. 0.04 Max. 0.04 Max.

0.04 Max. 0.04 Max. 0.045 Max. 0.045 Max. 0.04 Max. 0.04 Max.

0.45-1.20 0.40-1.20 0.80-1.40

Si

Ni

Cr

Mo

V

0.10-0.35

-

-

-

-

0.10-0.35

-

-

-

-

-

-

-

-

-

-

-

-

0.10-0.35

-

0.70-1.10

0.45-0.65

-

0.100.35

-

0.70-1.10

0.450.65

-

0.35 Max. 0.35 Max.

0.10-0.15

0.40 Max.

0.10-0.18

0.40-0.70

0.080.15

0.400.70

0.04 Max.

0.04 Max.

0.50 Max.

-

2.00 2.50

0.901.20

-

0.15 Max.

0.400.70

0.04 Max.

0.04 Max.

0.10-0.35

-

0.25-0.50

0.50-0.70

0.17-0.23

 1.00

0.030 Max.

0.030 Max.

 0.50

0.30-0.80

10.0012.50

0.80-1.20

Mechanical Properties (Min.) T.S Y.S %E Kg / mm2 Kg / mm2 Min. 36.7024 25 48.96 41.8026 21 54.10 41.8225 22 56.10 46.9028.60 21 61.20 46.9018.36 22 62.22 44.9029.58 22 60.20 48.80

26.80

17

0.22-0.30

47.30

30

17

0.25-0.35

70-86

50

17

WELDING MANUAL

23

Table-A2.7 Tubes Sl. No.

P.No. / Group No.

Material Specification

1

P1/1

DIN St. 35.8

2

P1/1

DIN St. 45.8

3

P1/1

BS 3059 / 360

4

P1/1

BS 3059 / 440

5

P3/1

6

P4/1

7

P4/1

8

P5/1

9

P5/1

10

P5/1

11

-

12

P5B / 2

15 Mo3 DIN17175 13 Cr Mo 44 DIN17175 BS 3059 / 620 10 Cr Mo 910 DIN17175 BS 3059 (622) 440 BS 3059 (622) 490 14 Mo V 63 DIN17175 X20CrMoV121 DIN17175

Chemical Composition (%) C

Mn

P

S

0.17 Max. 0.21 Max. 0.17 Max.

0.400.80 0.40-1.20

0.12-0.18

0.90-1.20

0.04 Max. 0.04 Max. 0.045 Max. 0.040 Max. 0.035 Max. 0.035 Max. 0.040 Max. 0.035 Max. 0.04 Max. 0.040 Max. 0.035 Max. 0.030 Max.

0.04 Max. 0.04 Max. 0.045 Max. 0.035 Max. 0.035 Max. 0.035 Max. 0.040 Max. 0.035 Max. 0.04 Max. 0.040 Max. 0.035 Max. 0.030 Max.

0.12-0.20 0.100.18 0.10-0.15

0.400.80

0.400.80 0.400.70 0.400.70

0.08-0.15

0.40-0.70

0.08-0.15

0.40-0.70

0.08-0.15

0.40-0.70

0.10-0.18

0.40-0.70

0.17-0.23

 1.00

Si

Ni

Cr

Mo

V

0.10-0.35

-

-

-

-

0.10-0.35

-

-

-

-

0.35 Max.

-

-

-

-

0.10-0.35

-

-

-

-

0.10-0.35

-

-

0.25-0.35

-

0.10-0.35

-

0.70-1.10

0.10-0.35

-

0.70-1.10

-

2.00-2.50

0.90-1.20

-

-

2.00-2.50

0.90-1.20

-

-

2.00-2.50

0.90-1.20

-

0.30-0.60

0.50-0.70

0.22-0.32

10.0012.50

0.80-1.20

0.25-0.35

0.50 Max. 0.50 Max. 0.50 Max. 0.10-0.35  0.50

0.30-0.80

Table- A2.7 Tubes (Other Specifications)

0.450.65 0.450.65

-

Mechanical Properties (Min.) T.S T.S %E Kg / mm2 Kg / mm2 Min. 36.7024 25 48.96 41.8026 21 54.06 36.7022 24 51.00 44.8825 21 59.20 45.9027.50 22 61.20 44.8829.60 22 60.18 46.9018.40 22 62.20 45.9028.60 20 61.20 44.9017.85 20 60.18 49.9828.05 20 65.00 46.9032.60 20 62.22 70-86

50

17

WELDING MANUAL

CHAPTER - A3 WELDING MATERIAL SPECIFICATION AND CONTROL

24

WELDING MANUAL

25

WELDING MATERIAL SPECIFICATION AND CONTROL 1.0

SCOPE: This chapter gives details for welding material specification and control at sites.

2.0

3.0

CONTENTS: 1.

Table- A3.1 - Weld Metal Chemical Composition.

2.

Table-A3.2 - Mechanical property requirement for all-weld metal.

3.

Receipt inspection of welding electrodes/filler wires.

4.

Storage and identification of welding electrodes/filler wires.

5.

Drying and holding of welding electrodes.

6.

Selection and issue of welding electrodes/filler wires.

7.

Table-A3.3 - Selection of GTAW filler wire, SMAW electrodes for butt welds in tubes, pipes, headers.

8.

Table-A3.4 - Selection of electrodes for welding attachments to tubes.

9.

Table-A3.5 - Selection of electrodes, preheat, PWHT for attachment to attachment welds.

10.

Table-A3.6 - Selection of electrodes for welding nozzle attachments, hand hole plate, RG plug etc. to headers, pipes.

11.

Table-A3.7 – Selection of filler wire and electrodes for non-pressure parts ( including structures )

12.

Table-A3.8 - A numbers

13.

Table-A3.9 - F numbers

14.

SFA Classification

For welding consumables not covered in this chapter, relevant details may be obtained from the Manufacturing Units.

WELDING MANUAL

26

Table – A3.1 WELD METAL CHEMICAL COMPOSITION Electrode E 6010 E 6013 E 7018 / E 7018-1 E 7018-A1 E 8018-B2 E 9018-B3 E 9015-B9 / E 9018-B9

SFA No.

Weight, % S Ni NS 0.30 NS 0.30

5.1 5.1

C 0.20 0.20

Mn 1.20 1.20

Si 1.00 1.00

P NS NS

5.1

0.15

1.60

0.75

0.035

0.035

5.5 5.5 5.5

0.12 0.05-0.12 0.05-0.12

0.90 0.90 0.90

0.80 0.80 0.80

0.03 0.03 0.03

5.5

0.08-0.13

1.20

0.30

0.01

Other Elements % Cr 0.20 0.20

Mo 0.30 0.30

V 0.08 0.08

Cu NS NS

0.30

0.20

0.30

0.08

NS

0.03 0.03 0.03

NS NS NS

0.40-0.65 0.40-0.65 0.90-1.20

NS NS NS

NS NS NS

0.01

0.80

0.85-1.20

0.15-0.30

0.04-0.25

9.0011.00 9.0011.00 12.0014.00 12.0014.00 9.0011.00

NS 1.00-1.50 2.00-2.50 8.0010.50 18.0021.00 18.0021.00 22.0025.00 22.0025.00 18.0021.00

0.75

NS

0.75

0.75

NS

0.75

0.75

NS

0.75

0.75

NS

0.75

0.75

NS

0.75

E 308

5.4

0.08

0.50-2.50

1.00

0.04

0.03

E 308-L

5.4

0.04

0.50-2.50

1.00

0.04

0.03

E 309

5.4

0.15

0.50-2.50

1.00

0.04

0.03

E 309-L

5.4

0.04

0.50-2.50

1.00

0.04

0.03

E 347

5.4

0.08

0.50-2.50

1.00

0.04

0.03

ENi-Cl

5.15

2.00

2.50

4.00

NS

0.03

85 d min

NS

NS

NS

2.5e

ENiFe-Cl

5.15

2.00

2.50

4.00

NS

0.03

45d-60

NS

NS

NS

2.5e

Note : Single values are maximum permissible limits. NS – Not Specified

Combined Limit for Mn+Ni+Cu+Mo+V=1.75

Cb+Ta 8XC Min. to 1.00 Max. Fe Al others 8.0 1.0 Total 1.0 Fe Al others Remf 1.0 Total 1.0

WELDING MANUAL

27

Table – A3.1(Contd…) WELD METAL CHEMICAL COMPOSITION Weight, % S Ni

SFA No.

C

Mn

Si

P

ER70S-2

5.18

0.07

0.90-1.40

0.40-0.70

0.025

0.035

ER80S-G ER90S-G ER80S-B2 ER90S-B3 ER80S-D2

5.28 5.28 5.28 5.28 5.28

0.07-0.12 0.07-0.12 0.07-0.12

0.40-0.70 0.40-0.70 1.60-2.10

0.40-0.70 0.40-0.70 0.50-0.80

0.025 0.025 0.025

Not Specified Not Specified 0.025 0.20 0.025 0.20 0.025 0.15

ER90S-B9

5.28

0.07-0.13

1.20

0.15-0.30

0.01

0.01

ER 308

5.9

0.08

1.00-2.50

0.30-0.65

0.03

0.03

ER 309

5.9

0.12

1.00-2.50

0.30-0.65

0.03

0.03

ER 309-L

5.9

0.03

1.00-2.50

0.30-0.65

0.03

0.03

ER 347

5.9

0.08

1.00-2.50

0.30-0.65

0.03

0.03

Electrode

Note : Single values are maximum permissible limits. NS – Not Specified

0.15

0.80 9.0011.00 12.0014.00 12.0014.00 9.0011.00

Other Elements %

Cr

Mo

V

Cu

0.15

0.15

0.03

0.50b

Ti 0.050.15

1.20-1.50 2.30-2.70 NS 8.0010.50 19.5022.00 23.0025.00 23.0025.00 19.0021.50

0.40-0.65 0.90-1.20 0.40-0.60

NS NS NS

0.35c 0.35c 0.50c

Total other Elements 0.50 Total other Elements 0.50 Total other Elements 0.50

0.80-1.20

0.15-0.23

0.20

Total other Elements 0.50

0.75

NS

0.75

0.75

NS

0.75

0.75

NS

0.75

0.75

NS

0.75

Zr 0.020.12

Al 0.050.15

Cb+Ta 10XC Min. to 1.0 Max.

WELDING MANUAL

28

TABLE – A3.1 (Contd…) WELD METAL CHEMICAL COMPOSITION a) These elements may be present but are not intentionally added. b) The maximum weight percent of copper in the rod or electrode due to any coating plus the residual copper content in the steel shall be 0.50. c) The maximum weight percent of copper in the rod or electrode due to any coating plus the residual copper content in the steel shall comply with the stated value. d) Nickel plus incident Cobalt. e) Copper plus incident Silver. f) “Rem” stands for remainder. g) Manufacturer‟s certification to have met the requirements of ASME Sec. II Part C is acceptable in cases where the chemical analysis are not reflected. h) Single values are maximum.

WELDING MANUAL

29

Table-A3.2 MECHANICAL PROPERTY REQUIREMENT FOR ALL-WELD METAL

SFA No.

Tensile Strength Ksi / MPa

Yield Strength at 0.2% of Proof Stress, ksi/ MPa

Elongation In 2 inch (50.8 mm) %

E6010

5.1

60 / 430

48 / 330

22

E6013

5.1

60 /430

48 / 330

17

E7018

5.1

70 / 490

58 / 400

22

E7018-1*

5.1

70 / 490

58 / 400

22

E7018-A1

5.5

70 / 490

57 / 390

22

E8018-B2

5.5

80 /550

67 / 460

19

E9018-B3

5.5

90 /620

77 / 530

17

E9018-B9

5.5

90 /620

77 / 530

17

E308

5.4

80 / 550

-

35

E308L

5.4

75 / 520

-

35

E309

5.4

80 / 550

-

30

E309L

5.4

75 / 520

-

30

E347

5.4

75 / 520

-

30

ENi-CI

5.15

40-65 / 276-448

38-60 / 268-414

3-6

ENiFe-CI

5.15

58-84 / 400 -579

43-63 / 294 -434

6-18

ER70S-2

5.18

70 /490

58 / 400

22

ER80S-B2

5.28

80 / 550

68 / 470

19

Electrode

* - These electrodes shall meet the lower temperature impact requirement of 20 ft-lb at - 50°F. ( 27 Joules at – 46° C)

average minimum

WELDING MANUAL

30

Table- A3.2 (Contd..) MECHANICAL PROPERTY REQUIREMENT FOR ALL-WELD METAL

SFA No.

Tensile Strength Ksi / MPa

Yield Strength at 0.2% of Proof Stress, ksi / Mpa

Elongation In 2 inch (50.8 mm) %

ER90S-B3

5.28

90 / 620

78 / 540

17

ER80S-D2

5.28

80 / 550

68 / 470

17

ER90S-B9

5.28

90 / 620

60 / 410

16

ER308

5.9

ER308L

5.9

ER309

5.9

ER309L

5.9

ER347

5.9

Electrode

These values are not required in the test certificate

NOTE:

a) Single values are minimum. b) Manufacturer‟s certification to have met the requirements of ASME-Section II Part C is acceptable in cases where the mechanical properties are not reflected. c) 1ksi is approximately equal to 6.89 Mpa.

WELDING MANUAL

31

RECEIPT INSPECTION OF WELDING ELECTRODES / FILLER WIRES 1.

All electrodes/filler wires received at site stores shall be segregated for type and size of electrode.

2.

Ensure that electrode packets received are free from physical damage.

3.

Where electrodes are damaged, the same shall be removed from use.

4.

Only electrodes identified in the “list of approved vendors of welding electrodes” are to be accepted.

5.

Where filler metals are supplied by manufacturing unit, inspect for damages, if any.

6.

Ensure availability of relevant test certificates. Refer tables of chemical compositions and mechanical properties for acceptance.

7.

Endorse acceptance/rejection on the test certificate.

WELDING MANUAL

32

STORAGE & IDENTIFICATION OF WELDING ELECTRODES/FILLER WIRES

1.0

SCOPE:

1.1

This procedure is applicable for storage of welding electrodes/filler wires used at sites.

2.0

PROCEDURE:

2.1

Only materials accepted (based on receipt inspection) shall be taken into account for storage.

2.2

Storage Facility:

2.2.1

The storage facility shall be identified.

2.2.2

Access shall be restricted to authorised personnel.

2.2.3

The storage area shall be clean and dry.

2.2.4

Steel racks may be used for storage. Avoid storing wood inside the storage room.

2.2.5

Maintain the temperature of the storage facility above the ambient temperature. This can be achieved by the use of appropriate heating arrangements.

2.3

The electrodes/filler wire shall be segregated and identified for a.

Type of electrode e.g. E7018.

b.

Size of electrode e.g. Dia 3.15 mm.

2.4

Colour coding for filler wires:

2.4.1

On receipt of GTAW filler wires, codify the filler wires as below, in case embossing is not available on either ends. Both ends shall be colored. Specification

Brand Name*

Colour Code

RT 1/2 Mo (ER80S-G / ER 70S-A1)

TGS-M / Union1 Mo

Green

RT 1 Cr 1/2 Mo (ER80S-G / ER 80SB2)

TGS 1CM

Silver grey / White

RT 2 1/4 Cr 1 Mo (ER90S-G/ ER 90S – B3) RT 9 Cr 1Mo 1/4 V(ER90S-B9 ) RT 347 (ER347) (*or other approved equivalents)

TGS 2CM / Union1CrMo 910 MTS-3

Brown / Red

TGS – 347/ Thermanit H347

Yellow Blue

2.4.2

Where another set of colour code is followed, maintain a record of coding used.

2.4.3

Where the filler wire is cut, apply the appropriate colour code at both ends of the piece.

2.4.4

For other filler wires, a suitable colour distinct from Table 1 shall be applied.

2.4.5

AWS No. or brand name embossed end to be retained for identification.

WELDING MANUAL

33

DRYING AND HOLDING OF WELDING ELECTRODES 1.0 SCOPE: 1.1

This section details activities regarding drying and holding of welding electrodes used at sites.

2.0

PROCEDURE:

2.1

While handling, avoid contact of oil, grease with electrodes. Do not use oily or wet gloves.

2.2

It is recommended that not more than two days‟ requirements are dried.

3.0

GTAW Filler Wires:

3.1

These wires do not require any drying.

4.0

Covered Electrodes:

4.1.0

Drying and holding :

4.1.1

Identify drying oven and holding oven.

4.1.2

They shall preferably have a temperature control facility upto 400°C for drying oven and 200°C for holding oven.

4.1.3

A calibrated thermometer shall be provided for monitoring temperature.

4.2.0

On opening a packet of electrodes, segregate and place them in the drying oven. Avoid mix up.

4.2.1

After loading, raise the drying oven temperature to the desired range as per table in 4.2.5.

4.2.2

Note the time when the temperature reaches the desired range. Maintain this temperature for the duration required as per Table in 4.2.5.

4.2.3

On completion of drying, transfer the electrodes to holding oven; maintain a minimum temperature of 150°C till issue.

4.2.4

The electrode shall not be subjected to more than two cycles of drying.

WELDING MANUAL

4.2.5

Date

34

Maintain a register containing following details:

Sl.No.

Brand Name

Batch No.

Dia

Qty.

Baking Temp. reach time

Time of transfer to holding oven

Remarks

1 2 3

Redrying and Holding Parameters AWS Classification E7018 E7018-1 E7018-A1 E8018-B2 E9018-B3 E8018-B2L E9018-B3L E9018-B9 E309 & E347

Redrying (*) Temperature °C

Time (Hours)

Size- 300 250 250 - 300 250 - 300 250 - 300 250 - 300 250 - 300 250 - 300 250 - 300 250 - 300

2 2 2 2 2 2 2 2 1

Minimum Holding Temperature °C (@) 150 150 150 150 150 150 150 150 150

Note : (*) Guideline has been given however, supplier‟s recommendations shall be followed. Note : (@) Maintain the temperature in the oven till issue. 4.2.6

After issue, maintain the electrodes in a portable oven at a minimum temperature of 65°C till use (not applicable for E6013 electrodes)

4.3

Unused, returned electrodes shall be segregated and kept in the holding oven.

WELDING MANUAL

35

SELECTION AND ISSUE OF WELDING ELECTRODES / FILLER WIRES 1.0

SCOPE:

1.1

This procedure details methods for selection and issue of welding electrodes/filler wires for site operations.

2.0

PROCEDURE:

2.1

Selection:

2.1.1

The type of filler wire/electrode for welding shall be based on the details given in the contract documents like Erection Welding Schedule, drawings, Welding Procedure Specifications as supplied by the manufacturing units.

2.1.2

Where not specified by the manufacturing units, selection shall be based on the tables enclosed.

2.1.3

Where electrodes/ filler wires are not covered in the documents mentioned in 2.1.1., 2.1.2, refer to manufacturing units.

2.2

Issue :

2.2.1

Issue of welding electrodes / filler wires shall be based on authorised welding electrodes issue voucher.

2.2.2

It is recommended to restrict quantity issued to not more than 4 hours‟ requirements.

2.2.3

Redried low hydrogen electrodes shall be carried to the work spot in a portable oven.

2.2.3.1

Maintain the temperature in the portable oven at the work spot above 65°C.

2.2.4

Unused electrodes shall be returned and kept in the holding oven till reissue.

WELDING MANUAL

36

Table- A3.3 SELECTION OF GTAW FILLER WIRE, SMAW ELECTRODE FOR BUTT WELDS IN TUBES, PIPES AND HEADERS

P1 Gr 1

Welding Process GTAW

P1 Gr 2

SMAW

Material

P3 Gr 1 P4 Gr 1 P5A Gr 1 P15 E Gr 1

GTAW

P1 Gr 1 P1 Gr 2 ER 70S-A1 E7018-1 Note 1 ER 70S-A1

ER 70S-A1

SMAW

E7018-1

E7018-A1

GTAW

ER 70S-A1

ER 70S-A1

ER 80S-B2

SMAW

E7018-1

E7018-A1

E8018-B2

GTAW

ER 70S-A1

ER 70S-A1

SMAW

E7018-1

E7018-A1

P3 Gr 1

P4 Gr 1

P5A Gr 1

P15 E Gr 1

ER 80S-B2

ER 90S-B3

ER 90S-B3

E8018-B2

E9018-B3

E9018-B3 ER90S-B9

GTAW

P15 E Gr 1 SMAW

CrMoV Note 2

GTAW

ERNiCr3

ERNiCr3

ER347

SMAW

ENiCrFe3

ENiCrFe3

E347

GTAW

SMAW Note-1 : E7018-A1 for P1 Gr2 + P1 Gr2 when PWHT is involved. Note-2 : DIN14MoV63 or equivalent Note-3 : For t > 20 mm,use ER 90S –B3 for the root welding

Cr Mo V

ER90S-B9 Note-3 E 9015-B9 / E 9018-B9

GTAW

P8

P8

ER 90S-B3

ER 90S-B3

E9018-B3

E9018-B3

WELDING MANUAL

37

Table- A3.4 SELECTION OF ELECTRODES FOR WELDING ATTACHMENTS TO TUBES Attachment Material Tube Material P1 Group 1

P4 Group 1

P5A Group 1

P8

P1 Group 1 P1 Group 2

E 7018

E 7018

E 7018

E 7018-A1

P3

E 7018-A1

E 7018-A1

E 7018-A1

E 7018-A1

P4 Group 1

E 8018-B2

E 8018-B2

E 8018-B2

E 7018-A1

P5A Group 1

E 9018-B3

E 9018-B3

E 9018-B3

E 7018-A1

E 309

E 309

E 347

P8

WELDING MANUAL

38

Table- A3.5 SELECTION OF ELECTRODES, PREHEAT, PWHT FOR ATTACHMENT TO ATTACHMENT WELDS (Seal Bands, High Crown Bars, End Bars, End Bar Lifting Lugs and Collector Plates etc.)

Material

P1

P4

P5 A

P8

P 15 E / 1

Welding Requirements Electrode Preheat PWHT Electrode Preheat PWHT Electrode Preheat PWHT Electrode Preheat PWHT Electrode Preheat PWHT

P1

P4

E7018 Nil Nil E7018 (Note 2) 150 (Note 4) Nil (Note 2 & 3) E7018 150C (Note 4) Nil (Note 1 & 2) E309 Nil Nil

E8018-B2 150 (Note 4) Nil (Note 3) E8018-B2 150C (Note 4) Nil (Note 1) E309 Nil Nil

-

-

P5 A

P8 Group 1

P8 Group 2

P 15E / 1

E9018-B3 150C (Note 4) Nil (Note 1) E309 Nil Nil E9018-B3 220C 745 + 15 C

E347 Nil Nil ENi Cr Fe3 220C 745 + 15 C

E309 Nil Nil ENi Cr Fe3 220C 745 + 15 C

E9015-B9 220C 760 + 10 C

Note – 1 : When P5 A material thickness is more than 10 mm, PWHT is required. Note – 2 : Electrode, preheat and PWHT requirement for welding end bar lifting lug are as follows: End Bar Lifting Lug

End Bar

Electrode

Preheat C

PWHT C

P1

P4

E8018-B2

150

640 – 670

P1

P5

E9018-B3

150

680 – 710

Note – 3: When P4 material thickness is more than 13 mm PWHT required. Note – 4 : Preheat is not required for P4up to 16 mm & for P5 A up to 12 mm, if PWHT is carried out. Note - 5: For load carrying members, PWHT is required irrespective of thickness.

WELDING MANUAL

39

Table- A3.6 SELECTION OF ELECTRODES FOR WELDING NOZZLE ATTACHMENTS, HAND HOLE PLATE, RG PLUG ETC. TO HEADERS, PIPES.

Header, Pipe Material

Attachment Material P1

P3

P4

P5 A

P15 E/1

P8

P1

E7018-1

-

E7018-1

-

-

ENiCrFe3

P4

-

-

E8018-B2

E8018-B2

-

-

P5 A

-

-

-

E9018-B3

E9018-B3

ENiCrFe3

P15 E/1

-

-

-

E9018-B3

E9015-B9 / E9018-B9

ENiCrFe3

CrMoV Note 1

-

-

-

E9018-B3

Note 1 : DIN 14MoV63 or equivalent.

-

ENiCrFe3

WELDING MANUAL

40

Table – A3.7 SELECTION OF ELECTRODES FOR NON-PRESSURE PARTS (INCLUDING STRUCTURES) (NOTE 1) Material

SMAW Electrodes For butt welds  6 mm: E 6013

Carton Steel + P1 Carton Steel + Carton Steel

EM 12 K

 8 mm : E 6013

EL 8

>8 mm: E 7018

EM 12 K

E 6013 or E 7018 E 8018 – B2

C O2 Wires

EL 8

> 6 mm: E 7018 P1 + P1 For fillets

SAW Wires

E 71 T - 1

EM 12 K EB 2

E 81 T 1 – B2

Note 1 : E 6013 Electrodes can be used for all non-load carrying welds of all thickness of IS 2062 plates upto 20 mm thickness and 8 mm fillets.

WELDING MANUAL

41

TABLE- A3.8 A NUMBERS CLASSIFICATION OF FERROUS WELD METAL ANALYSIS FOR PROCEDURE QUALIFICATION

A. No.

Types of Weld Deposit

Analysis, % (Note 1) C

Cr

Mo

Ni

Mn

Si

1

Mild steel

0.20







1.60

1.00

2

Carbon-Molybdenum

0.15

0.50

0.400.65



1.60

1.00

3

Chrome (0.4% to 2%)Molybdenum

0.15

0.402.00

0.400.65



1.60

1.00

4

Chrome (2% to 6%)Molybdenum

0.15

2.006.00

0.401.50



1.60

2.00

5

Chrome (6% to 10.5%)Molybdenum

0.15

6.0010.50

0.401.50



1.20

2.00

6

Chrome-Martensitic

0.15

11.0015.00

0.70



2.00

1.00

7

Chrome-Ferritic

0.15

11.0030.00

1.00



1.00

3.00

8

Chromium-Nickel

0.15

14.5030.00

4.00

7.5015.00

2.50

1.00

9

Chromium-Nickel

0.30

19.0030.00

6.00

15.0037.00

2.50

1.00

10

Nickel to 4%

0.15



0.55

0.804.00

1.70

1.00

11

Manganese-Molybdenum

0.17



0.250.75

0.85

1.252.25

1.00

12

Nickel-Chrome-Molybdenum

0.15

1.50

0.250.80

1.252.80

0.752.25

1.00

Note 1: Single values shown above are maximum.

WELDING MANUAL

42

Table- A3.9 F.No.

ASME Specification No.

AWS Classification No.

Steel and Steel Alloys 1

SFA-5.1

EXX20

1

SFA-5.1

EXX22

1

SFA-5.1

EXX24

1

SFA-5.1

EXX27

1

SFA-5.1

EXX28

1

SFA-5.4

EXXX(X)-26

1

SFA-5.5

EXX20-X

1

SFA-5.5

EXX27-X

2

SFA-5.1

EXX12

2

SFA-5.1

EXX13

2

SFA-5.1

EXX14

2

SFA-5.1

EXX19

2

SFA-5.5

E(X)XX13-X

3

SFA-5.1

EXX10

3

SFA-5.1

EXX11

3

SFA-5.5

E(X)XX10-X

3

SFA-5.5

E(X)XX11-X

4

SFA-5.1

EXX15

4

SFA-5.1

EXX16

4

SFA-5.1

EXX18

4

SFA-5.1

EXX18M

4

SFA-5.1

EXX48

4

SFA-5.4 other than austenitic and duplex

EXXX(X)-15

4

SFA-5.4 other than austenitic and duplex

EXXX(X)-16

4

SFA-5.4 other than austenitic and duplex

EXXX(X)-17

4

SFA-5.5

E(X)XX15-X

4

SFA-5.5

E(X)XX16-X

4

SFA-5.5

E(X)XX18-X

4

SFA-5.5

E(X)XX18M

4

SFA-5.5

E(X)XX18M1

WELDING MANUAL

43

Table- A3.9

F.No.

ASME Specification No.

AWS Classification No.

5

SFA-5.4 austenitic and duplex

EXXX(X)-15

5

SFA-5.4 austenitic and duplex

EXXX(X)-16

5

SFA-5.4 austenitic and duplex

EXXX(X)-17

6

SFA-5.2

All classifications

6

SFA-5.9

All classifications

6

SFA-5.17

All classifications

6

SFA-5.18

All classifications

6

SFA-5.20

All classifications

6

SFA-5.22

All classifications

6

SFA-5.23

All classifications

6

SFA-5.25

All classifications

6

SFA-5.26

All classifications

6

SFA-5.28

All classifications

6

SFA-5.29

All classifications

6

SFA-5.30

INMs-X

6

SFA-5.30

IN5XX

6

SFA-5.30

IN3XX(X) Aluminium and Aluminium-Base Alloys

21

SFA-5.3

E1100

21

SFA-5.3

E3003

21

SFA-5.10

ER1100

21

SFA-5.10

R1100

21

SFA-5.10

ER1188

21

SFA-5.10

R1188

22

SFA-5.10

ER5183

22

SFA-5.10

R5183

22

SFA-5.10

ER5356

22

SFA-5.10

R5356

22

SFA-5.10

ER5554

22

SFA-5.10

R5554

22

SFA-5.10

ER5556

WELDING MANUAL

44

TABLE- A3.9(CONTD.) F NUMBERS GROUPING OF ELECTRODES AND WELDING RODS FOR QUALIFICATION F.No.

ASME Specification No.

AWS Classification No.

22

SFA-5.10

R5556

22

SFA-5.10

ER5654

22

SFA-5.10

R5654

23

SFA-5.3

E4043

23

SFA-5.10

ER4009

23

SFA-5.10

R4009

23

SFA-5.10

ER4010

23

SFA-5.10

R4010

23

SFA-5.10

R4011

23

SFA-5.10

ER4043

23

SFA-5.10

R4043

23

SFA-5.10

ER4047

23

SFA-5.10

R4047

23

SFA-5.10

ER4145

23

SFA-5.10

R4145

23

SFA-5.10

ER4643

23

SFA-5.10

R4643

24

SFA-5.10

R206.0

24

SFA-5.10

R-C355.0

24

SFA-5.10

R-A356.0

24

SFA-5.10

R357.0

24

SFA-5.10

R-A357.0

25

SFA-5.10

ER2319

25

SFA-5.10

R2319 Copper And Copper Alloys

31

SFA-5.6

ECu

31

SFA-5.7

ERCu

32

SFA-5.6

ECuSi

32

SFA-5.7

ERCuSi-A

WELDING MANUAL

45

TABLE- A3.9 (CONTD.) F NUMBERS GROUPING OF ELECTRODES AND WELDING RODS FOR QUALIFICATION F.No. 33 33 33 34 34 34 35 35 35 35 36 36 36 36 36 37 37 37 37 41 41 41

ASME Specification No. AWS Classification No. SFA-5.6 ECuSn-A SFA-5.6 ECuSn-C SFA-5.7 ERCuSn-A SFA-5.6 ECuNi SFA-5.7 ERCuNi SFA-5.30 IN67 SFA-5.8 RBCuZn-A SFA-5.8 RBCuZn-B SFA-5.8 RBCuZn-C SFA-5.8 RBCuZn-D SFA-5.6 ECuAl-A2 SFA-5.6 ECuAl-B SFA-5.7 ERCuAl-A1 SFA-5.7 ERCuAl-A2 SFA-5.7 ERCuAl-A3 SFA-5.6 ECuNiAl SFA-5.6 ECuMnNiAl SFA-5.7 ERCuNiAl SFA-5.7 ERCuMnNiAl Nickel And Nickel Alloys SFA-5.11 ENi-1 SFA-5.14 ERNi-1 SFA-5.30

IN61

42 42

SFA-5.11

ENiCu-7

SFA-5.14

ERNiCu-7

42 42

SFA-5.14 SFA-5.30

ERNiCu-8 IN60

WELDING MANUAL

46

TABLE- A3.9 (CONTD.) F NUMBERS GROUPING OF ELECTRODES AND WELDING RODS FOR QUALIFICATION F.No. 45 45 45 45 45

45

ASME Specification No.

AWS Classification No.

SFA5.11 SFA5.14 SFA5.14 SFA5.14 SFA5.14 SFA5.14

ENiCrMo-11 ERNiCrMo-1 ERNiCrMo-8 ERNiCrMo-9 ERNiCrMo-11

ERNiFeCr-1

Titanium And Titanium Alloys 51 51 51 51 52 53 53 54

SFA-5.16 SFA-5.16 SFA-5.16 SFA-5.16 SFA-5.16 SFA-5.16 SFA-5.16 SFA-5.16

ERTi-1 ERTi-2 ERTi-3 ERTi-7 ERTi-4 ERTi-9 ERTi-9ELI ERTi-12

55

SFA-5.16

ERTi-5 Zirconium And Zirconium Alloys

61 61 61

SFA-5.24 SFA-5.24 SFA-5.24

ERZr2 ERZr3 ERZr4 Hard-Facing Weld Metal Overlay

71 SFA-5.13

E Co Cr – A & All classifications

SFA-5.21

ER Co Cr – A & All classifications

72

WELDING MANUAL

47

SFA CLASSIFICATION SFA NO.

DESCRIPTION

5.01 5.1

Filler Metal Procurement guidelines Carbon Steel Electrodes for Shielded Metal Arc Welding

5.2

Carbon and Low Alloy Steel Rods for Oxy fuel Gas Welding

5.3

Aluminium and Aluminium Alloy Electrodes for Shielded Metal Arc Welding

5.4

Stainless Steel Electrodes for Shielded Metal Arc Welding

5.5

Low-Alloy Steel Electrodes for Shielded Metal Arc Welding

5.6

Covered Copper and Copper Alloy Arc Welding Electrodes

5.7

Copper and Copper Alloy Bare Welding Rods and Electrodes

5.8

Filler Metal for Brazing and Braze Welding

5.9

Bare Stainless Steel Welding Electrodes and Rods

5.10

Bare Aluminium and Aluminium Alloy Welding Electrodes and Rods

5.11

Nickel and Nickel Alloy Welding Electrodes for Shielded Metal Arc Welding

5.12

Tungsten and Tungsten Alloy Electrodes for Arc Welding and Cutting

5.13

Surfacing electrodes for shielded metal arc welding

5.14

Nickel and Nickel Alloy Bare Welding Electrodes and Rods

5.15

Welding Electrodes and Rods for Cast Iron

5.16

Titanium and Titanium Alloy Welding Rods and Electrodes

5.17

Carbon Steel Electrodes and Fluxes for Submerged Arc Welding

5.18

Carbon Steel electrodes and rods for Gas Shielded Arc Welding

5.20

Carbon Steel Electrodes for Flux Cored Arc Welding

WELDING MANUAL

48

SFA CLASSIFICATION SFA NO.

DESCRIPTION

5.21

Bare electrodes and rods for surfacing

5.22

Stainless Steel Electrodes for Flux Cored Arc Welding and Stainless Steel Flux Cored Rods for Gas Tungsten Arc Welding

5.23

Low Alloy Steel Electrodes and Fluxes for Submerged Arc Welding

5.24

Zirconium and Zirconium Alloy Welding Electrodes and Rods

5.25

Carbon and Low Alloy Steel Electrodes and Fluxes for Electro-slag Welding

5.26

Carbon and Low Alloy Steel Electrodes for Electro-gas Welding

5.28

Low-Alloy Steel Electrodes and Rods for Gas Shielded Arc Welding

5.29

Low Alloy Steel Electrodes for Flux Cored Arc Welding

5.30

Consumable Inserts

5.31

Fluxes for Brazing and Braze Welding

5.32

Welding Shielding gas

WELDING MANUAL

CHAPTER - A4

49

CHAPTER - A4 PROCEDURE FOR WELDER QUALIFICATION

WELDING MANUAL

CHAPTER - A4

50

PROCEDURE FOR WELDER QUALIFICATION 1.0

SCOPE:

1.1

This chapter details the procedure for qualification of welder and performance monitoring.

2.0

CONTENTS: 1.

Qualification of Welder.

2.

Table- A4.1 - Welder Qualification Requirements.

3.

Figure-1 Fillet Weld Break Specimen. Figure- 2 Method of Rupturing. Figure- 3 Positions. Figure- 4 Plate Butt Weld Specimen. Figure- 5 Pipe Butt Weld Specimen. Figure- 6 Bend Test Specimen. Figure- 7 Bend Test Jig.

4.

Record of Welder Performance Qualification Tests.

5.

Welder performance monitoring.

WELDING MANUAL

CHAPTER - A4

51

QUALIFICATION OF WELDER

1.0

BASE METAL:

1.1

For selection refer Tables in Chapter II.

2.0

TEST COUPON:

2.1

Depending on the range to be qualified, choose the appropriate test coupon from Table – A4.1

2.2

For plate butt welds, details of edge preparation shall be as per Figure-4.

2.3

For pipe butt welds, details of edge preparation shall be as per Figure-5.

2.4

For structural tack welds, refer Figure-1.

3.0

REQUIREMENT OF TESTS:

3.1

For Structural Tack Welders:

3.1.1 Break Test as per Figure-2. 3.2

For Plate Butt Welds:

3.2.1 Minimum of 2 specimens for bend test; one for root bend and other for face bend. Width of specimen shall be 38 mm for plate thickness upto 10 mm. For Plate thickness greater than 10 mm, side bend test ( 2 Specimens) shall be done and the width of specimens shall be 10 mm . 3.3

For Pipe Welder :

3.3.1 The order of removal of test specimens shall be as per Figure-6. 3.3.2 For width and number of bend specimens, refer below:

WELDING MANUAL

OD

W

> 101.6 50.8 - 101.6 < 50.8 32mm & < 80mm 100 % UT for thickness > 80mm 100 % MPI for thickness > 25mm (after PWHT)

WEB BUTT JOINT: Root Back grinding

:

100% LPI

On completion of weld Spot RT for thickness 32mm FILLET WELDS: Between flange and web

100% MPI (after PWHT)

WELDING MANUAL

E)

81

PRE-HEATING, POST HEATING & PWHT REQUIREMENTS : Refer WPS & Heat Treatment Manual

PWHT CYCLE: Weld thermocouples on top & bottom flange and web joints (as per sketch-4). Arrange PWHT of flange and web joints with electric resistance coil heaters. Issue PWHT job card. (Refer Exhibit) Select midpoint of temperature range and control cycle within a tolerance of  15°C. Record PWHT cycle with a calibrated temperature recorder Identify PWHT chart with chart No & date and PWHT cycle with weld joint number. Review the cycle and record observations / acceptance on chart .

F)

FINAL INSPECTION (AFTER PWHT):

Grind / buff the Flange Butt & Fillet joints (site welds) and conduct MPI. Clean all Site welds and paint with two coats of red oxide primer. Repeat all checks under section B and record measurements ( Sketch – 2A / 2B). Punch centre line of girder on flange thicknesses and top surface of top flange

G)

OTHER PREPARATORY WORKS FOR ERECTION:

Blue match girder pin bottom piece with column and complete support lugs welding in position. Subsequently blue match girder pin top piece with girder, tack weld support lugs in position, remove and complete lugs welding. Conduct LPI & maintain record.

Open the girder pin assembly, buff clean the pin and seating surfaces, apply grease, reassemble and lock the pin with pin assembly by tack welding of lock plates. Mount the girder pin assembly on ceiling girder for easiness of erection of girder pins. Buff Clean Cement wash in the HSFG bolt area and cleat angles at WB‟s location

WELDING MANUAL

82

CHAPTER – B1 PRE – ASSY SKETCHES

WELDING MANUAL

83

WELDING MANUAL

84

WELDING MANUAL

85

WELDING MANUAL

86

WELDING MANUAL

87

WELDING MANUAL

88

WELDING MANUAL

89

WELDING MANUAL

Weld Sequence Sht. 1 of 2

90

WELDING MANUAL

91

WELDING SEQUENCE FOR CEILING GIRDER Sl. SEQ. No. No.

WELDING SEQUENCE

1

1

Pre heat and weld root run at flange

2

2

Weld root run at flange

3

Repeat step 1 and 2 and weld three runs Post heat and cool to room temperature

4 5

Back grind and do LPI (at flange) 3

Pre heat and weld Root + Three runs (at other side of the flange)

6

Follow steps 1, 2 and 3 alternatively and welding upto 60% of the thickness of the

7

flange the mismatch and check the root gap of the web and grind if required Correct

8

4

Weld root run (at web)

9

5

Weld root run (at web)

10

4

Weld two run (at web)

11

5

Weld two run (at web), post heat and cool to room temperature

12

Back grinding and do LP (at web)

13

Grind the flange welding and take intermediate RT if required

14

6

Root run (at other side of the web)

15

7

Root run (at other side of the web)

16

6

Weld two run at web

17

7

Weld two run at web

18

1,2

Weld three run at flange

19

3

Weld three run at flange

20 21 22

4 5

Follow steps 1,2 and 3 alternatively and complete the flange welding Weld three run at web Weld three run at web

23

6

Weld three run at web

24 25 26

7 8

Weld three run at web Follow steps 4, 5,6,7 alternatively and complete the web welding Weld root +two run (at flange +web) - Fillet weld

27

9

Weld root +two run (at flange +web) - Fillet weld Follow step 8 and 9 alternatively(each three run and complete flange +web fillet

28

welding) Weld Sequence

Sht. 2 of 2

WELDING MANUAL

92

BHEL : ___________________ SITE Unit No.: _________________________ WELDING JOB CARD

Unit no.

:

Area : Boiler/TG/PCP

Card no.

: 002

PGMA, DU

: 35/211

Joint No.

: GRBLHS

Drg Ref

:

Flange Dia X Thick

:

Date 26/11/2000

Web PL 40 x 25

PL 100X75 Material

:

IS2062Fe410B

IS8500Fe540 Welder no.(s)

:

ST082(TOP)

ST043(BOTTOM) Date of welding

:

26/11/200 Filler wire

:

Electrode

:

E7018

E8018B2 Preheat

:

150 deg c

150 deg.c Post heat

:

150deg.c/1 hour

250 deg.c/1 hour Inter pass temp

:

300 deg.c max

300 deg.c max

Welding Engr.

WELDING MANUAL

93

BHEL : ______________SITE

Unit : ______________ (PWHT) Stress Relief (S.R.) JOB CARD

Unit no.

:

Area

:

Boiler/TG/PCP Card no.

:

PGMA, DU

:

Joint No.

:

Drg Ref

:

007

Date 04/01/2001

GRERWS (Unit-111)

Flange Dia x Thick

Web

:

PL 36 x 25

PL 100X75 Material

:

IS2062Fe410B

IS8500Fe540 NDE Cleared on

:

04/01/2001 Report no. Actual

Required Rate of heating Max deg c / hour

52

55 Soak temperature deg c

:

630

635+/-15 Soak time Minutes

:

165

165 Rate of cooling Max deg.c/hour

:

62

65

Welding Engr.

WELDING MANUAL

94

WELDING MANUAL

95

CHAPTER - B2 ERECTION WELDING PRACTICE FOR SA335 P91 MATERIAL

WELDING MANUAL

96

ERECTION WELDING PRACTICE FOR SA335 P91 MATERIAL 1.0

SCOPE:

1.1

This document details salient practices to be adopted during erection of SA335 P91 material.

2.0

MATERIAL: Pipe materials shall be identified as follows:1) Colour Code : Brown & Red 2) Hard Stamping : Specification, Heat No, Size. 3) Paint / Stencil : WO DU, as per the relevant drg & document.

2.1 When any defect like crack, lamination, deposit noticed during visual examination the same shall be confirmed by Liquid Penetrant Inspection. If confirmed, it shall be referred to unit. 3.0 3.1

ERECTION: Edge Preparation and fit up

3.1.1 Cutting of P-91 material shall be done by band saw / hacksaw / machining / grinding only. Edge preparation (EP) shall be done only by machining. In extreme cases , grinding can be done with prior approval of Welding Engineer/Quality Assurance Engineer. During machining /grinding, care should be taken to avoid excessive pressure to prevent heating up of the pipe edges. 3.1.2

All Edge Preparations done at site shall be subjected to Liquid Penetrant Inspection Weld build-up on Edge Preparation is prohibited.

3.1.3

The weld fit-up shall be carried out properly to ensure proper alignment and root gap. Neither tack welds nor bridge piece shall be used to secure alignment. Partial root weld of minimum 20mm length by GTAW and fit-up by a clamping arrangement is recommended. Use of site manufactured clamps for fit up is acceptable .The necessary preheat and purging shall be done as per clause 4.1 and 3.2.2

3.1.4

The fit-up shall be as per drawing. Root gap shall be 2 to 4 mm; root mismatch shall be within 1-mm. Suitable Reference punch marks shall be made on both the pipes (at least on three axis). a) At 200 mm from the EP for UT. b) At 1000 mm from the EP for identifying weld during PWHT.

3.2.0 FIXING OF THERMOCOUPLE (T/C) AND HEATING ELEMENTS DURING PREHEATING AND PWHT 3.2.1 No Preheating is required for fixing T / C with resistance spot welding Following are the equipment / facilities for heating cycles. (1) Heating methods: Induction heating (2) Thermo couples : Ni-Cr / Ni-Al of 0.5 mm gauge size. (3) Temp.Recorders : 6 Points / 12 Points.

(LPI).

WELDING MANUAL

3.2.2

97

ARRANGEMENT FOR PURGING :

Argon gas of 99.99% conforming to Gr 2 IS 5760 –1998 shall be used for purging the root side of weld. The purging dam (blank) shall be fixed on either side of the weld bevel prior to pre-heating. The dam shall be fixed inside the pipe and it shall be located away from the heating zone. Purging is to be done for root welding(GTAW) followed by two filler passes of SMAW in case of butt welds. Purging is not required in the case of nozzle and attachment welds, when they are not full penetration joints. The Argon to be used shall be dry. The flow rate is to be maintained during purging is 10 to 26 litres/minute and for shielding during GTAW is 8 to14 litres/minute.(A minimum flow rate as per welding Procedure specification shall be maintained). Start purging from inside of pipe when root temperature reaches 220deg C. Provide continuous and adequate Argon Gas to ensure complete purging in the root area. The minimum pre-flushing time for purging before start of welding shall be 5 minutes, irrespective of the pipe size. Wherever possible, solid purging gas chambers are to be used which can be removed after welding. If not possible, only water-soluble paper is to be used. Plastic foils that are watersoluble are NOT acceptable. 3.2.3 USING ALUMINIUM DAM ARRANGEMENT: In order to retain the Argon gas at the inside of the pipe near root area of the weld joint, the purging dams made of Aluminium (or other suitable material like mild steel) and permanent gaskets may be provided during the weld fit-up work as indicated in the sketch. The Aluminium discs shall be firmly secured with a thin wire rope. After completion of the root welding followed by two filler passes, the disc may be pulled outwards softly. CAUTION : ENSURE REMOVAL OF PURGE DAM ARRANGEMENT AFTER WELDING

WELDING MANUAL

98

.3.2.4 USING OF WATER SOLUBLE PAPER: The dams can be made of water-soluble paper for creating the purging chamber. The advantage in such dam arrangement is that dissolving in water can flush the dams. The following are different methods used. 3.2.4:-

WELDING MANUAL

4.0

99

WELDING / WELDERS QUALIFICATION: Only qualified welding procedures are to be used. Welders Qualified as per ASME Sec IX and IBR on P91 material shall only be engaged. Welders log book to be maintained and welders performance to be monitored by site welding engineer / Quality assurance engineer. The applicable WPS for P91+P91 shall be WPS N0.1034.

4.1

PREHEATING: Prior to start of pre heating ensure that surfaces are clean and free from grease, oil and dirt. Preheating temp shall be maintained at 220 deg C (min) by using Induction heating. The Temperature shall be ensured by using a Calibrated autographic recorder and two calibrated thermo couples fixed at 0 deg and 180 deg positions on both pipes 50 mm away from the EP. The thermocouple shall be welded with the condenser discharge portable spot welding machine. The preheating arrangements shall be inspected and approved by welding engineer /Quality Assurance Engineer.(Ref Fig - 1) Alternate arrangements shall be made during power failure. Two additional spare thermocouple to be fixed(as described above) for emergency use. Gas burners shall be employed to maintain the Temperature until the power resumes.

4.2

WELDING: Root Welding shall be done using GTAW process ( as per WPS) five minutes after the start of argon purging. Filler wire shall be cleaned and free from rust or oil. Argon Purging shall be continued minimum two filler passes of SMAW.

4.3

STORAGE OF WELDING CONSUMABLES: a. Welding consumables are received with proper packing and marking which includes the relevant batch number for easy identification. b. Electrodes are stored in their original sealed containers / packages until issued and kept in dry and clean environment as per the instructions of electrode manufacturers, taking care of shelf life. c. Welding filler wires are received with proper packing and marking which includes the relevant batch number for easy identification. d. The filler wires are stored in their original packages until issue and kept in dry and clean environment.

4.3.1

4.4

The electrode GTAW wires issued to the welders should be controlled through issue slips. SMAW electrodes used must be dried in drying ovens with calibrated temperature Controller. The drying temp shall be as recommended by the electrode manufacturer. The drying Temp shall be 200 - 300 deg C for two hours if it is not specified by the manufacturer. Portable flasks shall be used by the welders for carrying electrodes to the place of use. The electrodes shall be kept at minimum100 deg C in the flask. Welding shall be carried out with short arc and stringer bead technique only.

The inter-pass temperature shall not exceed 350 deg C. After completion of Welding bring down the temp to 80 - 100 deg C and hold it at this temp for one hour minimum. The PWHT shall commence after completing one hour of soaking. CAUTION:- No LPI / Wet MPI shall be carried out on weld before PWHT.

WELDING MANUAL

5.0

100

POST WELD HEAT TREATMENT:

Arrangements: - A minimum of four thermocouples shall be placed such that at least two are on the weld and the other two on the base material on either side of the weld within the heating band at 180 degrees apart about 50mm from the weld joint. Two stand by thermocouple shall also be provided on the weld in case of any failure of the thermocouple. The width of the heated circumferential band on either side of the weld must be at least 5 times the thickness of the weld. In case of fillet joints the heating band shall be six times the thickness of the base material. (Ref Fig - 2). An insulation of about 10mm thickness shall be provided between the cable and weld joint.

5.1

Obtain the clearance for post weld heat treatment cycle from QAE / Welding Engineer.

The PWHT temp for P91 with P91 material shall be 760 + 10 deg C and the soaking time shall be 2.5 minutes per mm of weld thickness, subject to a MINIMUM OF TWO HOURS. All records shall be reviewed by Welding Engineer prior to PWHT clearance. Heating shall be done by Induction heating only. The rate of heating / cooling :- Thickness up to 50mm - 110 deg C / hr.(max) (above 350 deg C) Thickness 50 to 75mm - 75 deg C / hr.(max) Thickness above 75mm - 55 deg C / hr.(max) Thickness = Actual thickness as measured. 5.2

INSULATION: The width of the insulation band beyond the heating band shall be at least two times the heating band width on either side of the weld ment. The recording of time & temp shall be continuously monitored with a calibrated recorder right from preheating. This will be ensured at every one hour by site authorized personnel.

5.3

PREVENTIVE MEASURES DURING POWER FAILURE AND NON-FUNCTIONING OF EQUIPMENT'S: No interruption is allowed during welding and PWHT. Hence all the equipment for the purpose of power supply, welding , heating etc., shall have alternative arrangements. (diesel generator for providing power to the welding and heating equipments, standby welding and heating equipments, reserve thermocouple connections, gas burner arrangement for maintaining temp etc.) Following preventive measures shall be adopted until normal power supply or backup power supply through diesel generator is restored. (a) During start of preheating: In case of any power failure/interruption during preheating, the weld fit-up shall be insulated and brought to room temperature. After the electric supply resumes the joint shall be preheated as per Clause No: 4.1. (Ref: Fig 3)

(b) During GTAW / SMAW: Use gas burner arrangement to maintain the temperature at 80 deg - 100 deg C upto a length of 50mm on either side from weld centre line along the complete circumference of the pipe. Root welding shall be continued after power is restored and preheating temperature is raised to 220 deg C. During the above period temperature shall be recorded through contact type Thermometer. (Ref : Fig4)

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101

(c)

During cooling cycle after SMAW welding to holding temperature at 80 to 100 deg C for one hour. (Ref: Fig 5) Care shall be taken to avoid faster cooling rate by adequate insulation. The required temp 80 - 100 deg C shall be maintained by gas burner arrangements till power resumes / start of PWHT.

(d)

During post weld heat treatment; The following shall be followed *1) During heating cycle The whole operation to be repeated from the beginning. (Ref: Fig 6) *2) During soaking Heat treat (soak) subsequently for the entire duration. (Complete period). (Ref: Fig 7) The heating rate shall be as per the chart. 3) During cooling (above 350 deg C ). Reheat to soaking temperature and cool at the required rate. ( Ref : Fig 8) * Temp should not be allowed to fall below 80 – 100 deg C. Gas burner arrangement shall be used to maintain the temperature.

5.4

In all the above cases (a to d) the temp. Measurement on the weld joint by means of contact type calibrated temp. Gauges shall be employed to record the temperature at regular Intervals of 15 minutes in the log book by Quality Assurance Engineer /Welding Engineer.

5.5

TEMPERATURE MONITORING: The welding and heat treatment chart given in Figure 9 shall be followed for the following details. The actual PWHT chart shall be monitored for the following: a) Preheat b) Inter pass Temperature (GTAW + SMAW) c) Controlled cooling and Holding at 80-100 Deg C for minimum one hour under insulation. Start PWHT after minimum one hour of soaking. d) Heating to PWHT e) Soaking at PWHT f) Cooling to 350 Deg C g) Cooling to Room Temperature (under insulation)

5.5 CAUTION: THE PWHT TEMP. SHALL NOT DEVIATE FROM THE VALUES SPECIFIED IN THE CHART RANGE SINCE ANY DEVIATIONS TO THE SPECIFIED HOLDING TEMPERATURE RANGE, WILL ADVERSLY AFFECT THE MECHANICAL PROPERTIES OF THE WELDMENT AND MAY LEAD TO REJECTION OF THE WELDMENT. THE WELD JOINTS

SHOULD

WATER/LIQUID IS

BE

KEPT

ALLOWED

DRY.UNDER TO

COME

WELL AS PREHEATED PORTION OF PIPE.

NO IN

CIRCUMSTANCES

ANY

CONTACT WITH WELD AS

WELDING MANUAL

102

INDUCTION HEATING (for all Thickness)

TOP

1 50mm

3

4 50mm

50mm

3

Induction Cable

1

4

2 50mm

2

30 mm

Insulation 4 X T Min OR as recommended by equipment supplier.

30mm

Insulation 4 X T Min OR as recommended by equipment supplier.

1&2 Measurement TC, 3&4 Spare TC THERMOCOUPLE (TC) ,PREHEATING ARRANGEMENT

Fig - 1

WELDING MANUAL

103

ARRANGEMENT FOR POST WELD HEAT TREATMENT

Insulate 2 Times Heating Band Width

fibre glass cloth or Ceramic wool

Heating Band W= 8 X T min or as recommended by the equipment supplier

TC1

50mm

Induction Cable

1&2 Measurement TC, 3&4 Spare TC TC 3

50mm

TC 4 at 180° apart

TC2

TC5, TC6 ( Spare TC) shall be fixed at 90°, 270° to TC3

Fig-2

WELDING MANUAL

104

Power Failure during Preheating Temp in deg c

Theoretical curve Actual curve 350

220

POWER CUT

After power resumes

100 80 RT Time

Immediately cover the joint by insulation, if welding has not been started. Start preheat as per Cl.4.1 after power resumes Fig - 3

Power Failure during GTAW/SMAW Temp in deg c Theoretical curve

Actual curve

350

BHARAT HEAVY ELECTRICALS LIMITED PIPING CENTRE CHENNAI 220

OF 25

PAGE 2

After power resumes

100 Maintain 80 - 100°c by immediate BHARAT CHENNAI PAGE 2 80 HEAVY ELECTRICALS LIMITED PIPING CENTRE During power cut

RT

OF 25

insulation and heating by burners

Time

Fig - 4

WELDING MANUAL

105

Power Failure during cooling / holding

Temp in deg c

Theoretic al curve

Actual curve

350 220

After power resumes 100 80

RT

During power cut

Time

Fig - 5

Maintain 80 - 100°C for a min period one hour by immediate insulation and heating by gas

WELDING MANUAL

106

Power Failure during PWHT heating cycle Temp in deg c Theoretical curve 760 ± 10 Actual curve

350

220

Rate of heating shall be adhered

100 80

Power cut

RT

Time

Fig - 6

Power Failure during PWHT soaking cycle Temp in deg c

T T1

760 ± 10 Actual curve

Power cut

350

Theoretical curve

220

T1 =T

100 80 RT Time

Fig - 7

WELDING MANUAL

107

Power Failure during PWHT cooling cycle Temp in deg c

Actual curve Theoretical curve

760 ± 10

350 Free fall (While heat insulated)

220

Rate of cooling shall be adhered

100 80 RT

Time

Fig - 8

WELDING MANUAL

108

WELDING MANUAL

5.7

109

CALIBRATION: All equipments like recorder, thermocouple, compensating cable, oven thermostat etc. should have valid calibration carried at BHEL approved labs. The calibration reports shall be reviewed and accepted by Calibration In-charge at site prior to use.

6.0

NONDESTRUCTIVE EXAMINATION ( Refer NDE Manual ) : 6.1 All NDE shall be done after PWHT only. Prior to testing all welds shall be smoothly ground. All weld s (fillet & butt) shall be subjected to MPI (MPI shall be done by YOKE type only). In addition to MPI, butt-welds and all full penetration welds shall be examined by UT. LPI procedure shall be BHE: NDT : PB : P T : 01 and MPI procedure shall be BHE: NDT : PB : MT: 05 The penetrant materials (Dye Penetrant, Solvent cleaner & Developer) and medium (dry/wet particles) used in MPI shall be of BHEL approved brands only. UT procedure shall be as per BHE:NDT:PB: UT21 with additional requirements as in (a) through (e) a)

The calibration blocks used shall be of same material specification (P91) dia & thickness.

b)

The UT equipment shall be calibrated prior to use and should be of „digital type‟ – Krautkramer Model USN 50 or equivalent or higher version , capable of storing calibration data as well as ultrasonic test results as per UT-21

c)

All record able indications will be stored in memory of – either the digital flaw detector or a PC for review at a later period.

d)

The equipment calibration data for specific weld as well as the hard copy of „Static echo-trace pattern‟ – Showing the flaw-echo amplitude with respect to DAC, flaw depth, projection surface distance (probe position) and beam-path shall be attached to UT test report. This hard-copy of echo-trace with equipment calibration data will form part of test documentation.

e)

The examination as well as evaluation will be performed by a qualified Level II personnel, and a test report will be issued. Any defect noticed during NDT shall be marked with marker.

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110

REPAIR OF WELD JOINTS: (A) WELD REPAIR AT ROOT: On visual examination during root welding if it reveals any surface defects, the same shall be removed by grinding maintaining temperature 80 - 100 deg. C and re welded with GTAW maintaining 220 deg. C before starting SMAW.

(B) WELD REPAIR ON COMPLETION: Any defect observed on the weld shall be brought to the notice of Quality assurance engineer. The size and nature of defect shall be reviewed. Any repair on weld to be carried on their approval only. If any defects are noticed on the fully completed weld while performing U.T after completion of PWHT, the same may be assessed in order to find the seriousness of the defect and to locate where exactly the defect lies from the weld outside surface. The defect area shall be marked and repaired as below: a) The weld shall be removed by grinding (gouging not permitted) such that the area for repair welding is free from sharp corners and provided with sufficient slope towards the weld face sides. Incase of cut & weld joints HAZ (5mm) will have to be removed by grinding. b) Surface examination (MPI/LPI) on the ground and welded area to be performed to ensure a sound base metal before depositing weld layers using SMAW. c) The temp. of the weld is to be maintained at preheat temp. d) Carry out SMAW using the same procedure as that of welding. e) All the specified precautions w.r.t to welding consumables, heating cycles, post weld heat treatment etc. as followed for original welding, shall be strictly adhered. The NDE shall be conducted for the entire weld joint. f) If any further defects are observed on the repaired weld, the same may be further reworked as mentioned above.

8.0

HARDNESS SURVEY: The equipment recommended to measure the hardness are EQUOTIP or MICRODUR make or equivalent portable equipment. The equipment used for the hardness measurement shall be calibrated as recommended by the manufacturer and also on a P91 calibration block provided by PC. The surface shall be cleaned and prepared as per hardness test instrument manufacturer‟s recommendation prior to hardness survey. Hardness survey shall be done on each joint at three locations along the circumference. At each location three readings shall be taken on weld and parent metal .The readings on the parent metal shall be taken within 15mm from the weld fusion line. All the hardness values shall be recorded.

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111

The max allowable hardness at weld and parent metal shall be 300 HV10. Joints having hardness above 300 HV shall be reheat treated and hardness shall be checked again. If hardness is still more refer to unit. PM 1 WELD PM 2

0

270

90

180 Figure – 10 LOCATION PM 1 READINGS 1 0 90 180 270

2

3

AVE

PM : PARENT MATERIAL 9.0

1

WELD 2

3

PM 2 AVE 1

2

3

AVE : AVERAGE

COMBINATION WELDING: For other combination of material like P22 with P91, and X22 with P91 the applicable WPS for the involving material shall be obtained from equipment supplier / WTC / PC and the same shall be used . 9.1

SOAKING TIME FOR COMBINATION WELDING: WPS N0. Material 1035 P91+P22 MS W0454. P91+X22

Soaking time 2.5mts / mm minimum one hour 2.5mts / mm minimum two hour for thickness upto 50 mm and minimum four hours for thickness above 50 mm. However the precautions as required for P91shall be fully taken care of.

10.0

Temp., 74515C 75010C

DEMAGNETISATION: Refer NDE Manual Ch 1.11

11.0

TRAINING:

11.1

The personnel engaged in P91 piping fabrication shall be trained in the following areas. a. Method and Care during fit-up. b. Argon gas root purging arrangement. c. Fixing of thermocouple and wires. d. Arrangements for Pre/Post heating requirements and methods. e. Adjustment of heating pads/cables at the time of controlling the temperature within specified tolerance limits during welding or PWHT in case of induction heating. f. Good appreciation of the WPS requirements. g. Handling of P91 welding consumables and re-drying conditions. h. Special precautions during the power/equipment failure. i. Weld joints of dissimilar thickness / material specification.

AVE

WELDING MANUAL

j.

112

Weld defect control and weld repair systems.

11.2

SPECIFIC TRAINING FOR WELDERS: a. The qualified welders who will be engaged in P91 welding shall be given training on pipe joints simulated with P91 welding and heating cycle conditions. b. The acquaintance on welding positions, as applicable shall be given using P91 pipes and P91 welding consumables. c. Welding techniques and instructions on Dos and DON‟Ts of P91 welding. d. Welders only who are qualified on P91 welding alone shall be engaged. e. Whenever new welders have to be engaged they shall undergo all the training as above and shall be qualified with P91 material only.

11.3

CONTROL ON WELDERS: The welder during welding at site follow the following procedures. The welder shall interact with the HT operator (Induction equipment operator) to ensure that preheat and interpass temperature during welding are maintained as per requirements. The welder shall not mix the welding electrodes with that of the other welder. At the end of the shift, the unused electrodes shall be returned to the stores.

11.4

PERSONNEL / CONTRACTORS ENGAGED FOR HEATING CYCLES (HT Operator):

11.4.1 The Personnel / Contractor shall have adequate heat treat experience on P91 or similar material. 11.4.2 HT operator shall be aware of the following: a) The equipment used and its working principle and operation. a) The procedures to be followed in using heating equipments. b) Procedure to be followed in case of power failure or equipment non-functioning so that heating cycle is not disrupted. c) Calibration of equipments. d) Method of fixing thermocouples and compensating cables leading to HT recorder. e) Fixing of heating pads or elements on the pipe joints and also in maintaining the temperature within the specified limits. 11.5

NDE PERSONNEL QUALIFICATIONS: All NDE personnel performing NDT like UT & MPI/LPI shall be qualified in accordance with BHEL Procedure meeting the requirements of recommended practice SNT – TC - IA. MPI & LPI shall be carried out by level I qualified personnel and shall be evaluated by level II qualified personnel. However UT examination and evaluation shall be done by level II qualified personnel.

11.6

LEVEL OF SUPERVISION Site Incharge shall be responsible for the completion of all activities from weld fit-up to final clearance of weld joints after satisfactory NDE and acceptance by BHEL/Customer/IBR.

WELDING MANUAL

12.0

113

DO‟s and DON‟T‟s during P 91 welding, heat treatment and NDE at construction site:

12.1 DO‟S: a) Cutting by Band saw/Hack saw/Machining. b) Pipes Edge Preparation by machining. Machining shall be done without excessive pressure to prevent heating up of pipe c) Grinding may be done on exceptional cases after approval and taking adequate care to prevent overheating. d) Thermocouple wire (hot/Cold junctions) shall be welded with condenser discharge portable spot-welding equipment. e) Reserve Thermocouples shall be made available , incase of failure of connected thermocouple elements. f) Ensure adequate Argon Gas for complete purging of air inside the pipe before starting GTAW root welding. g) Ensure Preheating at 220 Deg.C minimum before GTAW root welding. h)

Start preheating only after clearance from Welding engineer / Quality assurance engineer for weld fit-up and alignment of the joint as well as fixing of Thermocouple connections ( for Induction heating)

i) Do visual inspection on root weld maintaining weld preheating temp. j) Continue Argon purging until the GTAW root welding followed by minimum two filler passes of SMAW, is completed. k) Perform partial root welding to facilitate fit-up if necessary. l) Ensure that only one layer of root welding using TGS 2CM filler wire (2 ¼ Cr 1 Mo) is deposited. (wherever specified). m) Ensure proper use of TIG wires as identified by colour coding or suitable hard punching. n) Keep the GTAW wires in absolutely clean condition and free from oil , rust, etc. o) Dry the SMAW electrodes before use. p) Ensure the interpass temperature is less than 350 Deg.C. q) Hold at 80-100 Deg.C for a period of Minimum 1 hour before the start of PWHT. r)

Record entire heating cycle on Chart through recorders.

s) Exercise control during grinding of weld and adjoining base metal while removing surface/sub-surface defects or during preparation for NDE. t) Ensure no contact with moisture during preheat, welding, post heat and PWHT of Weld Joints. u) Ensure removal of argon purging arrangements after welding. v) Use short Arc only. The maximum weaving shall be limited to 1.5 times the dia of the electrode.

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114

13.0 DON‟T‟s: a) Avoid Oxy-Acetylene flame cutting. b) Avoid Weld-build up to correct the weld end-d1 or to set right the lip of the weld bevel. c) Avoid Arc strike on materials at the time of weld fit up or during welding. d) Do not Tack weld the Thermocouple wires with Manual Arc/TIG welding. e) NO GTAW root welding without thorough purging of root area. f) Do not use Oxy-acetylene flame heating for any heating requirements. g) Do not use Thermal chalks on the weld groove. h) Do not stop argon purging till completion of GTAW root welding and two layers of SMAW. i) No Tack welding or Bridge piece welding is permitted. j) Do not use unidentified TIG wires or electrodes. k) Do not exceed the maximum interpass temperature indicated in WPS l) Do not allow moisture, rain, water, cold wind, cold draft etc. to come in contact with the weld zone or heating zone during the entire cycle from preheat to PWHT. m) Do not exceed the limits of PWHT soaking temperature. n) Do not Interrupt the Welding/heating cycle except for unavoidable power failures o) Do not use uncalibrated equipment for temperature measurement during heating, welding, post weld, heat treating etc., 14.0 1)

NDE Consumables: For LPI consumables list refer NDE Manual CH 1.1

2) Dry Magnetic powder:

3)

(a) MAGNAFLUX - PRODUCT GREY; 8A – RED (b) FERROCHEM PRODUCT NO: 266 (c) K-ELECTRONICS PRODUCT – RD- 200 (SPECIAL) Non-fluorescent magnetic ink: (Prepare bath as instructed by supplier) a) MAGNAFLUX – Product 9C RED with MX/MG carrier II oil vehicle. b) FERROCHEM–PRODUCT NO: 146 A with oil vehicle (with high flash point 92C) c) SARDA MAGNA CHECK INK with oil vehicle (with high flash point 92C)

4)

15.0

Fluorescent magnetic ink: (Prepare bath as instructed by supplier) a) MAGNA FLUX – Product 14A with MX/MG carrier II oil vehicle. b) MAGNA FLUX – Product 14 AM – Prepared bath of 14A and MG/MX carrier II ready to use without measuring and Mixing in aerosol container with MX/MG carrier II oil vehicle DOCUMENTATIONS: The documentation shall be as per the customer approved BHEL Quality Plan.

WELDING MANUAL

115

TECHNICAL DIRECTIVE Sht no.: 1 of 2 ARGON PURITY LEVEL WHAT IS ARGON: Argon is chemically-inert, monatomic gas, heavy and available in quantity at reasonable cost. Its chemical symbol is Ar. Atomic weight is 40. Molecular weight is 40. APPLICATION OF ARGON IN BHEL: In the welding process, Argon is used for SHIELDING and BACKING purpose. The atmosphere in which we live is composed of about 4/5th of Nitrogen and 1/5th Oxygen. The welding process when exposed to air, most metals exhibit a strong tendency to combine with Oxygen, and to lesser extend with Nitrogen, especially when in the molten condition. The rate of oxide formation will vary with different metals, but even a thin film of oxide on the surface of metals to be welded can lead to difficulties. For the most part, the oxides are relatively weak, brittle materials that in no way resemble the metal from which they are formed. A layer of oxide can easily prevent the joining of two pieces by welding. Argon is a shield gas used in Gas Tungsten Arc Welding (GTAW), Root Shielding and Plasma cutting. Argon protects welds against oxidation as well as reduces fume emissions during welding. PRODUCTION OF ARGON : A co-product of oxygen and nitrogen production, argon is manufactured commercially by means of air separation technology. In a cryogenic process, atmospheric air is compressed and cooled. Following liquefaction, the air is fractionally distilled based on the different boiling points of each component. (The boiling point of argon is between those of nitrogen and oxygen.). During distillation, liquid nitrogen is the first product extracted from the high-pressure column. Next, a stream containing oxygen and argon (plus other gases) is withdrawn. The crude stream, containing approximately 10 percent argon, is refined in a separate distillation column to produce argon with 98 percent purity. Manufacturers can further refine the stream by mixing the argon with hydrogen, catalytically burning the trace oxygen to water, drying and, finally, distilling the stream to remove remaining hydrogen and nitrogen. Using this process, producers can achieve an argon product with 99.9995 percent purity.

WELDING MANUAL

116

TECHNICAL DIRECTIVE Sht no.: 2 of 2 ARGON PURITY LEVEL The compressed argon is supplied in cylinders and liquid argon is supplied in tanks. The cylinder used for argon will have the body colour of BLUE without band, size of 25 cms dia. & 1.5 m length, capacity of 6.2 M3 and pressure when fully charged at 150C (approx) 137 Kg/Cm2 (1949 psi). PURITY LEVEL OF ARGON INDIAN STANDARD for ARGON, Compressed & Liquid Specification no. IS 5760: 1998 shall be referred. There are 3 grades of argon, namely: • Grade 1 : Ultra high purity argon for use in electronics and allied industries and indirect reading vacuum spectrograph, • Grade 2 : High purity argon for use in lamp and allied industries and • Grade 3 : Commercial grade argon for use in welding industry and for other metallurgical operations. Accordingly the argon shall comply with the requirements given below: Sl. No. CHARACTERISTIC i. ii. iii. iv. v. vi. vii.

Oxygen, ppm, Max. Nitrogen, ppm, Max. Hydrogen, ppm, Max. Water vapours, ppm. Max. Carbon dioxide, ppm, Max. Carbon monoxide, ppm, Max. Hydrocarbons, ppm, Max.

REQUIREMENT Grade 1 Grade 2 Grade 3 0.5 5.0 10.0 2.0 10.0 300 1.0 2.0 5.0 0.5 4.0 7.0 0.5 0.5 3.0 0.5 0.5 2.0 0.2 0.5 -

PURCHASE SPECIFICATION FOR ARGON: BHEL - WELDING TECHNOLOGY CENTRE, Trichy recommends the specifications for purchasing the Argon for welding process is, “Argon as per Grade 3 of IS-5760: 1998 Rev 02 with Oxygen & Water Vapours restricted to max. 7 PPM each and with Argon purity level of min. 99.99%. The supply should accompany Test Certificate for the batch indicating individual element „PPM‟ level and overall purity level.” Hence, it is recommended to purchase the Argon with above specification by BHEL as well as by our Sub-contractors engaged at sites. ---- O ----

WELDING MANUAL

117

Welding research institute Bharat Heavy Electricals Ltd. Tiruchirappalli-620014 Use of Resistance heating for Post weld heat treatment of P91 pipes. (For Reference only – WPS of concerned Unit shall prevail) The subject of the use resistance heating for PWHT has been raised over the past few years especially for application to P91 steel pipes. In response to this WRI had taken up extensive studies on the effectiveness of this method in P22, P91 and SA106 Gr.B pipes using the conventionally used continuous coil type heating method and flexible ceramic pad based resistance heating. The studies were primarily aimed at evaluation of the effectiveness of the method to achieve close temperature gradients of the order of 15C across the wall thickness of the pipe during soaking period of Post weld heat treatment. In view of this thermocouples were attached on the inner walls of the pipe also in this study, though it is not done in actual situations to enable measurement of temperature gradients at various stages of PWHT across the wall thickness. The studies were conducted with different parameters such as heating dimensions, soaking times etc. The study reveled the following 1.

Close temperature gradients up to 15C could be achieved across the circumference of the pipe when an automatic heat treatment is carried out using Flexible ceramic type pad elements along with Programmable temperature controller energized by a thyristorised power source that gives an output supply of 65/80V and a digital temperature indicator cum printer is used.

2.

This automatic method could be easily used to control the preheat temperature as well as the inter pass temperature required to be controlled during welding of P91 steels. The digital printer could give the temperature values along with real time and were found to be reliable.

3.

The conventional method of PWHT using continuous coil type heating method were found to give higher temperature gradients of the order of 25C and required a close monitoring by skilled personnel to obtain the right results. Subsequent to this study, a workshop was conducted in Nov 2003 at PSSR chennai to communicate the results to all construction engineers. Representatives from various power sector regions attended this workshop. During deliberations, it was felt by all that the automatic resistance based heat treatment can be applied in one of the 500 MW sites. Some people opined that prior to the actual use it could be demonstrated in Bellary site as a next step for implementation of the technique.

WELDING MANUAL

118

In the meanwhile, WRI was recently requested (July 2006) to assist L&T ECC division to establish the resistance heating method for heating and PWHT of P91 pipes at SIPAT site for the 660 MW boiler being erected by them. In response to this the same contractor who was engaged earlier for WRI trials was engaged and a demonstration was carried out at SIPAT site. The primary aim of this demonstration was to demonstrate the effectiveness of the automatic method to get temperature gradients to levels of 15C in P91 pipes up to 30 mm thickness. In tune with this two trials were conducted at site. The first pipe was a P91 pipe with 25 mm thickness in which the entire preheating, interpass temperature control and during welding and PWHT cycle was applied. The welded pipe was also subjected to procedure qualification tests at WRI. Secondly one more pipe of 45 mm thickness was also tried to study the effectiveness of the method with thermal cycle simulation only without welding. The results of the above study reveal the following 1.

Temperature gradients within 8-10C could be obtained between the outer and inner walls with the automatic resistance heating method.

2.

The temperature chart showed that no interruptions or kinks in the time-temperature record indicating the steady maintenance of temperature throughout the PWHT cycle.

3.

The method could be effectively used for the entire heating cycle, including preheating, interpass temperature control during welding, cooling to intermediate temperature and regular PWHT cycle.

4.

Similar results were observed in the case of 45 mm thick pipe also and the results were highly reliable.

5.

The trials at WRI shop as well as SIPAT site has given good and satisfactory results indicating that the automatic local PWHT is more reliable, consistent and can be applied in site with ease. In view of the above it can be concluded that the automatic resistance based heating method can be used for the entire heating cycle for welding P91 grade pipes up to 32 mm to achieve temperature gradients of the order of 10C which is required as per specification. The details of the various components of the automatic resistance heating equipment and system that are to be used in are given in Annex I. The contact address of the contractor through whom the trials were carried out is given in annex II. Besides this, some more contractors have also shown interest in carrying out the PWHT in the automatic mode. Their addresses are also given in annex II. As the entire set of equipments is made indigenously many contractors would come up with the automatic heating facilities when BHEL specifies the usage of this method. In this context it is recommended to carry out Procedure qualification test with the largest thickness pipe at site to establish the process with the contractors prior to application for the actual pipe. This would enable the contractors to stabilize the process and serve as a measure of quality assurance for site heat treatment.

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119

Annex I Details of the automatic resistance heating based equipment recommended for PWHT.

Sl.no

Key components of the Description of the items that are essential equipment

01

Type of heating element

Flexible ceramic pads containing stranded heating elements of standard width and breadths to cover various diameters of pipes. The pads can be of 2.7/3.6 kW power with 65/80V

02

Power supply

Power source: 50/70 KvA transformer power source with 3 phase input supply with 415 / 440 V, 50 Hz supply to provide a secondary output voltage of 65/85V and 225 Amps per phase. 6 way thyristorised switching, energy regulators.

03

Controller

Microprocessor based Programmable cycle controller (0-1200°C) with easy setting of time and temperature for setting heating/soaking and cooling rates.

04

Temperature recorder

Calibrated Digital multi point recorder (12 channel- 0 to 1200°C) cum printer with suitable connecting cable for real time recording temperature with time for the entire heating cycle.

05

Power cables

Suitable plug in type copper cables, 2/3/4 way splitter cables to connect heating pads and power source. Suitable temperature compensating cables to connect thermocouples and Power source and temperature recorder

06

Accessories

1. Capacitor discharge based Thermocouple fixing unit. 2. Calibrated thermocouples (type K). 3. Mineral wool /ceramic wool Insulation pads of min 25 mm thick for insulation of the pipe. 4. Steel banding machine with 1” thick steel band for securing the heating pads with the pipe.

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120

Annex II

List of vendors /contractors who can carry out the automatic local PWHT at site

01

02

Vendor used for the study at WRI and at SIPAT site Mr. Fernandez Phone Indo therm engineers Pvt.Ltd 25822175,25830410,25805563, 25831948 Plot No. A-374, Fax: 022- 25833882 Road No. 9 Cell no: 9892592329 Wagle Industrial Estate Email: [email protected] Thane –400 504

Vendors who are ready to offer PWHT services with auto equipments K.B. Jetly 022 - 556 7654/ 5581766/556 6096 East West Engineering & electronics company [email protected] 204, Acharya complex center Dr. C. Gidwani road Chembur, Mumbai 400 074

03

Shri .V. Kannan Shastra NDT services 131,Aharya commercial center Near Basant Cinema Dr.C.G.Road Chembur Mumbai –400 074

Ph: 022- 5575 1279 [email protected] Mobile: 98213 29436

04

Injo tech services Office No. 44, 5th floor Yugay Mangal complex Near ICICI bank, Erandwane Pune 411 038

Mr. Ingale 020-5621 2833, 5621 6833 Mobile of Mr. Ingale: 09822036600 [email protected]

05

OPI services, Pune

Mr. Sathe Cell: 9822499002

WELDING MANUAL

B-3 GENERAL TOLERANCES FOR WELDING STRUCTURES – (FORM AND POSITION)

CHAPTER - B3 GENERAL TOLERANCES FOR WELDING STRUCTURES – (FORM AND POSITION)

121

WELDING MANUAL

B-3 GENERAL TOLERANCES FOR WELDING STRUCTURES – 122

(FORM AND POSITION)

Doc. Ref.: AA 0621105 GENERAL TOLERANCES FOR WELDED STRUCTURES - (FORM AND POSITION) 1.0

GENERAL :

1.1

Tolerance on form and position as defined in this standard are permissible variations from the geometrically ideal form and position corresponding to the accuracies commonly obtained in workshops. The standard covers tolerances on straightness, flatness and parallelism.

Doc. Ref.: AA 0621105

1.2 This standard is based on DIN 8570 Part 3 - 1987 B3. GENERAL TOLERANCES FOR components WELDED STRUCTURES 1.3 General tolerances for machined are covered in -corporate standard 023 02 08. (FORMAA AND POSITION) 1.4

Refer Corporate Standard AA 062 11 04 for general tolerances for lengths and angles of welded components, assemblies and structures.

2.0 2.1

SCOPE : This standard prescribes four degrees of accuracies taking into account the function dependent and the fabrication dependent differences along with appearance aspects of welded components, assemblies and structures.

2.2

For technical and economic reasons other degrees of accuracy may be appropriate which have to be specifically stated.

3.0 3.1

DEVIATIONS : The values of deviations for different classes of accuracies of straightness, flatness and parallelism are given in Table-1. These values apply to overall dimension and to part lengths.

4.0 4.1

REPRESENTATION ON DRAWING : The required degree of accuracy shall be specified in all fabrication drawings. For example Class E of AA 062 11 05 (DIN 8570 Part 3). TABLE 1 : TOLERANCES ON STRAIGHTNESS, FLATNESS AND PARALLELISM

Nominal Dimension Range (larger side length of surface) - mm Grade Above Above Above Above Above Above Above Above Above of accu1000 2000 4000 8000 12000 16000 Above 30 to 120 to 315 to racy to to to to to to 20000 120 315 1000 2000 4000 8000 12000 16000 20000 E 0.5 1 1.5 2 3 4 5 6 7 8 F 1 1.5 3 4.5 6 8 10 12 14 16 G 1.5 3 5.5 9 11 16 20 22 25 25 H 2.5 5 9 14 18 26 32 36 40 40

WELDING MANUAL

B-3 GENERAL TOLERANCES FOR WELDING STRUCTURES – 123

(FORM AND POSITION)

5.0 5.1

TESTING :

Figures 1 to 3 illustrate the mode of testing for straightness, flatness and parallelism.

The test method should be selected on the basis of current measuring practice. There should be no unusual temperature or weather conditions, e.g. strong sunshine. The measured values apply to the conditions on the day of testing.

5.2

STRAIGHTNESS : The edge of the welded component and the straight edge can be arranged in relation to each other so that the end points of the measured length are the same distance apart from the ends of the straight edge. The distances between the edge and the straight edge should be measured.

5.3

FLATNESS : A measuring plane can be set up outside the welded component parallel to the limiting planes at any desired distance. For example this can be done with optical instruments, flexible tube liquid levels, tension wires, clamp plates, surface plates and machine beds.

5.4

PARALLELISM : Any of the measuring devices mentioned above can be used to set up a measuring plane outside the welded component parallel to its reference plane.

The distance

from the actual surface to the measuring plane is measured.

The position of the reference surface (= surface after machining) is dimensionally determined. Dimension a1 gives the required finished height of the foundation. Dimension a2 gives the minimum thickness of the support. The distance between the reference plane and the measuring plane is greater than : hmax by the minimum possible thickness of the machining allowance “b”. The variation of the actual surface (=surface before machining) from the reference plane must be within the tolerance on parallelism. Maximum variation is hmax - hmin  t Note : The tolerance on form and position as per this standard may be mentioned on the drawing in addition to the linear tolerances as per AA 062 11 04 wherever required.

WELDING MANUAL

B-3 GENERAL TOLERANCES FOR WELDING STRUCTURES – (FORM AND POSITION)

124

WELDING MANUAL

-

125

CHAPTER - B4 WELDING OF PIPES AND PIPES SHAPED CONNECTIONS IN STEAM TURBINE, TURBO-GENERATORS AND AUXILIARIES

WELDING MANUAL

-

126

WELDING OF PIPES AND PIPES SHAPED CONNECTIONS IN STEAM TURBINE, TURBO-GENERATORS AND AUXILIARIES Doc.Ref.: HW 0620599 1.0

SCOPE : These guidelines cover edge preparation, method of welding for pipes and pipe shaped connections to be used in Steam Turbine, Turbo-generator and heat exchanger of KWU design.

2.0

WELD EDGE PREPARATION :

2.1

Various forms of edge preparation to be used for shop weld, site weld and edge preparations for pipes manufactured from rolled plates are covered in this standard.

2.2

However, edge preparation may be altered in case where pipe connections are made between customer‟s pipe line and BHEL supply. In all such cases edge preparation must be given on the drawing.

3.0

ASSEMBLY AND WELDING PROCEDURES :

3.1

Before tacking the weld edges must be aligned. The linear misalignment between weld edges must be maintained according to specifications No. HW 0620099.

3.2

Machined weld end preparations of the components being despatched to site must be protected with a metal cover.

3.3

Shaped parts of piping e.g. flanges, reducer, elbows, T-sections etc. are ordered with edge preparations carried out at supplier‟s work.

3.4

Welding processes are selected in accordance with Annexure-I.

3.5

Welders qualified as per ASME Section IX are to be employed.

3.6

The distinction is to be made between shop and site welds in the drawing as per Plant Standard No. 0623.003.

3.7

Tack welds, if not to be removed, must be made with the same filler metal and must be performed by qualified welder.

3.8

The weld joints are to be purged by inert gas in case of high alloy steels.

4.0 4.1

PIPES ROLLED FROM PLATES : Weld seams of rolled pipe are welded by Shielded Metal Arc welding. The root is gouged / ground and welded from back side.

5.0

INSPECTION :

5.1

The weld seams are subjected to internal examination in accordance with HW 0850199. The external characteristics are examined in accordance with HW 0620099.

WELDING MANUAL

ANNEXURE-I

-

127

WELDING MANUAL

-

128

CHAPTER - B5 INSTRUCTIONS FOR CARRYING OUT CONDENSER PLATE AND NECK WELDING

WELDING MANUAL

-

129

INSTRUCTIONS FOR CARRYING OUT CONDENSER PLATE AND NECK WELDING 1.1

GENERAL:

1.1.1 The welding of the condenser is performed by „step back seam method‟ i.e. from tack weld to tack weld. 1.1.2

Subsequent filling welds after tack welding are always performed in the opposite direction. Welding to be carried out as per requirement envisaged in drawing / field welding schedule.

1.1.3

Condenser Erection Manual as well as instructions issued by manufacturing unit may also be referred in conjunction with this manual.

1.1.4

All the welding shall be carried out by qualified welders.

1.2

CONDENSER SHELL INTERNALS WELDING:

1.2.1 Tack weld the tube support plate sections aligned with the centre point to the slot profiles on the bottom plate and the side walls. After tack welding, verify that the holes in the support plates lie in the vertical and horizontal planes. Enter the actual measurements on the measurement data record provided. The thin steel wires and alignment devices can now be removed, as they are no longer required for further assembly of the condenser shell internals. Move the internals temporarily housed in the spaces in the tube support plate sections into their correct positions, align and tack weld them in accordance with the plantspecific drawing. Assemble the central fishing and the bracing assemblies such as flat irons and tubes. NOTE:The steam baffles and bracing units must not be tacked to the tube plates of the water boxes. This operation is not performed until all internals have been welded to one another. Then align the various sections of the air extraction line, weld them together to form one unit and tack weld to the tube support plates. During alignment, ensure that the air extraction openings are directed towards the bottom plate and that therefore the connection holes for the connecting piping systems are necessarily in the correct positions. Pass out and fit the pipe work to the connecting piping system through the connection holes. Assemble the shields for the cooler tube nests. Set down the shields on the flat iron supports, align and tack weld.

WELDING MANUAL

-

130

After assembly of all the steam space internals which, to allow for welding warpage, may only be tack-welded, commence welding of all the condenser shell internals, the welding sequence being of up most importance. NOTE: The feed water heater platform must be mounted and welded in place prior to the assembly of the condensate drain sheets as there is only a gap of approximately 200 mm between the feed water heater platform and the air cooler sheet. Then weld the vertical slot profile strips to the side walls and tube support plates. During this procedure, welders should as far as possible work simultaneously. When the condenser shell internals have been completely welded together, tack and weld the steam baffle plates, the bracing assemblies and the air extraction line and the connecting piping system at the front and rear tube plates. When all welding work has been concluded, remove all weld residue from the weld seams and weld zones in the entire condenser shell. NOTE:To prevent welding warpage, all welds must be performed simultaneously from both sides using the back-step method. Vertical joints must be welded from top to bottom, i.e. from the upper edge of the tube support plate to the bottom plate.

ATTENTION:-

THE PERTINENT WELDING PROCEDURE SPECIFICATION

AND WELDING INSTRUCTIONS MUST BE OBSERVED WHEN WELDING.

1. Steam space (top view) 2. Tube support plate 3. Vertical slot profiles 4. Welding locations

WELDING MANUAL

1.3

-

131

WELD CONNECTIONS BETWEEN CONDENSER AND LOW PRESSURE TURBINE

NOTE :- The assembly welding instructions given herein are of a general nature. Please see also the assembly plans, drawings and other instructions for the plant in question. 1.3.1

In any weld connection, the cooling of the locally heated material in the weld zone will, by laws of physics cause transverse and longitudinal contractions, these giving rise to stresses in the material. In order to keep these stresses as low as possible, it is imperative that the weld is prepared as specified in the drawings. Before welding is commenced the semi-circular structural profiles must be bolted to the dome end walls.

1.3.2

WELDING THE CONDENSER TO THE LOW-PRESSURE TURBINE After the condenser has been brought to operating weight and the spring supports have been adjusted to compensate for welding contraction, prepare for welding the condenser to the low-pressure turbine. Erect scaffolding inside the condenser in accordance with applicable accident prevention regulations to facilitate access to the weld locations. Then fit the intermediate, corner and web plates (as called for) and prepare the weld edges. Tack these parts to the condenser dome with welds with a tack length of three times the plate thickness at intervals of 25 times the plate thickness. Weld the joint using the back-step method from tack to tack (see Fig.1). When the base layer has been completed, make the following filler weld layers, each in a single pass, and reversing direction for each layer (see Fig.2). After welding, clean the weld zone using suitable tools. ATTENTION:-

THE PERTINENT WELDING PROCEDURE SPECIFICATION

AND WELDING INSTRUCTIONS MUST BE OBSERVED WHEN WELDING.

WELDING MANUAL

B-6

REPAIR PROCEDURE FOR ARRESTING THE LEAKAGE OF STRENGTH WELDS ON TUBE TO TUBE 132

CHAPTER - B6 REPAIR PROCEDURE FOR ARRESTING THE LEAKAGE OF STRENGTH WELDS ON TUBE TO TUBE SHEET JOINTS OF ‘U’ TUBE H.P. HEATER

WELDING MANUAL

B-6

REPAIR PROCEDURE FOR ARRESTING THE LEAKAGE OF STRENGTH WELDS ON TUBE TO TUBE 133

REPAIR PROCEDURE FOR ARRESTING THE LEAKAGE OF STRENGTH WELDS ON TUBE TO TUBE SHEET JOINTS OF ‘U’ TUBE H.P. HEATER

1.1 Pressurise the shell side with Nitrogen or Pneumatic air to 7 Kg / cm2 and apply soap solution over the complete area of welding on tube sheet. 1.2

Find out the leakage of tubes and identify by marking either with chalk or colour.

1.3 Reduce the pressure to zero and also ensure the removal of Nitrogen from the shell. 1.4 Face the defective weld as identified earlier by using face cutter and ensure the elimination of defect by dye penetrant (LPI) test. 1.5 If found satisfactory, clean the penetrant thoroughly and weld with manual TIG using the specific WPS according to Tube sheet material and tubes. 1.6 After welding test the weld by dye penetrant and ensure the sound weld metal deposition. 1.7 Pressurise the shell side again to 7 Kg / cm2 with Nitrogen or Pneumatic air and test the soundness of welds. 1.8 Plugging of tube of „U‟ tube HP Heater on weld overlayed tube sheets. This procedure explains the method of plugging of tubes on overlayed tube sheets of : 1.

Carbon steel tubes on inconel weld overlayed tube sheets.

2.

Inconel tubes to inconel weld overlayed tube sheets

3.

Carbon steel tubes on stainless steel overlayed tube sheets.

4.

Stainless steel tubes on Stainless steel overlayed tube sheets.

Procedure : 1.

Face the tube end (to be plugged) such that the face of the tube is 4 mm below the surface of the tube sheet using the facing cutter as shown in sketch.

2.

Clean the hole inside thoroughly with the solvent.

3.

Prepare the plug made of either SA 105 or 11416.1 to a length of 38 mm as shown in sketch such that the OD of plug is machined for the interference fit with the tube hole i.e. tight fit having plug Φ 0.05 mm less than the actual inside Φ of tube as shown in sketch.

WELDING MANUAL

4.

B-6

REPAIR PROCEDURE FOR ARRESTING THE LEAKAGE OF STRENGTH WELDS ON TUBE TO TUBE 134

Fit tightly the plug inside the hole as shown in sketch and weld by GTAW (manual) using the suitable filler rod.

5.

Inspect the soundness of weld after each layer by dye penetrant.

6.

After completing the weld pressurise the shell to the operating pressure and then inspect the weld by dye penetrant.

TUBE PLUG PROCEDURE

SKETCH

WELDING MANUAL

B-7

REPAIR PROCEDURE FOR GREY CAST IRON CASTINGS

CHAPTER - B7 REPAIR PROCEDURE FOR GREY CAST IRON CASTINGS

135

WELDING MANUAL

B-7

REPAIR PROCEDURE FOR GREY CAST IRON CASTINGS

136

REPAIR PROCEDURE FOR GREY CAST IRON CASTINGS 1.0

SCOPE

1.1

This quality control procedure is valid for the repair of grey cast iron castings covering the following specifications : IS 210 Gr. 20 & Gr. 25

1.2

Defective castings can be salvaged by sound welding practices provided the defects are accessible to repair are not extensive and are economical to reclaim by welding. Where repairs are carried out on pressure retaining areas special care should be exercised to ensure sound weld repair.

2.0

DEFECTS THAT DO NOT REQUIRE WELD REPAIRS :

2.1

Machinable surfaces : Foundry defects can be left without weld repairs on Machinable areas provided the depth of such defect is less than 50% of the machining allowance provided. Defects revealed during machining shall undergo weld repairs. Isolated pores or sand inclusions of size < 3 mm and separated from one another by atleast 25 mm can be left without weld repairs.

2.2

Non-Machinable surfaces : Foundry defects other than cracks, cold shuts, shrinkage etc. can be dressed smooth by grinding provided the depth of such defect is < 5 % of the specified wall thickness, and size < 10 mm, separated from one another by atleast 100 mm.

3.0

PREPARATION OF SURFACE :

3.1

The surface around the defective area shall be free from foreign materials such as oil, grease, paint, rust, sand etc.

3.2

The defective area shall be ground or machined to obtain a sound base for welding. In the case of surface defects, the skin should be similarly ground or machined.

3.3

Before starting weld repair free graphite shall be removed by flame heating and cleaned with a wire brush.

3.4

Depending upon the size of the defect, shallow or deep grooves shall be formed by grinding / machining.

WELDING MANUAL

3.5

B-7

REPAIR PROCEDURE FOR GREY CAST IRON CASTINGS

137

Where defects are located in relatively inaccessible positions, sufficient material shall be removed to permit a satisfactory welding operation.

4.0

ELECTRODES : Low heat nickel iron electrodes (ENi CI and ENiFe-CI type) should be used. The following brands are recommended for repairs : ENi CI : 1) NFM (D&H Secheron) 2) CASTRON KALT ( Modi) 3) FERROLOID -4 (ESAB) ENiFe-CI : 1) ESAB 802 2) 1111CI (D&H Secheron) Any other equivalent approved by BHEL may also be used.

5.0

WELDING PROCEDURE :

5.1

To ensure maximum freedom from porosity in weld deposits, nickel iron electrodes should be re-baked for atleast one hour at 260˚C in a well ventilated electric oven and either used immediately or stored in a similar oven at 120˚C until used.

5.2

The welding current should be kept as slow as possible consistent with smooth operation and a good wash at the sides of the joint.

5.3

Wherever possible the casting should be positioned for down hand welding operation. When extra long welds or several repair positions are involved it is preferable to stagger the welding operation to distribute the heat and to minimise the distortion.

5.4

Manipulation of the electrode : It is preferable to use stringer bead technique, with beads not > 50 to 75 mm in length, slight weaving of the electrode may be done to obtain better wash, but in no case the width of the deposit should be > 3 times the nominal dia. of the electrode.

5.5

It is preferred to butter the surface of the weld preparation first and then fill gradually towards the centre of the repaired area.

5.6

It is essential to clean the slag from each crater before making a re-strike and to remove it completely from each weld run before depositing the adjacent weld.

5.7

To ensure maximum weld soundness the forward movement of the electrode tip should be accelerated as the end of the weld run is approached, this will taper the run rather than ending it abruptly in a large weld pool. When re-striking the arc should be started ahead of the previous weld run, move back over the tapered portion, then continued forward.

WELDING MANUAL

B-7

REPAIR PROCEDURE FOR GREY CAST IRON CASTINGS

138

The defective zone must be adequately prepared to permit correct manipulation of the electrode. 6.0

PREHEATING :

6.1

Preheating is normally not required. Where preheating is resorted to, the entire casting should be preheated. Interpass temperature should not exceed 250˚C.

6.2

It is advisable to cool as slowly as possible after welding although in most cases, it is sufficient merely to cool under a cover of heat insulating material such as asbestos, sand or ashes.

6.2

Peening of the weldment after the weld cools down may be done to reduce the shrinkage stresses.

7.0

WORKMANSHIP : The weld profile should perfectly merge with the contour of the casting and shall be free from spatter, slag etc.

8.0

INSPECTION : In addition to visual examination, non-destructive tests like liquid penetrant inspection might be employed on repaired areas to ensure freedom from cracks.

WM B8 SPECIAL INSTRUCTIONS FOR THE REPAIR OF STEAM TURBINE CASINGS

CHAPTER - B8 SPECIAL INSTRUCTIONS FOR THE REPAIR OF STEAM TURBINE CASINGS

139

WM B8 SPECIAL INSTRUCTIONS FOR THE REPAIR OF STEAM TURBINE CASINGS

140

SPECIAL INSTRUCTIONS FOR THE REPAIR OF STEAM TURBINE CASINGS Note : These instructions are only guidelines. Specific written approval is to be taken from the Manufacturing units prior to carrying out repair works. 1.0

GENERAL INSTRUCTIONS :

1.1

This instruction is valid for the repair of steam turbine castings by welding. The materials for which this instruction is applicable are: CSN 422643, 422710, 422743, 422744, 422745, GS17CrMo55, GS C 25, SA216WCB, GS 17CrMoV511, 21CrMoV57V, 21Cr.MoV57.

1.2

The repair by welding may be carried out only by qualified welder having enough experience in this line.

1.3

The castings of casings supposed to be repaired by welding must be in the heat treated state specified in the respective drawing. It is forbidden to carry out any repair by welding on castings which were not annealed or subjected to the prescribed heat treatment.

2.0

DECISION ON REPAIR :

2.1

No repair must be carried out without the approval of the manufacturing unit.

2.2

The manufacturing department takes the decision about the repair based on a strict visual and defectoscopic examination taking into consideration the type and size of the defect and its location with regard to the possibility of repair.

No repair must be

undertaken, would it endanger the proper operation and safety of the equipment.

3.0

EXECUTING THE REPAIR :

3.1

The defects in castings ascertained by the manufacturing unit, must be chipped off or ground out or drilled out in such a way as to obtain a clean metallic surface. Gouging by flame or arc - air method is permissible only with non alloyed cast steel like CSN 422643. Even then the gouged portion must be ground in order to obtain a metallic surface. In case of doubts whether the defect has been completely removed or not, the electro-magnetic crack test must be applied.

3.2

The defective portions must be removed in such a way as to enable the welder to carry out the welding successfully. There must be no sharp edges and the transition from the defective portion to the faultless material must be done in a smooth way. The welding engineer has to certify whether the preparation has been carried out properly.

WM B8 SPECIAL INSTRUCTIONS FOR THE REPAIR OF STEAM TURBINE CASINGS

3.3

141

The exact procedure of welding different types of cast steels can be found in the enclosure of this instruction.

3.4

In case cracks develop during welding, the welder is obliged to stop the welding operation and call the welding engineer immediately who will instruct the welder how to proceed further on.

3.5

If preheating for welding is prescribed, it is recommended to heat the whole casting upto the required temperature.

The preheating temperature has to be maintained

through out the welding operation. Heating by means of heating fixtures (producer gas) is permissible. It is essential to protect the casting during welding against any sudden cooling which could cause the increase of inner stresses. The surface exposed to the atmosphere should be covered by suitable insulating materials (asbestos mats, glass wool etc.). The temperature of preheating is being checked during welding by means of suitable temperature indicating aids like thermo-chalks etc.

If the preheating

temperature falls during welding below the minimum required value, welding must be interrupted and the temperature regained.

3.6

Welding must proceed without any interruption. In case welding is interrupted for any unexpected reason the casting must not cool down fast but must be heated by gas burners in order to cool down slowly to the room temperature. The same procedure has to be followed when concluding the welding operation.

3.7

In case of large welds intermediate annealing has to be carried out according to the enclosure of this instruction.

4.0

INSPECTION OF THE REPAIR :

4.1

All major repairs done on casing by welding must be recorded. The manufacturing unit / inspection department is obliged to keep these records (including a sketch about the location of the defect). Only small repairs like local porosity need not be recorded.

4.2

The welds shall be inspected visually. Larger repairs shall always be inspected by applying defectoscopic methods. The weld must be homogenous without any cracks.

4.3

Defects found in the weld must be again repaired following the same procedure as stated above.

WM B8 SPECIAL INSTRUCTIONS FOR THE REPAIR OF STEAM TURBINE CASINGS

5.0 5.1

142

HEAT TREATMENT : The repaired and inspected castings must be again heat treated. The type of heat treatment will be given by the welding engineering department from case to case.

6.0

RESPONSIBILITY :

6.1

The manufacturing unit is responsible for : a)

The exact determination of the repair to be carried out on the casing.

b)

Ascertaining that the found defects were nicely removed.

c)

Inspection of the executed repair.

d)

Record keeping on repairs.

6.2

The welding engineering department / manufacturing unit is responsible for : a)

Certifying that the places on which welding is supposed to be done are properly prepared for undertaking the repair.

b)

Follow up of welding procedure specification.

c)

Supervision of the welding operation.

d)

Ascertaining that the preheating temperature has been reached if prescribed.

e)

Cooperating with the manufacturing unit when evaluating the result of the welding operation.

f)

Prescribing the necessary heat treatment after welding if required.

WM B8 SPECIAL INSTRUCTIONS FOR THE REPAIR OF STEAM TURBINE CASINGS

7.0

143

REPAIR WELDING PROCEDURE

1

Material specification

: GS-C25, 422710, 422643, SA 216 WCB

2

Removal of defects

: Defects shall be removed by grinding / machining.

3

Inspection of pre-welding

: Complete elimination of defects shall be

ensured

by

LPI

/

MPI

/

Radiography. 4

Welding procedure : a) Welder

: Qualified as per ASME Sec.IX / IBR

b) Process

: SMAW

c) Electrode

: E7018-A1. Properly baked electrodes to be used.

d) Position

: The welding shall be done in the flat position as far as possible.

e) Arc current

: Φ 2.50 mm (60-80 amps) Φ 3.15 mm (90-130 amps) Φ 4.00 mm (140-180 amps) Φ 5.00 mm (190-240 amps)

f) Preheating

: Upto 30 mm thickness } 10ºC 30-100 mm thickness } 100ºC 101-200 mm thickness } 150ºC

5

g) Inter pass te perature

: 350ºC max.

Stress relief

: Below 40 mm thickness no stress relief is required. Above 40-200 mm thickness stress relieve at 600-620ºC for 3 hours.

6

Inspection of Post welding

: MPI followed by UT.

WM B8 SPECIAL INSTRUCTIONS FOR THE REPAIR OF STEAM TURBINE CASINGS

8.0 1

144

REPAIR WELDING PROCEDURE Material specification

: GS-17CrMoV511, 21CrMoV57V, 21CrMoV57, 422731.1, 422743.1, 422744.1, 422745.1

2

Removal of defects

: Defects shall be removed by grinding or machining and ensure complete removal by LPI / MPI.

3

Welding procedure : a) Welder

: Qualified as per ASME Sec.IX / IBR

b) Process

: SMAW

c) Electrode

: E9018B3. Properly baked electrodes to be used.

d) Arc current

: Φ 2.50 mm (60-80 amps) Φ 3.15 mm (90-130 amps) Φ 4.00 mm (140-180 amps) Φ 5.00 mm (190-240 amps)

e) Preheating

: 300ºC, continue this temp. throughout the welding operation.

5

f) Inter pass temperature

: 375ºC max.

Post weld heat treatment

: The casing has to be stress

elieved as

per code of practice in welding procedure specification. 6

Inspection after Post weld heat treatment

: MPI followed by UT.

WM B8 SPECIAL INSTRUCTIONS FOR THE REPAIR OF STEAM TURBINE CASINGS

9.0 1

145

REPAIR WELDING PROCEDURE Material specification

: GS-17CrMo55(P4), A182F12, A217WC6, A387-12

2

Removal of defects

: Defects shall be removed by grinding or machining and ensure complete removal by LPI.

3

Welding procedure : a) Welder

: Qualified as per ASME Sec.IX

b) Electrode

: E8018B2. Properly baked electrodes to be used.

d) Arc current

: Φ 4.00 mm (140-180 amps) Φ 5.00 mm (190-240 amps)

e) Preheating

: 250ºC, maintain this temp. throughout the welding operation.

5

f) Inter pass temperature

: 350ºC max.

Post weld heat tr atment

: Maintain the temp. at 300ºC for about 2-3 hours and allow it to cool under asbestos.

6

Inspection after Post weld heat treatment

: MPI followed by UT.

Note : If weld repair is extensive, i.e. thickness of weld metal is more than 10 mm, the casing has to be stress relieved as per the code of practice.

WELDING MANUAL

B 9 GAS METAL ARC WELDING

CHAPTER - B9 GAS METAL ARC WELDING

146

WELDING MANUAL

B 9 GAS METAL ARC WELDING

147

GAS METAL ARC WELDING 1. GENERAL

Gas Metal Arc Welding (GMAW) can be used as a faster alternative to Shielded Metal Arc Welding (SMAW) . In GMAW the consumable is a wire spool, which is continuously fed by a motor. This consumable as well as the shielding gas come out through a hand held torch and the torch is moved manually.

This method thus combines the flexibility of manual methods with the high productivity of motorised consumable wire movement. The method has two commonly used variants :

(a) Metal Inert Gas (MIG) welding (an example is the welding of aluminium bus ducts at site) (b) Metal Active Gas (MAG) welding (an example is steel chimney fabrication at site) While Argon is almost always used in MIG welding for shielding the arc, Carbon Dioxide or Carbon Dioxide with Argon is used for MAG welding. 2. ADVANTAGES OF GMAW The advantages of GMAW over SMAW are : (a) High welding speed due to continuous feed of filler metal and high deposition rate (b) No slag removal and no slag inclusion (c) Higher deposition efficiency (d) Higher arcing time (e) Low hydrogen content in weld metal 3. VARIABLES AFFECTING WELD QUALITY The variables which affect weld quality in GMAW ARE: (a) Welding current (b) Polarity (c) Arc Voltage (d) Travel speed (e) Electrode extension (f) Weld joint position (g) Electrode diameter (h) Shielding gas composition (i) Gas flow rate

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B 9 GAS METAL ARC WELDING

148

The optimum process variables, however, depend on type of base metal, electrode composition, welding position and the specified quality requirements. Some suggestive areas where this process can be used to great advantages are CW piping, Power House Structurals, Ceiling Girders, Condenser etc. The relevant information from welding techniques and welding procedure data used in one of the BHEL sites in construction of steel chimney is given below for guidance. If site wants to adopt GMAW process, procedure shall be developed at site and get it vetted by respective Engineering centres / Manufacturing units.

WELDING TECHNIQUES Joint details :

8mm

8 mm Fillet

8 mm

Current range

: 120 to 160 Amps

Voltage range

: 19 to 22 Volts

Electrode consumed (cm / M)

: 3 to 3.8 M / Min.

Current AC or DC

: DC

Polarity

: EP

Size of reinforcement

: 1.5 to 2 mm

Whether removed

: No

Inspection and test schedules

: As per IS 7307 PT-1

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B 9 GAS METAL ARC WELDING

WELDING PROCEDURE DATA SHEET Welding Process

: Semi-Auto

Material specification

: IS 2062 Gr.A

Thickness Plate Pipe diameter

: 8 mm : --

Filler metal specification

: IS-6419 84-C504 (ER-7086)

Weld metal analysis

: NA

FLUX OR SHIELDING GAS Flux trade Name or composition

: NA

Shielding gas composition

: 99.7% CO2

Trade Name

: NA

Flow rate

: 10-15 LPM

Backing strip used

: NA

Pre-heat temperature range

: 10C Min.

Interpass temperature range

: 265C Max.

Post Weld Heat Treatment

: NA

WELDING PROCEDURE Single or Multi-pass

: Multi-pass

Single or Multiple Arc

: Single

Welding position(s)

: Horizontal – Vertical

FOR INFORMATION ONLY Electrode and filler wire diameter

: 1.2 mm

Trade Name

: CTTOFIL(ADVANI)

Type of backing

: NA

Fore hand and back hand

: NA

149

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CHAPTER – B 10

ORBITAL WELDING

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ORBITAL WELDING ( FOR INFORMATION ONLY )

WHAT IS ORBITAL WELDING 1.

Definition

The term Orbital-Welding is based on the Latin word ORBIS = circle. This has been adopted primarily by aerospace and used in terms of Orbit (n.) or Orbital (adj.) for the trajectory of a manmade or natural satellite or around a celestial body.

The combination Orbital and Welding specifies a process by which an arc travels circumferentially around a work piece (usually a tube or pipe).

The concept Orbital Welding is basically a loosely defined term that is usually used for process only, where the arc travels at least 360 degrees around the work piece without interruption.

Consequently, processes, which interrupt the full 360-weld sequence such as for better puddle control (often used for MIG/MAG welding, using the down-hand welding sequence in 2 halfcircles), can not truly be called orbital welding.

Orbital Tube Welding Understanding the basic principles behind orbital tube welding may help you arrive more rapidly at the optimum weld procedure for your specific application. by Bernard Mannion and Jack Heinzmann III Orbital welding was first used in the 1960s, when the aerospace industry recognized the need for a superior joining technique for aerospace hydraulic lines. A mechanism was developed in which the arc from a Tungsten electrode was rotated around the tubing weld joint. The arc welding current was regulated with a control system thus automating the entire process. The result was a more precision and reliable method than the manual welding method it replaced. In the early 1980s, Orbital welding became practical for many industries when combination power supply/control systems were developed that operated from 110 VAC. These systems were physically small enough to be carried from place-to-place on a construction site for multiple in-place welds Modern day orbital welding systems offer computer control, where welding parameters for a variety of applications can be stored in memory and later called up for a specific application. Hence, the skills of a certified welder are thus built into the welding system,

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producing enormous numbers of identical welds and leaving significantly less room for error or defects. Orbital Welding Equipment In the orbital welding process, tubes/pipes are clamped in place, and an orbital weldhead rotates an electrode and electric arc around the weld joint to make the required weld. An orbital welding system consists of a power supply and an orbital weldhead. The power supply/control system supplies and controls the welding parameters according to the specific weld program created or recalled from memory. This supply provides the control parameters, the arc welding current, the power to drive the motor in the weldhead, and switches the shield gas(es) on/off as necessary. Orbital weld heads are normally of the enclosed type, and provide an inert atmosphere chamber that surrounds the weld joint. Standard enclosed orbital weld heads are practical in welding tube sizes from 1/16 inch (1.6 mm) to 6 inches (152 mm) with wall thicknesses of up to .154 inches (3.9 mm). Larger diameters and wall thicknesses can be accommodated with open style weld heads. Reasons for Using Orbital Welding Equipment There are many reasons for using orbital welding equipment. The ability to make high quality, consistent welds repeatedly, at a speed close to the maximum weld speed, offer many benefits to the user: 1.

Productivity. An orbital welding system will drastically outperform manual welders, many times paying for the cost of the orbital equipment in a single job.

2.

Quality. The quality of a weld created by an orbital welding system (with the correct weld program) will be superior to that of manual welding. In applications such as semiconductor or pharmaceutical tube welding, orbital welding is the only means to reach the weld quality requirements.

3.

Consistency. Once a weld program has been established, an orbital welding system can repeatedly perform the same weld hundreds of times, eliminating the normal variability, inconsistencies, errors, and defects of manual welding.

4.

Skill level. Certified welders are increasingly hard to find. With orbital welding equipment, you don't need a certified welding operator. All it takes is a skilled mechanic with some weld training.

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153

Versatility. Orbital welding may be used in applications where a tube or pipe to be welded cannot be rotated or where rotation of the part is not practical. In addition, orbital welding may be used in applications where access space restrictions limit the physical size of the welding device. Weld heads may be used in rows of boiler tubing, where it would be difficult for a manual welder to use a welding torch or view the weld joint.

Many other reasons exist for the use of orbital equipment over manual welding. For example, applications where inspection of the internal weld is not practical for each weld created. By making a sample weld coupon that passes certification, the logic holds that if the sample weld is acceptable, that successive welds created by an automatic machine with the same input parameters should also be sound. General Guidelines for Orbital Tube Welding For orbital welding in many precision or high purity applications, the base material to be welded; the tube diameter(s); weld joint and part fit-up requirements; shield gas type and purity; arc length; and Tungsten electrode material, tip geometry, and surface condition may already be written into a specification covering the application. Each orbital welding equipment supplier differs slightly in recommended welding practices and procedures. Where possible, follow the recommendations of your orbital equipment supplier for equipment set-up and use, especially in areas that pertain to warranty issues. Note that, this section is only intended as a guideline for those applications where no specification exists. The engineer responsible for the welding must create the welding setup, and derive the welding parameters, in order to arrive at the optimum welding solution. WELDING BASICS AND SET-UP The Physics of the GTAW Process The orbital welding process uses the Gas Tungsten Arc Welding process (GTAW), as the source of the electric arc that melts the base material and forms the weld. In the GTAW process (also referred to as the Tungsten Inert Gas process - TIG) an electric arc is established between a Tungsten electrode and the part to be welded. To start the arc, an RF or high voltage signal (usually 3.5 to 7 KV) is used to break down (ionize) the insulating properties of the shield gas and make it electrically conductive in order to pass through a tiny amount of current. A capacitor dumps current into this electrical path, which reduces the arc voltage to a level where the power supply can then supply current for the arc. The power supply responds to the demand and provides weld current to keep the arc

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established. The metal to be welded is melted by the intense heat of the arc and fuses together. Material Weldability The material selected varies according to the application and environment the tubing must survive. The mechanical, thermal, stability, and corrosion resistance requirements of the application will dictate the material chosen. For complex applications, a significant amount of testing will be necessary to ensure the long-term suitability of the chosen material from a functionality and cost viewpoint. In general, the most commonly used 300 series stainless steels have a high degree of weldability with the exception of 303/303SE, which contain additives for ease of machining. Four hundred series stainless steels are often weldable, but may require post weld heat treatment. Accommodation must be made for the potential differences of different material heats. The chemical composition of each heat batch number will have minor differences in the concentration of alloying and trace elements. These trace elements can vary the conductivity and melting characteristics slightly for each heat. When a change in heat number is made, a test coupon should be made for the new heat. Minor changes in amperage may be required to return the weld to its original profile. It is important that certain elements of the material be held to close tolerances. Minor deviations in elements, such as sulfur, can vary the fluid flow in the weld pool, completely changing the weld profile and causing arc wander. Weld Joint Fit-Up Weld joint fit-up is dependent on the weld specification requirements on tube straightness, weld concavity, reinforcement, and drop through. If no specification exists, the laws of physics will require that the molten material flow and compensate for tube mismatch and any gap in the weld joint. Tubing is produced according to tolerances that are rigid or loose according to the application for which the tube was purchased. It is important that the wall thickness is repeatable at the weld joint from part to part. Differences in tube diameter or out-ofroundness will cause weld joint mismatch and arc gap variations from one welding set up to another.

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Tube and pipe end prep facing equipment is recommended in order to help ensure end squareness and end flatness. Both the I.D. and O.D. should be burr free with no chamfer.When two tubes are butted together for welding, two of the main considerations are mismatch and gaps. In general, the following rules apply: 

Any gap should be less than five percent of the wall thickness. It is possible to weld with gaps of up to 10 percent (or greater) of wall thickness, but the resultant quality of weld will suffer greatly, and repeatability will also become a significant challenge.



Wall thickness variations at the weld zone should be +/- five percent of nominal wall thickness. Again, the laws of physics will allow welding with mismatch of up to 25 percent of wall thickness if this is the only challenge. Again, the resultant quality of weld will suffer greatly, and repeatability will become an issue.



Alignment mismatch (high-low) should be avoided by using engineering stands and clamps to align the two tubes to be welded. This system also removes the mechanical requirement of aligning the tubes from the orbital weld head.

Shield Gas (es) An inert gas is required on the tube O.D. and I.D. during welding to prevent the molten material from combining with the oxygen in the ambient atmosphere. The objective of the welder should be to create a weld that has zero tint at the weld zone I.D. Argon is the most commonly used shield gas (for the O.D. of the tube) and the purge gas (for the I.D. of the tube). Helium is often used for welding on copper material. Mixed gases, such as 98 percent Argon/two percent Hydrogen; 95 percent Argon/five percent Hydrogen; 90 percent Argon/10 percent Hydrogen; or 75 percent Helium/25 percent Argon may be used when the wall thickness to be welded is heavy (.1" or above). Using mixtures of 95 percent Argon/five percent Hydrogen is incompatible with carbon steels and some exotic alloys, often causing hydrogen embrittlement in the resultant weld. As a general rule, for simplicity and reduction of shield gas cost, use 100 percent Argon gas. Gas purity is dictated by the application. For high purity situations, where the concern for micro-contamination

is

paramount,

such

as

semiconductor

and

pharmaceutical

applications, the shield and purge gases must minimize the heat tint that could otherwise be undesirable. In these applications, ultra high purity gas or gas with a local purifier is employed. For non-critical applications, commercial grade argon gas may be used. Tungsten Electrode The Tungsten welding electrode, the source of the welding arc, is one of the most important elements of the welding system that is commonly ignored by welding systems

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users. Users continue to manually grind and wonder why they produce inconsistent results. Whether in manual or automatic welding, this is the area where manufacturing organizations can improve the consistency of their welding output with minor effort. Basically, the objective for the choice of Tungsten parameters is to balance the benefits of a clean arc start and reduced arc wander with good weld penetration and a satisfactory electrode life. Electrode Materials For quite some time, Tungsten manufacturers have added an oxide to pure Tungsten to improve the arc starting characteristics and longevity of pure Tungsten electrodes. In the orbital welding industry, the most commonly used electrode materials are two percent thoriated Tungsten and two percent ceriated Tungsten.

Safety The safety issues of Tungsten electrode material are now being looked at more closely. Many users of the TIG welding process do not realize that the welding electrode they use contains Thorium, a radioactive element added to the Tungsten. While the radioactivity is of a low level, it brings an issue of danger, especially with the radioactive dust that is generated when grinding the electrodes to a point for welding. Alternative, non-radioactive Tungsten materials are now available, such as two percent ceriated electrodes, which often offer superior arc welding. While these materials are commercially available they have been largely ignored until recently. Recommended

Electrode Materials Cerium, as a base material, has a lower work function than Thorium, offering superior emission characteristics. So, not only do ceriated electrodes offer an advance in electrode safety, they also improve the arc starting ability of the orbital equipment. However, as mentioned earlier, it is always best to follow the advice of your orbital equipment manufacturer. Electrode Tip Geometry Given the ever-increasing weld quality requirements of the final weld, more and more companies are looking for ways to ensure that their weld quality is up to par. Consistency and repeatability are key to welding applications. The shape and quality of the Tungsten electrode tip is also being recognized as a vital process variable. Once a weld procedure has been established, it is important that consistent electrode material, tip geometry, and surface condition be used.

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Welders should follow an equipment supplier's suggested procedures and dimensions first, because they have usually performed a significant amount of qualifying and troubleshooting work to optimize electrode preparation for their equipment. However, where these specifications do not exist, or the welder or engineer would like to change those settings to possibly improve and optimize their welding, the following guidelines apply: Electrode Taper This is usually called out in degrees of included angle (usually anywhere between 14° and 60°). Below is a summary chart that illustrates how different tapers offer different arc shapes and features: Sharper Electrodes

Blunter Electrodes

Last less than blunt

Last longer

Less weld penetration

Better weld penetration

Wider arc shape

Narrower arc shape

Handle less amperage

Handle more amperage

Less arc wander

Potential for more arc wander

More consistent arc

Less consistent arc

To demonstrate graphically how the taper selection will effect the size of the weld bead and the amount of penetration, the following drawing shows typical representations of the arc shape and resultant weld profile for different tapers. Electrode Tip Diameter Grinding an electrode to a point is sometimes desirable for certain applications, especially where arc starting is difficult or short duration welds on small parts are performed. In most cases, however, it is best for a welder to leave a flat spot or tip diameter at the end of electrode. This reduces erosion at the thin part of a point, and reduces the concern that the tip may fall into the weld. Larger and smaller tip diameters offer the following trade-offs: Smaller Tip

Larger Tip

Easier to start

Usually harder to start

Less arc wander

More chance of arc wander

Less electrode life

More electrode life

Less weld penetration

More weld penetration

Tungsten Electrode Grinders and Pre-Ground Electrodes

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Using electrodes pre-ground to requirements or a dedicated commercial electrode grinder to provide electrode tip quality and consistency, offers the following benefits to the user in their welding process: Improved arc starting, increased arc stability, and more consistent weld penetration. 

Longer electrode life before electrode wear or contamination.



Reduction of Tungsten shedding. This minimizes the possibility of Tungsten inclusions in the weld.



A dedicated electrode grinder helps ensure that the welding electrodes will not become contaminated by residue or material left on a standard shop grinder wheel.



Tungsten electrode grinding equipment requires less skill to ensure that the Tungsten electrode is ground correctly and with more consistency.

Pre-Ground Electrodes

Rather than risk electrode radioactivity issues, and constantly endure the variability of each operator grinding the electrodes with a slightly different touch, many manufacturing organizations have chosen to purchase electrodes pre-ground. Since a small difference in the dimensions of an orbital electrode can produce a big difference in the weld results, preground electrodes are the preferred electrode choice to maintain the consistency of your welding. This low-cost option ensures that the electrode material quality, tip geometry, and ground electrode surface input to the welding process is constant. Consult electrode charts or a pre-ground electrode supplier to obtain the electrode diameter and tip geometry that is most suitable for your welding application. Conclusion In conclusion, the important points to remember are: 

Orbital welding has been used by many industries to improve the quality and quantity of tube welding when compared to what can be accomplished by manual welders.



The effective cost of an employee computes to be significantly more than just his base salary. The output of a $20 per hour skilled welder actually costs over $72,000 per year (almost twice his yearly base wage).



If a complete orbital welding system costs between $15,000 and $20,000 and can output over twice the amount of welding that a manual welder can produce then the equipment will pay for itself in a matter of months.

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159

Finally, the volume of welds that are produced by an automated welding system will far exceed that of a manual welder. In addition to weld quality improvements, this will bring two additional financial benefits: One, increased output per day at lower cost. Two, lowered scrap and rework costs due to improved weld consistency.

Tubesheet Weld Heads - Orbital Welding Equipment / Automated Welding Equipment

These Magnatech weld heads are specifically designed for making tube-totubesheet welds. Configured for fast and simple operation, the Head is inserted into the tube to be welded, and the operator pushes the START WELD switch. Multiple torch positioning adjustments allow virtually all tubesheet joint designs to be welded. All three models weld a wide range of tube sizes and operate in any position. For welds requiring filler wire addition, an optional wire feeder can be mounted on the weld head. A standard wire spool, mounted directly on the Head, provides precise and positive wire feeding, not possible with floormounted feeders. These weld Heads bring the productivity and repetitive precision of machine welding to the fabrication and repair of steam generators and heat exchangers. All three weld Heads models are used with Magnatech power sources, ranging form simple to operate analog models to microprocessor-based systems with program storage capability. TUBE GEOMETRIES Model 424 is ideal for all tubesheet geometries. Model 425 with AVC is for multipass welding Model 426 is ideal for fusion welding where preheat is not required.

Process: Weld Head

GTAW Open arc.

Type: Tube Size

Model 424: 10mm - 78mm (0.4" - 3.07") OD

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160

Model 425: 10mm - 140.2mm (0.4" - 5.52") OD Model 426: 10mm - 70.1mm (0.4" - 2.76") OD 

Water-cooled torch and weld Head body (models 425 & 426 only) allow use on pre-heated tubesheets

Features:



Lifting eye allows use on a counterbalance for weightless operation



Multiple torch angle and wire feed positioning mechanism allow optimum torch position and wire entry angle



Simple centering cartridge design allows quick installation without requiring prior installation of expensive custom-fabricated locating fixtures



Inexpensive centering cartridges fit the exact tube ID



Filler wire spool rotates with the torch - eliminating wire entry problems common with floor-mounted feeders (Models 424 & 425)

Options:



No cable wrap-up



Filler Wire feeder using standard 1kg (2lbs.) spools



Three point standoff for welding "extended tube" geometries



Transparent purge gas chamber for titanium floods the enclosed weld area independent of torch shielding gas, reducing purge time and weld oxidation



Arc Voltage Control parallel to tungsten electrode - even when the torch is angled for a fillet weld



Torches for internal bore welding



Extension Cables



Dual Head Switcher allows two Heads to be used alternately maximizing "arc on" duty cycle

Applications:



Heat exchanger seal and strength welds



Power generation



Petrochemical



Sanitary



Food and beverage @@@@

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CHAPTER – B11

EDGE PREPARATION DETAILS FOR PIPES

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CHAPTER – B12 Erection Procedure for Rear Water Box & Rear water Chamber

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Erection Procedure for Rear Water Box & Rear water Chamber

Condensers supplied by Haridwar for 210/250/500 MW ratings are having flanged connection between water box and water chamber at both the ends. (Front & rear). This is to facilitate retubing in case it is required. With the use of stainless steel, reliability of condenser tube material has increased and chances of failures and re-tubing has reduced tremendously. In Amarkantak 210 MW, flanges have been removed from rear water box & water chamber and both have been directly welded together. Space for re-tubing has been kept on front water box side. A- Pre assembly 1.

Place both Rear water chambers on horizontal surface with water side surface of tube plate on top position. Level the water chambers w.r.t tube plate. Mark top & bottom position of water chambers.

2.

Weld backing strip on all four walls of water chambers as shown in Fig.I. In Rear water chamber (GS) backing strip will be welded inside on all the four walls and on Rear water chamber (TS) it will be welded inside on three walls and outside on vertical wall near condenser centre line.

3.

Measure tube sheet flatness as per recommended procedure and record the dimensions in log sheet L-02.

4.

Water box inside length & width and corresponding dimensions of water chamber to be checked w.r.t. horizontal & vertical centre lines and recorded in log sheet to ascertain trueness of dimensions.

5.

If logged dimensions indicate any mismatch, same may be corrected

6.

Match Rear water Box (TS/GS) by lowering it over respective water chamber / backing strip such that the weld edges of water chamber and water box match for proper welding. In case of mismatch, the same to be rectified.

B - Assembly : Assembly can be done in two ways as per site‟s convenience. Option –1 1. Remove the water box after completing the activity as per A (6) above.

2. Weld 4 number channels (2 horizontal & 2 vertical) of size 100x50 along the length and width to stiffen the water chamber. Refer Fig. I. Holes in the tube plate to be suitably protected.

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3. Lower the water chamber (without water box) on bottom plate for erection as per standard procedure. 4. Tack weld / final weld water chamber with side walls and bottom plate. 5. Carry out tubing. 6. Weld the water boxes using proper welding sequence as given (C ) below. Option – II (Refer Fig.-2) 1. Weld water box and chamber with the help of technological plates (12 x 100 x 250) as shown in the drawing. 2. Lower water box and chamber together for erection. 3. Tack weld / Final weld water chamber with side walls and bottom plate. 4. Remove water box to facilitate tubing & expansion by cutting stiffening plates. 5. Carry out tubing. 6. Weld the water boxes using proper welding sequence as given (C ) below. C- Welding sequence for water box & water chamber (Refer Fig-3) 1. Tack weld Water box (GS) and Chamber(GS) -100 (200). 2. Root run on all sides. 3. Final welding to be done as per Detail-I. 4. Welding of Generator side water box-Water chamber to be completed first as it has all welds from outside. 5. Bring Turbine side water box in position. Repeat steps 1-4 indicated above. 6. All welding is from outside except vertical welding of Rear water box & water chamber (TS) near condenser centerline which is from inside. 7. Direction of welding shall be as indicated in the drawing. 8. Over head welding is required for carrying out bottom welding of water boxes and water chambers. (Naveen Prakash)

(S.K.Baveja)

(Lalit Kishore)

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CHAPTER – B13

WELDING & HT DETAILS OF THERMOCOUPLE PAD & CLAMPS FOR SH & RH

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WELDING & HT DETAILS OF THERMOCOUPLE PAD & CLAMPS FOR SH & RH Pad / Clamp Material : SS 304, 316, 321, 310 Sl.No

Tube Material (SH & RH)

Thickness in mm (t – max).

Thermocouple pad Material

Pre-heat (min)

Post-weld heat Consumable Treatment Electrode

1

SA210 Gr. A1

7.6

SS 304, 316, 321, 310

2

SA213 T11

8.6

SS 304, 316, 321, 310

1250C

NIL

E7018 A1

t
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