Brazed Aluminium Plate Fin Heat Exchangers-Construction,Uses Advantages in Cryogenic Refrigeration Systems

Paper 44a

BRAZED ALUMINUM PLATE FIN HEAT EXCHANGERS – CONSTRUCTION, USES, AND ADVANTAGES IN CRYOGENIC REFRIGERATION SYSTEMS

Dan Markussen Principal Sales Engineer  Chart Industries

Larry Lewis CEO

BRAZED ALUMINUM PLATE FIN HEAT EXCHANGERS – CONSTRUCTION, USES, AND ADVANTAGES IN CRYOGENIC REFRIGERATION SYSTEMS Dan Markussen, Chart Industries and Larry Lewis, SME Associates Abstract This paper will provide an overview of the components of a brazed aluminum heat exchanger (BAHX) and how Chart Industries designs, manufacturers, and tests them. An overview is provided of the range of uses for BAHX in cryogenic process refrigeration systems with an emphasis on debottlenecking ethylene production facilities by optimizing their  refrigeration systems. Discussion is presented on the uses of BAHX and the advantages that they provide the designer of refrigeration systems and the owners of cryogenic refining facilities. Introduction The continued emphasis on increasing plant efficiency driven by the increased costs of  energy and feedstocks have led plant designers and owners to demand more from their heat exchangers. The required gains in efficiency and throughput targeted by a debottlenecking project can be achieved through the use of the highly efficient and flexible design of brazed aluminum heat exchangers, (BAHX.) Over the past several decades, the use of BAHX has become quite prevalent in cryogenic refrigeration systems. Applications such as petrochemical processing, industrial gas processing, production of LNG and other hydrocarbon processing covers the general spectrum

BRAZED ALUMINUM PLATE FIN HEAT EXCHANGERS – CONSTRUCTION, USES, AND ADVANTAGES IN CRYOGENIC REFRIGERATION SYSTEMS Dan Markussen, Chart Industries and Larry Lewis, SME Associates Abstract This paper will provide an overview of the components of a brazed aluminum heat exchanger (BAHX) and how Chart Industries designs, manufacturers, and tests them. An overview is provided of the range of uses for BAHX in cryogenic process refrigeration systems with an emphasis on debottlenecking ethylene production facilities by optimizing their  refrigeration systems. Discussion is presented on the uses of BAHX and the advantages that they provide the designer of refrigeration systems and the owners of cryogenic refining facilities. Introduction The continued emphasis on increasing plant efficiency driven by the increased costs of  energy and feedstocks have led plant designers and owners to demand more from their heat exchangers. The required gains in efficiency and throughput targeted by a debottlenecking project can be achieved through the use of the highly efficient and flexible design of brazed aluminum heat exchangers, (BAHX.) Over the past several decades, the use of BAHX has become quite prevalent in cryogenic refrigeration systems. Applications such as petrochemical processing, industrial gas processing, production of LNG and other hydrocarbon processing covers the general spectrum

They offer the benefits of a compact design that is typically one-fifth the size of comparable carbon or stainless steel shell and tube heat exchanger and will weigh approximately 10 percent of the weight. BAHX smaller size is attributable to the high density of the heat transfer  fins and the thermal conductivity of the aluminum material. Typical fin heights range from 0.200 to 0.380” and vary from 8 fins per inch to 25 fins per inch. Most of the surface is secondary surface with the parting sheet being the primary surface. The thermal conductivity of  aluminum is very high resulting in fin efficiencies that are typically more than 80 percent. The heat transfer fin configuration is designed to create an optimum balance between pressure drop and heat transfer of the stream. Other benefits inherent in the aluminum plate fin design include close temperature approaches and a unique ability to configure multiple streams. The multiple streams can be different types of fluids, such as gas-to-gas, gas-to-liquid, two phase or any combination, with each stream balanced and optimized both thermally and hydraulically. Whereas a typical shell and tube heat exchanger is limited to two streams, brazed aluminum heat exchangers can be designed and configured in parallel or in series to create multi stream capabilities with up to 15 different streams. Figure 1 shows the major components of a typical brazed aluminum fin heat exchanger. Brazed aluminum heat exchangers are built by stacking layers of corrugated fins separated by parting sheets and sealed along the edges with side bars.

A wide range of fin patterns [plain, perforated, herringbone and serrated] accommodate different thermal and hydraulic process requirements enabling the exchanger to be custom designed for an infinite number of processes. (See Figure 2)

Figure 2  Manufacturing Brazed aluminum heat exchangers are manufactured as an all brazed and welded pressure vessel with no mechanical joints. The heat exchanger consists of a core block constructed of alternating layers of corrugated sheets, (fins), and flat parting sheets. Each layer is bound by bars and provided with inlet and outlet distributors. The core matrix is produced by vacuum brazing; that is joining, the fins, bars and parting sheets at high temperature in a clean, vacuum environment. Brazed aluminum exchangers, due to their 

Finally, customers and/or users of brazed aluminum exchangers should only consider suppliers that conform to the standards of ALPEMA (Brazed Aluminum PlateFin Heat Exchanger Manufacturers’ Association). ALPEMA standards provide consistent quality and conformance guidelines for the design and manufacture of  brazed aluminum exchangers. More information regarding ALPEMA may be obtained from www.alpema.org Applications In addition to design, construction, quality and performance factors, application matching heat exchanger performance lies in the ability to match the application to the appropriate technology as specifically as possible . (see Figure 3) Correct decisions will help to ensure low-cost, effective operation over the long term. As stated earlier, shell-and-tube heat exchangers are versatile, all-around products intended for warm, corrosive or dirty applications where thermal performance is not highly valued. Conversely, brazed aluminum heat exchangers are ideal for cold/cryogenic; clean process streams where thermal performance, close temperature approaches, compactness and low weight are important plant considerations. Key applications include industrial gas production, natural gas processing, refinery and petrochemical processing, hydrogen and helium liquefaction and recovery, and offshore platform or FPSO processing. A variation of the brazed aluminum fin (BAHX) heat exchanger is the Core-In-Kettle ® Heat Exchanger. This approach consists of an aluminum plate fin heat exchanger assembled inside of a vessel. The aluminum plate fin heat exchanger assembly replaces the traditional

Mercury removal systems upstream of the exchanger are commonly installed so that brazed aluminum plate-fin heat exchangers may be used with streams containing mercury. Operators may also use special shutdown procedures to restrict moisture and maintain temperatures below 100 ° C. In addition to mercury removal systems, equipment from Chart Industries can be designed to be mercury tolerant. Chart’s proprietary mercury-tolerant designs allow corrosive mercury to be present in the aluminum exchanger without causing the exchanger to fail.

Benefits of The Core-In Kettle Heat Exchanger Technology Core-in-Kettle designs can possess up to ten times more heat transfer surface than traditional tube designs, providing numerous operational and performance advantages: Close temperature approaches can be accommodated generally to 1 degree C with resultant savings in power and operating costs. The Core-in-Kettle’s smaller vessel design creates cost savings though lower liquid inventory, reduction in insulation, smaller foot-print and associated space costs, And, savings in foundation and support costs as Core-in-Kettle designs are typically one-fifth the weight of  tube and shell designs. Brazed aluminum construction eliminates mechanical joints and large diameter flanges that could leak. (See Figure 4)

Core-In Kettle Applications Core-in-Kettle heat exchangers are - ideal - for lowering initial and operating costs. In a Core-in Kettle exchanger, a brazed aluminum core is immersed in a bath of refrigerant and extremely high UA/in3 are achieved due to the refrigerant path open flow area being quite large. The reduced approach temperatures lower refrigerant compression horsepower  requirements and save money. The most common applications include C2 splitter  condensers, C3 splitter heat pumps, C4 splitter heat pumps, and refrigeration condensers and evaporators. (See Figure 5)

Figure 5  Run Back Condensers Run Back Condensers are high efficiency exchangers for the partial condensation of a range of fluids. Their sophisticated design accommodates heat and mass transfer effects while

Benefits of Run Back Condensers include liquid runback to the tower which eliminates pumps, the elimination of several tower trays, and by shifting the refrigeration requirement for  the tower to a warmer level – reducing tower cost and improving efficiency.

Cold Boxes A cold box - in terms of BAHXs - is a steel structure enclosed, ( See Figure 7 ), with thingauged steel panel walls. A cold box can typically contain and support one or more BAHXs, process vessels, knock out drums, and associated interconnecting piping. Cold boxes can employ the use of specially designed control valves that allow access to the valve stems and the valve internals from the outside of the box. The piping penetrations through the box are typically free floating and insulated - pipe anchor points remain at the heat exchangers and vessels. Liquid level control lines, flow meters, and thermocouples with explosion proof   junction boxes can also be included in the design and scope of supply in order to assist plant operators with monitoring plant performance. Cold boxes are typically filled with perlite insulation and provided with nitrogen purging to keep the interior components cold and safe. The compactness and ease of insulation of cryogenic process equipment makes cold boxes ideal for use in ethylene plants. Typically used in the coldest part of an ethylene plant, a cold box is usually supplied to perform the hydrogen purification requirements. Hydrogen purification typically is performed at temperatures well below -200°F and requires the use of  two or more brazed aluminum exchangers, two process vessels, knock out drums, and cryogenic control valves. Although it is possible to mechanically insulate these components and its piping system, it is usually much more practical and economical to package the hydrogen purification system in a cold box.

Example of Heat Exchangers and Ethylene Extraction In ethylene plants, brazed aluminum exchangers offer the advantage of pinch technology optimizing the refrigeration systems by tight approach temperatures and reducing refrigeration horsepower. Since brazed aluminum exchangers can accommodate as many as 15 streams, complex refrigeration schemes can be accomplished in services such as the ethylene recovery/purification train and the H2 purification unit. As an example of the advantages of tighter approach temperature on refrigeration horsepower, we offer an example of a 12 MM BTU/hr Ethylene condenser (load) operating at  –146.3 F @ 19.5 psia. Figure 8  shows a cascade refrigeration system utilizing tubular  exchangers with 10 F approach temperatures. A simple cycle with 2 propylene refrigeration loops and one ethylene refrigeration loop was selected for the example. The tubular  exchanger example requires 9,730 HP, excluding utility HP. This equates to a Coefficient of  Performance (COP) of 0.484 BTU refrigeration/BTU power.

Figure 9

Figure 11

Sidebar  FAQs Although the use of brazed aluminum heat exchangers is fairly wide spread and well accepted as practical use in cryogenic processing industries, there remain many questions that are often unknown to the casual user of BAHX due to their special design and manufacturing process. The following issues are just a few that perhaps this paper has not covered or needs to be reiterated due to them often being addressed in industry. 1. How are BAHXs tested? a. A BAHX is first structurally tested. For hydrostatic test methods, each stream is pressurized, with the other streams at zero pressure, to 1.3 times the design pressure per the requirements of ASME. The unit remains pressurized for 5-10 minutes. Pneumatic test methods can be used with the pressure level being adjusted to 1.1-time design pressure. b. Leak testing is performed after the structural test has been successfully performed. Internal leak testing is performed by pressurizing each stream individually and monitoring small nozzle valves on the unpressurized streams using soap film solution. External leak testing is performed using soap solution on the exchanger external joints. c. Helium vacuum leak testing may also be used to validate the leak tightness of an exchanger, usually at an extra expense. 2. Are the exchangers repairable if a leak is detected after the exchanger has been put in service?

sheets, side/end bars, and fins) and 5083 alloy is used in the header and nozzle components. 6061 alloy is usually the alloy of choice for flanged connections. 5. Type of stainless steel to aluminum coupling preferred? a. For mechanical couplings, a RFWN flange is often used. For non-mechanical connections there are a variety of suppliers of stainless to aluminum transition  joints. It is best to consult with the BAHX supplier as to what supplier is recommended. Usually the BAHX supplier has experience with each of the suppliers and is capable of making a qualified recommendation as to which supplier(s) are adequate. 6. What process information is required for specification? a. Contact a BAHX supplier, they can provide a blank data sheet to be filled in. Stream inlet and outlet temperatures and pressures are needed, as are either the physical properties at the inlet/outlet or the stream chemical composition. Chart prefers to receive a customer’s HYSYS file for the specified exchanger since Chart has a program which converts the HYSYS output to Chart’s design program input. 7. Installation concerns? Piping stress on nozzles? a. Consult with the supplier’s installation and operating manual. Usually the supplier will have specified methods of lifting and installing the exchanger. The ALPEMA suppliers will perform thermal expansion/contraction mechanical calculations in order to provide adequate piping strength.

11. What fin types are available? What are their selection criteria? How are new fin designs developed and tested? a. Fin types come in a wide variety from most of the ALPEMA suppliers. They range in height, thickness, configuration (straight, perforated, herringbone, and serrated), and fin count (fins per inch). b. Fins are selected on the basis of required design pressure, thermal performance, and allowable pressure drop. The optimum fin is one that does all of these things at the lowest cost. 12. Corrosion and mercury features a. Chart is the developer and world leader in providing exchangers that are suitable to perform in a mercury environment. Due to the variety of conditions for the exchanger to operate in with mercury present and the proprietary nature of  Chart’s design, Chart recommends that a potential customer speak to us about their individual needs. Please note, Chart has/is presenting a paper about this subject at this conference.

About Chart Industries Chart Industries, Inc. is a leading global supplier of standard and custom engineered products and systems serving a wide variety of low temperature and cryogenic applications. Headquartered in Cleveland, Ohio, Chart has domestic operations located in seven states and an international presence in Australia, China, Czech Republic, Germany and the United

BRAZED ALUMINUM PLATE FIN  HEAT EXCHANGERS – CONSTRUCTION, USES, AND ADVANTAGES IN  CRYOGENIC REFRIGERATION SYSTEMS  paper 44a Presented by: Larry Lewis,

SME Associates

Co-authored by Dan Markussen,

Chart Industries

BAHX’s are Compact, High Performance Designs

• Approx. 10% the weight of CS or SS tubular exchangers • Approx. 20% of the volume of CS or SS tubular exchangers • Single and multiphase, condensing or evaporating service • Complex designs with up to 15 streams are common • Single core modules can exceed 6 MM BTU/hr-F “UA” o

• Approach or pinch temperature of