This disclosure relates to heat exchangers in general, and, more particularly, to heat exchangers, including but not limited to shell-and-tube heat exchangers, employing heat conducting foam material.
Heat exchangers are used in many different types of systems for transferring heat between fluids in single phase, binary or two-phase applications. An example of a commonly used heat exchanger is a shell-and-tube heat exchanger. Generally, a shell-and-tube heat exchanger includes multiple tubes placed between two tube sheets and encapsulated in a shell. A first fluid is passed through the tubes and a second fluid is passed through the shell such that it flows past the tubes separated from the first fluid. Heat energy is transferred between the first fluid and second fluid through the walls of the tubes.
A shell-and-tube heat exchanger is considered the primary heat exchanger in industrial heat transfer applications since they are economical to build and operate. However, shell-and-tube heat exchangers are not generally known for having high heat transfer efficiency.
Shell-and-tube heat exchangers are described that utilize one or more foam heat transfer units engaged with the tubes to enhance the heat transfer between first and second fluids. The foam of the heat transfer units can be any thermally conductive foam material that enhances heat transfer, for example graphite foam. The shell-and-tube heat exchangers described herein are highly efficient, inexpensive to build, and corrosion resistant. The described heat exchangers can be used in a variety of applications, including but not limited to, low thermal driving force applications, power generation applications, and non-power generation applications such as refrigeration and cryogenics. The foam heat transfer units can be made from any thermally conductive foam material including, but not limited to, graphite foam or metal foam.
In one embodiment, a heat exchanger includes a tube having a central axis and an outer surface. A heat transfer unit is connected to and in thermal contact with the outer surface of the tube, with the heat transfer unit having a heat transfer surface extending substantially radially from the outer surface of the tube. The heat transfer unit includes graphite foam. For example, the heat transfer can consist essentially of, or consist of, graphite foam.
In another embodiment, a heat exchanger includes a tube bundle having a central axis and a plurality of tubes for conveying a first fluid. A first tube sheet and a second tube sheet are provided, and each of the tubes includes a first end joined to the first tube sheet in a manner to prevent fluid leakage between the first end and the first tube sheet and a second end joined to the second tube sheet in a manner to prevent fluid leakage between the second end and the second tube sheet. A heat transfer unit is connected to and in thermal contact with the tubes, with the heat transfer unit consisting essentially of graphite foam.
One suitable method for connecting the tubes and the tube sheets is friction-stir-welding (FSW). The use of FSW is particularly beneficial in heat exchanger applications subject to corrosive service, since the FSW process eliminates seams, no dissimilar metals are used and, in the case of saltwater environments, no galvanic cell is created.
In another embodiment, the heat transfer unit is in the form of a generally radiused and wedge-shaped, planar body that consists essentially of foam material, for example graphite foam.
The body includes first and second opposite major surfaces, a support rod hole or cut-out extending through the body from the first major surface to the second major surface, an arcuate radially outer edge connected to linear side edges at opposite ends of the outer edge, and at least two tube contact surfaces opposite the radially outer edge. In other embodiments, the heat transfer units can be a combination of radiused and triangular or square shaped to fit in the pitch space between tubes. All of the heat transfer units described herein can be used by themselves or together in various combinations that one finds suitable to increase the heat transfer efficiency of the heat exchanger.
In an embodiment, the tubes can be twisted around a foam heat transfer unit. In addition, each tube can be twisted around its own axis to further increase heat transfer efficiency.
The tubes of the shell-and-tube heat exchangers described herein can be arranged in numerous patterns and pitches, including but not limited to, an equilateral triangular pattern defining a triangular pitch between tubes, a square pattern defining a square pitch between tubes, and a staggered square pattern defining a square or diamond pitch between tubes.
The shell-and-tube heat exchangers described herein can also be configured to have any desired flow configuration, including but not limited to, cross-flow, counter-current flow, and co-current flow. In addition, the tubes can have any desired tube layout/configuration including, but not limited to, single pass and multi-pass. Further, the shell, tubes, tube sheets, and other components of the described heat exchangers can be made of any materials suitable for the desired application of the heat exchanger including, but not limited to, metals such as aluminum, titanium, copper and bronze, steels such as carbon steel and high alloy stainless steels, and non-metals such as plastics, fiber-reinforced plastics, thermally enhanced polymers, and thermoplastics.
The first fluid and the second fluid are at different temperatures. For example, the first fluid can be at a lower temperature than the second fluid so that the second fluid is cooled by the first fluid.
During operation, the first fluid enters through the inlet 24 and is distributed by the manifold or plenum 18 to the tubes 12 whose ends are in communication with the plenum 18. The first fluid flows through the tubes 12 to the second end of the tubes and into the output plenum 20 and then through the outlet 26. At the same time, the second fluid is introduced into the shell 22 through the inlet 28. The second fluid flows around and past the tubes 12 in contact with the outer surfaces thereof, exchanging heat with the first fluid flowing through the tubes 12. The baffles 16 help increase the flow path length of the second fluid, thereby increasing the interaction and residence time between the second fluid in the shell-side and the walls of tubes. The second fluid ultimately exits through the outlet 30.
Turning to
The heat exchanger 50 includes a shell 52 and a tube bundle 54 that is configured to be disposable in the shell 52. In the illustrated embodiment, the shell 52 includes an axial inlet 56 at a first end for introducing a first fluid and an axial outlet 58 at the opposite second end for the first fluid. In addition, the shell includes a radial inlet 60 near the first end for introducing a second fluid and a radial outlet 62 near the second end for the second fluid.
The shell 52 is configured to enclose the tube bundle 54 and constrain the second fluid to flow along the surfaces of tubes in the tube bundle. The shell 52 can be made of any material that is suitably resistant to corrosion or other effects from contact with the type of second fluid being used, as well as be suitable for the environment in which the heat exchanger 50 is used. For example, the shell can be made of a metal including, but not limited to, steel or aluminum, or from a non-metal material including, but not limited to, a plastic or fiber-reinforced plastic.
The tube bundle 54 extends substantially the length of the shell and includes a plurality of hollow tubes 64 for conveying the first fluid through the heat exchanger 50. The tubes 64 are fixed at a first end 66 to a first tube sheet 68 and fixed at a second end 70 to a second tube sheet 72. As would be understood by a person of ordinary skill in the art, the tube sheets 68, 72 are sized to fit within the ends of the shell 52 with a relatively close fit between the outer surfaces of the tube sheets and the inner surface of the shell. When the tube bundle 54 is installed inside the shell 52, the tube sheets of the tube bundle and the shell collectively define an interior chamber that contains the tubes 64 of the tube bundle. The radial inlet 60 and radial outlet 62 for the second fluid are in fluid communication with the interior chamber. Due to the closeness of the fit and/or through additional sealing, leakage of the second fluid from the interior chamber of the shell past the interface between the outer surfaces of the tube sheets 68, 72 and the inner surface of the shell is prevented.
As shown in
FSW is a known method for joining elements of the same material. Immense friction is provided to the elements such that the immediate vicinity of the joining area is heated to temperatures below the melting point. This softens the adjoining sections, but because the material remains in a solid state, the original material properties are retained. Movement or stirring along the weld line forces the softened material from the elements towards the trailing edge, causing the adjacent regions to fuse, thereby forming a weld. FSW reduces or eliminates galvanic corrosion due to contact between dissimilar metals at end joints. Furthermore, the resultant weld retains the material properties of the material of the joined sections. Further information on FSW is disclosed in U.S. Patent Application Publication Number 2009/0308582, titled Heat Exchanger, filed on Jun. 15, 2009, which is incorporated herein by reference.
The tubes 64 and the tube sheets 68, 72 are preferably made of the same material, such as, for example, aluminum, aluminum alloy, or marine-grade aluminum alloy. Aluminum and most of its alloys, as well as high alloy stainless steels and titanium, are amenable to the use of the FSW joining technique. The tubes and tube sheets can also be made from other materials such as metals including, but not limited to, high alloy stainless steels, carbon steels, titanium, copper, and bronze, and non-metal materials including, but not limited to, thermally enhanced polymers or thermoset plastics.
Other joining techniques can be used to secure the tubes and the tube sheets, such as expansion, press-fit, brazing, bonding, and welding (such as fusion welding and lap welding), depending upon the application and needs of the heat exchanger and the user.
In the example illustrated in
It is preferred that the tubes be made of a material, such as a metal like aluminum, that permits extrusion or other seamless formation of the tubes. By eliminating seams from the tubes, corrosion is minimized.
The tube bundle 54 also includes a baffle assembly 80 integrated therewith. In the illustrated embodiment, the baffle assembly 80 is formed by a plurality of discrete (i.e. separate) heat transfer units 82 that are connected to each other so that the baffle assembly 80 has a substantially helix-shape that extends along the majority of the length of the tube bundle 54 around the longitudinal axis of the tube bundle. More preferably the helix-shaped baffle assembly 80 formed by the heat transfer units 82 extends substantially the entire axial length of the tube bundle.
The baffle assembly 80 increases the interaction time between the second fluid in the interior chamber of the shell and the walls of the tubes 64. Further, as described further below, the heat transfer units 82 forming the baffle assembly are made of material that is thermally conductive, so that the baffle assembly 80 effectively increases the amount of surface area for thermal contact between the tubes and the second fluid. In addition, the substantially helix-shaped baffle assembly 80 substantially reduces or even eliminates dead spots in the interior chamber of the shell. The helix-shaped baffle assembly 80 can reduce pressure drop, reduce flow restriction of the fluid, and reduce the required force of pumping, yet at the same time provide directional changes of the second fluid to increase interaction between the second fluid and the tubes. Thus, the baffle assembly 80 provides the heat exchanger 50 with greater overall heat transfer efficiency between the second fluid and the tubes.
In an embodiment, the heat transfer units 82 can be strengthened by the use of solid or perforated plates, made from a thermally conductive material such as aluminum, affixed to the heat transfer units 82. The plates can be affixed to the units 82 in a periodic pattern along the helix, or they can be affixed to the units in any arrangement one finds provides a suitable strengthening function. The plates can be used to assist in the assembly of the tube bundle and the heat exchanger, and can assist with minimizing the pressure drop on the shell-side flow.
Referring to
The body 84 includes a first major surface 86 and a second major surface 88 opposite the first major surface. In the illustrated embodiment, the major surfaces 86, 88 are substantially planar. However, one or more of the major surfaces 86, 88 need not be planar and could have contours or be shaped in a manner to facilitate fluid flow across or past the unit 82. Fin patterns shown in
The perimeter of the body 84 is defined by an arcuate radially outer edge 92 connected to linear side edges 94, 96 at opposite ends of the outer edge. The side edges 94, 96 converge toward a common center 98 which is removed during formation of the unit 82. The side edges 94, 96 terminate at radiused tube contact surfaces 100, 102, respectively, that are positioned on the body 84 opposite the radially outer edge 92.
Each of the contact surfaces 100, 102 is configured to connect to an outer surface of one of the tubes 64 for establishing thermal contact between the heat transfer unit 82 and the tubes. To maximize thermal contact, the contact surfaces 100, 102 are configured to match the outer surface of the tubes 64. In the illustrated embodiment, the contact surfaces 100, 102 are curved, arcuate, or radiused to generally match a portion of the outer surface of the tubes 64. However, the contact surfaces 100, 102 can have any shape that corresponds to the shape of the tubes, for example square or rectangular, triangular, oval, or any other shape, and combinations thereof.
The body 84 also includes a finger section 104 that in use extends between the two tubes 64 engaged with the contact surfaces 100, 102. The finger section 104 includes linear edges 106, 108 that extend from the contact surfaces 100, 102 and that terminate at a third tube contact surface 110 that is configured to contact an outer surface of a third tube 64 for establishing thermal contact with the third tube. The contact surface 110 is configured to match the outer surface of the third tube. In the illustrated embodiment, the contact surface is slightly curved or arcuate to generally match a portion of the outer surface of the third tube. However, the contact surface 110 can have any shape that corresponds to the shape of the third tube, for example square or rectangular, triangular, oval, or any other shape, and combinations thereof. In certain embodiments, for example where contact between the body 84 and a third tube is not desired or where there is insufficient space between the tubes for the finger section to extend through, the finger section 104 can be eliminated.
The heat transfer units 82 are mounted on the tube bundle 54 with the outer edges 92 thereof facing radially outward. A support rod 120 extends through the hole 90 or other opening and the tube contact surfaces 100, 102, 110 are in thermal contact with outer surfaces of three separate tubes 64. When in thermal contact with the tubes, the major surfaces 86, 88 form heat transfer surfaces that extend substantially radially from the outer surfaces of the tubes. As used herein, “in thermal contact” includes direct or indirect contact between the tube contact surfaces and the tubes to permit transfer of thermal energy between the tube contact surfaces and the tubes. Indirect contact between the tube contact surfaces and the tubes could result from the presence of, for example, an adhesive or other material between the tube contact surfaces and the surfaces of the tubes. When a hole is used, the hole 90 is preferably sized such that a relatively tight friction fit is provided with the support rod 120 to prevent axial movement of the heat transfer unit on the rod. If desired, fixation of the heat transfer unit 82 on the rod 120 can be supplemented by fixation means, for example an adhesive between the hole 90 and the rod. Instead of the hole, a slot can be formed that receives the support rod which can be secured via a friction fit or bonded using an adhesive.
If adhesive bonding is used, the adhesive can be thermally conductive. The thermal conductivity of the adhesive can be increased by incorporating ligaments of highly conductive graphite foam, with the ligaments in contact with the surfaces heat transfer unit(s) and the tubes, and the adhesive forming a matrix around the ligaments to keep the ligaments in intimate contact with the tubes and heat transfer units. The ligaments will also enhance bonding strength by increasing resistance to shear, peel and tensile loads.
As best seen in
The periodicity of the helix can be changed by altering the angle of rotation of the heat transfer units. For example, the helix can have an angle of 30 degrees, 60 degrees, 90 degrees, 120 degrees, 150 degrees, 180 degrees and other angles. A person having ordinary skill in the art can determine the desired angles of rotation depending upon, for example, the desired performance of the heat exchanger.
In addition, as discussed above, a metal plate (
When the tube bundle is installed in the shell 52, the heat transfer units 82 are also sized such that the radially outer edges 92 thereof are positioned closely adjacent to, or in contact with, the interior surface of the shell to minimize or prevent the second fluid flowing in the shell from flowing between the radially outer edges 92 and the interior surface. This forces the majority of the fluid to flow past the tubes 64 in a generally spiral flow path defined by the heat transfer units 82. In some embodiments, the heat transfer units 82 need not overlap, but can instead be sized and mounted so as to have gaps between adjacent heat transfer units to permit some of the fluid to flow axially between the adjacent heat transfer units.
The unit 82 (as well as the heat transfer units described below) includes, consists essentially of, or consists entirely of, a foam material such as graphite foam or metal foam. The term foam material is used herein to describe a material having closed cells, open cells, coarse porous reticulated structure, and/or combinations thereof. Examples of metal foam include, but are not limited to, aluminum foam, titanium foam, bronze foam or copper foam. In an embodiment, the foam material does not include metal such as aluminum, titanium, bronze or copper.
In one embodiment, the foam material is preferably graphite foam having an open porous structure. Graphite foam is advantageous because graphite foam has high thermal conductivity, a mass that is significantly less than metal foam materials, and has advantageous physical properties, such as being able to absorb vibrations (e.g. sound). Graphite foam can be configured in a wide range of geometries based on application needs and/or heat transfer requirements. Graphite foam can be used in exemplary applications such as power electronics cooling, transpiration, evaporative cooling, radiators, space radiators, EMI shielding, thermal and acoustic signature management, and battery cooling.
In
As shown by the arrows in
With each of the heat transfer units 150, 160, they can be used by themselves, with each other, or with the heat transfer units 82. In addition, when the heat transfer units 150, 160 are mounted on the tubes 64, the outer surfaces of the heat transfer units 150, 160 preferably are in thermal contact with, directly or indirectly, the outer surfaces of the heat transfer units 150, 160 of one or more adjacent tubes 64.
Depending upon the layout of the heat transfer units 174, the heat transfer units can create offsets, spirals or other flow patterns, in either counter, co-current or cross-flow arrangements.
In
The heat transfer units 192 may be arranged as required for heat transfer efficiency and/or providing directional flow of the fluid outside the tubes 190. For example, the heat transfer units 192 can be arranged in any configuration to mimic a helix, multiple helix, offset baffle, offset blocks, or other patterns as shown in
A person of ordinary skill in the art would realize that the tubes can be arranged with other pitch shapes between the tubes, and that the foam heat transfer units can have other corresponding shapes as well.
With reference to
The heat exchanger 200 includes a shell 206 that has axial inlets and outlets at each end for a first fluid to flow into and out of the tubes 202. Tubes sheets, similar to the tube sheets 68, 72 would be provided at each end of the tube bundle, would be attached to each tube 202, and would fit within and close off the ends of the shell 206. The shell also includes a radial inlet 208 and a radial outlet 210 for a second fluid.
In this embodiment, the tubes 202 are twisted helically around the foam heat transfer unit 204 along the length of the heat transfer unit 204. The heat transfer unit 204 comprises a central, solid body of foam such that at any cross-section of the tube bundle, the foam body forms a heat transfer surface extending substantially radially from the outer surface of the tube(s). In
Although
Returning to
This twisted tube concept can be used by itself or in combination with any of the embodiments previously described herein. For example,
The heat transfer units 204, 230 have been described above as being solid bodies. However, the heat transfer units 204, 230 need not be solid. Instead, the heat transfer units 204, 230 can function as fluid carrying fluid distribution tubes which would be useful for creating a baffle-less design in a spray evaporator. For example, with reference to
All of the shell-and-tube heat exchangers described herein operate as follows. A first fluid is introduced into one axial end of the tubes of the tube bundles, with the fluid flowing through the tubes to an outlet end where the first fluid exits the heat exchanger. The tubes can be single pass or multi-pass. Simultaneously, a second fluid is introduced into the shell. The second fluid can flow counter to the first fluid, in the same direction as the first fluid, or in a cross-flow direction relative to the flow direction of the first fluid. As the second fluid flows through the shell, it contacts the outer surfaces of the tubes and/or the surfaces of the heat transfer units. Because the first fluid flows within the tubes, separated from the second fluid, heat is exchanged between the first and second fluids.
Depending upon the application, the first fluid can be at a higher temperature than the second fluid, in which case heat is transferred from the first fluid to the second fluid via the tubes and the heat transfer units. Alternatively, the second fluid can be at a higher temperature than the first fluid, in which case heat is transferred from the second fluid to the first fluid via the tubes and the heat transfer units.
The first and second fluids can be either liquids, gases/vapor or a binary mixture thereof. One example of a first fluid is water, such as sea water, and one example of a second fluid is ammonia in liquid or vapor form, which can be used in an Ocean Thermal Energy Conversion system.
The examples disclosed in this application are to be considered in all respects as illustrative and not limitative. The scope of the invention is indicated by the appended claims rather than by the foregoing description; and all changes which come within the meaning and range of equivalency of the claims are intended to be embraced therein.
This application claims the benefit of U.S. Provisional Applicant Ser. No. 61/439,564, filed on Feb. 4, 2011, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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61439564 | Feb 2011 | US |