Method of making a thick, low cost liquid heat transfer plate with vertically aligned fluid channels

Abstract

A process for fabricating a low-cost high-efficiency liquid cold plate is described. The process uses a metal extrusion designed with internal fluid channels that have their major cross-sectional axes aligned perpendicular to the major surfaces of the extrusion. Particular dimensions for the cross-sections of the fluid channels and their spacings permit the extrusion process to be performed simply. A simple process for fabricating fluid inlet and outlet manifolds, creating turbulent flow inside the fluid channels, a method for capping the extrusion ends, and a method for improving the surface contact with heat generating components is described.

Description

BACKGROUND OF THE INVENTION

Many types of equipment require some means of temperature control, either by heating or cooling, in order to function effectively. In general, such equipment consists of three elements: The component requiring temperature control, a heat transfer device, and a medium acting as a thermal energy sink or source. Some equipment, such as those that transfer heat from one medium to another, require heat transfer devices for supplying and removing heat.

In general, equipment which require small amounts of, or low watt-density, cooling, use natural or forced convection air cooling. On the other hand, equipment which requires large amounts of, or high watt-density, cooling, or precise temperature control, or operating temperatures at or below ambient air temperature use something other than air for cooling. Such techniques incorporate liquid cooling, thermoelectric cooling, or Freon compressor/condenser cooling.

In the home refrigerator, for example, heat is transferred from the inside of the refrigerator cabinet to the air outside. The refrigeration unit has two heat transfer devices. Inside the refrigerator there is typically an extruded air heat sink and fan which provides forced air convection to remove heat from the source medium, the air inside the refrigerator, and to transfer the heat to the refrigeration unit. Outside the refrigerator, heat from the refrigeration unit is transferred by an external radiator via natural convection into the heat sink medium, i.e., the surrounding air. However, for other applications that require a more efficient thermal energy transport system, liquids can readily provide the medium by which heat is transferred.

The transfer of heat by a liquid medium is often accomplished with a heat transfer plate, sometimes called a “cold plate”. A cold plate is typically a flat metal plate in contact with a flowing fluid. Thermally conductive metals, such as aluminum or copper, are commonly used for the plate, although other metals, such as stainless steel, may be used in corrosive environments. Components requiring temperature control are mounted onto an exterior surface of the cold plate.

The thermal efficiency of the cold plate depends upon the amount of surface area of the cold plate in contact with the flowing fluid, the degree of turbulence of the flowing fluid, and the efficiency of thermal contact between the components and the cold plate. It is desirable for a liquid cold plate to have a high degree of thermal efficiency, while at the same time be simple and inexpensive to manufacture. Simple and low-cost manufacturing is commonly achieved with a cold plate formed by a flat aluminum plate with copper tubing glued or pressed into grooves in the surface of the aluminum plate. Such designs have very low surface areas in contact with the flowing fluid, which provide limited heat transfer and have very high pressure drops to limit the amount of coolant that can be used. On the other hand, high efficiency heat transfer is commonly achieved with cold plates that have a large amount of surface area in contact with the cooling fluid. Such cold plates are typically either not flat and complex (e.g., shell and tube designs), or very expensive to manufacture (e.g., brazed plate-fin designs).

One example of cold plate use is the environment friendly, hybrid diesel/electric vehicles. Such vehicles have both diesel engines and electric motors for propulsion and use only half the fuel of standard diesel vehicles. The electronic components used to drive the electric motor generate considerable heat in a small area (approximately 100 watts/sq.in.) that must be transferred to the coolant system and ultimately transferred to the ambient air via the radiator. High-efficiency, low pressure drop, liquid cold plates must be used to transfer this heat into the coolant. Presently, only brazed plate-fin heat exchangers meet both these requirements. Unfortunately, brazed plate-fin heat exchangers are very expensive and thus drive up the costs of the vehicles, which slow their introduction into the marketplace.

Thus the desire for cold plates which are simple and easy-to-manufacture at low costs conflicts with the desire for cold plates with high heat transfer efficiency. However, the present invention resolves these conflicting desires with a cold plate that has high heat transfer, but which is also simple and inexpensive to manufacture. The present invention provides the same attributes of brazed plate-fin cold plates, high rates of heat transfer and low pressure drop, at only a fraction of the costs.

SUMMARY OF THE INVENTION

The present invention provides for a liquid heat transfer plate formed from a unitary, one-piece, plate which has a first flat surface and an opposite second flat surface and a plurality of fluid channels between said first and second surfaces. Each of the fluid channels has a cross-section with a major axis perpendicular to the first and second surfaces, and a minor axis perpendicular to and shorter than the major axis. The plate also has first and second ends perpendicular to the fluid channel direction and a first manifold near the first plate end. The manifold is perpendicular to the fluid channel and is fluidly connected to the fluid channel. The plate also has a second manifold near the second plate end perpendicular to the fluid channel and fluidly connected to the fluid channel. First and second caps fixed to the first and second plate ends respectively seal the fluid channel in the plate.

The present invention also provides for a process of manufacturing a heat transfer plate. A preform having first surface and a second surface opposite the first surface and a plurality of fluid channels in a first direction between the first and second surfaces is first extruded. Each of the fluid channels has a cross-section perpendicular to the first direction, with the cross-section having a major axis perpendicular to the first and second surfaces, and a minor axis perpendicular to and shorter than the major axis. Then the preform is cut in a second direction perpendicular to the first direction to define a plate having first and second ends. A first manifold is drilled near the first plate end perpendicular to the fluid channel so that the fluid channel is fluidly connected to the first manifold. A second manifold is drilled near the second plate end perpendicular to the fluid channel so that the fluid channel is fluidly connected to the second manifold. First and second caps are fixed to the first and second plate ends respectively to seal the fluid channel in the plate, and at least one of the first and second surfaces of the plate is leveled.

The resulting heat transfer plate is inexpensive to manufacture, flexible in design, and has high heat transfer performance capabilities.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional perspective view of an extrusion preform of the heat transfer plate according to an embodiment of the present invention;

FIG. 2 is a detailed cross-section of one of the fluid channels in the extrusion preform of FIG. 1 ;

FIG. 3A is a top view of a heat transfer plate formed from the extrusion of FIG. 1 ;

FIG. 3B is a cross-sectional view along line B-B′ in FIG. 3A ;

FIG. 3C is a cross-sectional view along line C-C′ in FIG. 3A ;

FIG. 3D is an external side view of the heat transfer plate perpendicular to the line C-C′ in FIG. 3A ;

FIG. 4A is a top view of the heat transfer plate with the end caps;

FIG. 4B is a detailed view of one of the end caps of FIG. 4A ; and

FIG. 4C is a side view of heat transfer plate of FIG. 4A ;

FIG. 5A is a partial cross-section of a fluid channel with a wire mesh;

FIG. 5B is a partial cross-section of a fluid channel with expanded metal; and

FIG. 6A is a cross-sectional view of an extrusion preform of the heat transfer plate according to another embodiment of the present invention;

FIG. 6B is a detailed cross-section of one of the fluid channels in the extrusion preform of FIG. 6 A.

DESCRIPTION OF THE SPECIFIC EMBODIMENTS

The heat transfer plate, i.e., the cold plate, of the present invention starts with an extruded preform 10 , as illustrated in FIG. 1 . An extrusion die is designed so that the preform 10 has a rectangular shape with cavities 11 in the direction of the extrusion. One or both of the large, flat parallel surfaces 21 and 22 become heat transfer surfaces in the completed heat transfer plate. The cavities 1 1 extend the length of the extrusion preform 10 and serve as fluid channels for the resulting heat transfer plate. As shown, each of the cavities 11 is elliptical in cross-section, but other cross-sections, such as slotted, circular, rectangular, polygonal, and hourglass shapes, have also been found to be effective. The advantage of elliptical channels is that they facilitate extrusion of the preform 10 ; the other shapes, while equally effective at heat transfer, raise the costs of the extrusion die and tend to complicate the manufacturing process. Ultimately, manufacturing costs are increased.

The extrusion die is also designed so that the inner surfaces of the cavities 11 are lined with ridges 12 , as shown in the detail of FIG. 2 . The ridges 12 increase the surface area of the surfaces of the fluid channels for convective heat transfer to improve the heat transfer plate's efficiency. For example, the ridges 12 with a cross-sectional “saw-tooth” shape, 0.020 inches high and 0.020 inches apart, increase the heat transfer surface area by over a factor of two. Besides the triangular sawtooth shape, the ridges 12 could also have other cross-sectional shapes, such as rectangular, hemispherical or trapezoidal. However, the triangular cross-section of the ridges 12 maximizes the heat transfer area without overly complicating the preform extrusion process. During the extrusion process, any small-scale surface feature added to the inner surfaces of the fluid channels 11 increases friction between the molten metal and the extrusion die. This slows the rate of extrusion and causes uneven metal flow. The greater the fluid channel surface area, the more friction is created during extrusion. The triangular sawtooth ridges 12 represent a good compromise between increased heat transfer and increased extrusion complexity (and manufacturing costs).

While other metals may be used, it has been found that an extruded aluminum alloy works effectively for the preform 10 . The dimensions of the extruded preform 10 are approximately 6 inches across and about an inch thick. Each of the six cavities 11 is approximately 1.5 inches wide and about 0.2 inches high. The particular dimensions of the preform 10 and the locations and design of the cavities are well-suited for low-cost manufacturing for the liquid channel elements of a thermoelectric heat exchanger, such as that described in U.S. Pat. No. 5,584,183, which issued Dec. 17, 1996 to Lloyd Wright et al. and is assigned to the present assignee. The described embodiment is also very well suited to withstand the applied clamping pressures which hold the various elements of the thermoelectric heat exchanger together, while maintaining the required heat transfer efficiencies. For other requirements, the other designs for the extruded preform 10 can be easily implemented for low-cost heat transfer plates, according to the present invention.

The extrusion preform 10 is then cut to the desired length so that the preform 10 has ends 13 , as shown in the top view of FIG. 3 A. Fluid inlet and outlet manifolds 14 A and 14 B are drilled near both ends 13 of the extrusion 10 in a direction perpendicular to the internal cavities 11 . FIG. 3B , a cross-sectional view along line B-B′ in FIG. 3A , illustrates one of the perpendicular holes forming the manifold 14 A. The manifold 14 A is drilled with a diameter sufficiently large and sufficiently deep into the preform 10 so that all internal cavities 11 are fluidly connected to the drilled fluid manifold 14 A. The other fluid manifold 14 B is similarly created as illustrated in FIG. 3C , a cross-sectional view along line C-C′ in FIG. 3 A. FIG. 3C shows that the manifold 14 B along its length and its fluid connection to all of the fluid cavities 11 .

The fluid manifolds 14 A and 14 B are sized to match standard drill diameters required for the subsequent tapping of pipe threads or straight SAE type threads at the entrance to each of the holes forming the manifolds 14 A and 14 B. The standard sizing avoids the need for special tools and parts. The resulting pipe threads 15 engage fittings to make fluid connections to the manifolds 14 A and 14 B. The threads 15 of the manifold 14 B are illustrated in the cross-sectional side view in FIG. 3 C and in the FIG. 3D side view, which illustrates the entrance to the manifold 14 B, in a direction perpendicular to the line C-C′ of FIG. 3 A.

As illustrated in FIG. 4A , cap plates 16 are fixed on each end 13 to seal the internal cavities 11 . The cap plates may be welded. FIG. 4B shows a fillet weld 17 at an edge of a cap plate 16 and the end 13 of the preform 10 . Full penetration welds for the cap plates 16 create excellent seals against leaks and can withstand very high pressures. Welding is well-characterized and relatively inexpensive. To minimize warping the preform 10 , the preform is preheated before welding the cap plates 16 .

Alternatively, the cap plates 16 may be fixed by being brazed, soldered, or glued to the ends 13 of the extrusion preform 10 . Brazing provides an excellent high-pressure seal against leaks; however, brazing is more expensive and is more prone, compared to welding, to leave undesirable voids in the sealing surface for leaks. Soldering has the same disadvantages as brazing. Furthermore, soldering with aluminum is very difficult unless the aluminum is coated with zinc, an additional manufacturing expense. Gluing, on the other hand, provides manufacturing at the lowest cost; nonetheless, the glued bonds are weakest compared to the other processes and cannot withstand high pressure. A consistent gluing process is difficult to achieve and hence, the glued bonds are considered the least reliable.

Finally, while the surfaces 21 and 22 of the preform 10 are nominally flat, they may not be sufficiently flat enough for optimum heat transfer. Thus one or both of the surfaces 21 and 22 is ground flat as needed before the assembled heat transfer plate is mounted to the heat generating components. Alternatively the surfaces 21 and 22 may be machined or lapped. Furthermore, to improve heat transfer inside the cavities 11 forming the fluid channels of the assembled heat transfer plate, expanded metal strips, a wire mesh, or other such material can be inserted inside the cavities 11 (and manifolds 14 A and 14 B) to break up laminar flow boundary layers to create turbulent flow. FIG. 5A illustrates a wire mesh turbulator 29 inside a cavity 11 and FIG. 5B illustrates an expanded metal turbulator 28 inside a cavity 11 .

An improvement in the heat transfer plate of the present invention is illustrated in FIGS. 6A and 6B . In this case, an extrusion preform 30 has cavities 31 , which form the fluid channels of the heat transfer plate, having their major axes are aligned perpendicular to surfaces 41 and 42 of the preform 30 . In effect, the cavities 11 of the preform 10 in FIG. 1 are rotated 90°. This new arrangement is suitable for “thick” heat transfer plates, i.e., plates having thicknesses greater than 0.5 inches. The metal between the resulting fluid channels formed by the cavities 31 acts as fins to dissipate heat into adjacent channels and is more efficient than the arrangement illustrated in FIG. 1 in which one set of parallel channels is underutilized in the heat transfer process.

However, there are difficulties in extruding a preform with such vertical cavities. With the proper sizing of the cavities 31 and the spacing between the cavities, as follows, the difficulties of the extrusion processes can be solved. Specifically, the width of the minor axis 33 of each cavity 31 should be in the range of 0.75-1.25, preferably 0.9-1.1, times the distance of the spacing 34 between the cavities 31 ; and the distance of the spacing 35 between each of the surfaces 41 and 42 and the cavities 31 should be at least 0.9 times the width of the minor axis 33 of each cavity 31 . The length of the major axis 32 of each cavity 31 should be at least 2 times, and preferably at least 3 times, the width of the minor axis 33 to optimize the total heat transfer area of the resulting fluid channel. The spacing 36 between the edge of the preform 30 (and resulting plate) and the nearest cavity 31 should be at least equal to the width of the cavity 31 , and preferably wide enough to accommodate any mounting holes 37 drilled into the preform 30 .

In passing, even though the cavities 31 are shown as having a cross-sectional shape of a slot with rounded edges, it should be realized that other shapes besides slots, such as ellipses, may be used.

To complete the heat transfer plate, the operations described previously with respect to the preform 10 are performed on the preform 30 . For example, the inner surfaces of the cavities 31 are created with ridges 42 to increase the surface area of the fluid channels.

The results of a heat transfer plate with the vertically oriented fluid channels are surprising. An extruded 6″×12″ heat transfer plate using a preform like that illustrated in FIG. 1 was created with six fluid channels having elliptical cross-sections of 1.5″×0.188″. The fluid channels had a total surface area of 544 in. 2 with inserted expanded metal turbulators. A thermal resistance of 0.0056° C./Watt with 4 gpm of water flow was found. In contrast, an extruded 5.5″×12″ heat transfer plate using a FIG. 6A preform was created with eleven fluid channels having slotted cross-sections of 0.625″×0.188″. The fluid channels had a total surface area of 430 in. 2 with inserted expanded metal turbulators. A thermal resistance of 0.0036° C./Watt was measured, a 50% improvement in heat transfer efficiency with a smaller surface area.

Although the foregoing invention has been described in some detail by way of illustration and example, for purposes of clarity of understanding, it will be obvious that certain changes and modifications may be practiced within the scope of the appended claims.

Claims

1. A process of manufacturing a heat transfer plate comprisingextruding a preform having a first surface and a second surface opposite said first surface and a plurality of fluid channels in a first direction between said first and second surfaces, each of said fluid channels having a cross-section perpendicular to said first direction, said cross-section having a major axis perpendicular to said first and second surfaces, and a minor axis perpendicular to and shorter than said major axis; cutting said preform in a second direction perpendicular to said first direction to define a plate having first and second ends from said preform; drilling a first manifold near said first plate end perpendicular to each of said fluid channel, said fluid channel fluidly connected to said first manifold; drilling a second manifold near said second plate end perpendicular to said fluid channel, said fluid channel fluidly connected to said second manifold; fixing first and second caps to said first and second plate ends respectively; and leveling at least one of said first and second surfaces of said plate.

2. The process of claim 1 wherein in said extruding step said major axis is at least two times longer than said minor axis.

3. The process of claim 2 wherein in said extruding step said major axis is at least three longer than said minor axis.

4. The process of claim 1 wherein in said extruding step separating said fluid channels by a spacing so that said minor axis is in the range of 0.75 to 1.25 times said spacing in said cross-section perpendicular to said first direction.

5. The process of claim 4 wherein said minor axis is in the range of 0.9 to 1.1 times said spacing.

6. The process of claim 1 wherein in said extruding step separating said fluid channels from said first flat surface by a distance at least 0.9 times said minor axis.

7. The process of claim 6 wherein in said extruding step separating said fluid channels from said second flat surface by a distance at least 0.9 times said minor axis.

8. The process of claim 1 wherein in said extruding step forming first and second edges of said preform and separating said first edge from a neighboring fluid channel by a distance at least equal to said minor axis.

9. The process of claim 1 wherein said leveling step comprises grinding said at least one of said first and second surfaces.

10. The process of claim 1 wherein in said extruding step separating said first and second surfaces by at least 0.5 in.

11. The process of claim 1 wherein in said extruding step said cross-section to said first direction of said fluid channels comprises a slot.

12. The process of claim 1 wherein in said extruding step said cross-section to said first direction of said fluid channels comprises an ellipse.

13. The process of claim 1 further comprising inserting a strip of expanded metal in each of said fluid channels.

14. The process of claim 1 further comprising inserting a wire mesh in each of said fluid channels.