阅读说明：本技术 用于将主动冷却以低成本扩展到额外冷冻器内壁的独立辅助热虹吸管 (Independent auxiliary thermosiphon for extending active cooling to additional freezer inner walls at low cost ) 是由 D·M·伯科维茨 T·理查兹 于 2018-10-16 设计创作，主要内容包括：辅助热虹吸管具有辅助制冷剂导管,该辅助制冷剂导管带有与冷冻器的内壁导热连接的辅助蒸发段。辅助制冷剂导管包含与主冷却设备的主制冷剂隔离的辅助制冷剂。辅助制冷剂导管还向上延伸到辅助蒸发段上方的高度处的辅助制冷剂导管的辅助冷凝段。热桥与辅助冷凝段物理热接触并且与主制冷设备的主蒸发段的一部分物理热接触。热通过热桥从辅助热虹吸管传递到主制冷剂导管并因此传递到主制冷设备以从冷冻器移除。(The auxiliary thermosiphon has an auxiliary refrigerant conduit with an auxiliary evaporator section in heat conducting connection with the inner wall of the freezer. The secondary refrigerant conduit contains a secondary refrigerant that is isolated from the primary refrigerant of the primary cooling device. The auxiliary refrigerant conduit also extends upwardly to an auxiliary condensing section of the auxiliary refrigerant conduit at a height above the auxiliary evaporating section. The thermal bridge is in physical thermal contact with the auxiliary condensing section and with a portion of the main evaporation section of the main refrigeration appliance. Heat is transferred from the auxiliary thermosiphon to the main refrigerant conduit and hence to the main refrigeration equipment through the thermal bridge for removal from the freezer.)

1. A freezer, having: a freezer cabinet with an inner wall surrounding a cooling space; and a primary cooling apparatus including a primary cooler and a primary refrigerant conduit containing a primary refrigerant, the primary refrigerant conduit having a primary condensing section at the primary cooler and a primary evaporating section, some of the primary evaporating sections being in thermally conductive connection with at least some of the interior walls for transferring heat from the interior walls to the primary cooler, the chiller further comprising:

(a) an auxiliary thermosiphon including an auxiliary refrigerant conduit having an auxiliary evaporation section in thermally conductive connection with an inner wall of the freezer cabinet, the auxiliary thermosiphon containing an auxiliary refrigerant isolated from the main refrigerant, the auxiliary refrigerant conduit further extending upwardly to an auxiliary condensation section at a height above the auxiliary evaporation section; and

(b) a thermal bridge in thermal physical contact with the auxiliary condensing section and in physical contact with a portion of the main evaporation section for transferring heat from the auxiliary thermosiphon to the main refrigerant conduit through the thermal bridge.

2. The freezer according to claim 1, wherein said thermal bridge more particularly comprises:

(a) a central heat conductor having at least one heat receiving channel, each heat receiving channel having a cross-sectional configuration matching at least a portion of an external cross-sectional configuration of the secondary condensing section of the secondary refrigerant conduit, and further having at least one heat discharge channel, each heat discharge channel having a cross-sectional configuration matching at least a portion of an external cross-sectional configuration of the primary evaporating section of the primary refrigerant conduit;

(b) the central heat conductor and the refrigerant conduit are assembled such that at least a portion of the auxiliary condensing section lies along the heat receiving trough and at least a portion of the main evaporating section lies along the heat discharge trough; and

(c) at least one tensioned strap surrounding and clamping together the assembled refrigerant conduit and the central thermal conductor.

3. The chiller according to claim 2 wherein said auxiliary thermosiphon conduit has closed opposite ends forming said auxiliary condensing section, wherein said central thermal conductor has a second said heat-receiving slot, and said closed opposite ends are assembled in said heat-receiving slot, wherein said central thermal conductor has a second said heat-discharge slot, and each of said heat-discharge slots contains a portion of said main evaporation section of said main refrigerant conduit, and wherein the assembled refrigerant conduits are surrounded by and clamped together by a plurality of said bands.

4. The freezer according to claim 2, wherein said auxiliary evaporator section of said auxiliary thermosiphon is in thermally conductive connection with a top interior wall of said freezer cabinet.

5. The freezer according to claim 2, wherein said auxiliary evaporator section of said auxiliary thermosiphon is in thermally conductive connection with a bottom interior wall of said freezer cabinet.

6. The freezer according to claim 2, wherein said auxiliary evaporator section of said auxiliary thermosiphon is in thermally conductive connection with an inner wall of a door of said freezer cabinet.

7. The freezer according to claim 2, wherein said auxiliary evaporator section of said auxiliary thermosiphon is mounted in a heat conductive connection to an inner wall by a heat conductive mounting bracket attached to said auxiliary evaporator section and to said inner wall, said mounting bracket having a spatially varying height and being arranged and distributed on said inner wall in a configuration supporting said auxiliary evaporator section to be inclined to a horizontal plane and to rise continuously upwardly from its lowest height to said thermal bridge.

8. The chiller according to claim 2 wherein said auxiliary refrigerant conduit is loaded to a pressure such that the vapor-liquid equilibrium temperature of said auxiliary refrigerant is at a selected operating temperature of said chiller.

9. A thermal bridge for transferring heat from a relatively warmer body to a relatively cooler body and comprising:

(a) one or more heat outlet pipes thermally connected to the relatively warmer body, and one or more heat receiver pipes thermally connected to the relatively cooler body;

(b) a central heat conductor having one or more outwardly open heat receiving slots, each heat receiving slot having a cross-sectional configuration matching the outer cross-sectional configuration of each heat exhaust tube, the central heat conductor further having one or more heat exhaust slots, each heat exhaust slot having a cross-sectional configuration matching the outer cross-sectional configuration of each heat receiver tube, the central heat conductor being assembled with the tubes such that each heat exhaust tube lies along a heat receiving slot and each heat receiver tube lies along a heat exhaust slot; and

(c) one or more tensioned straps that surround and clamp together the assembled pipes against the central heat conductor.

10. The freezer according to claim 9, wherein said central heat conductor has a plurality of said heat receiving slots, a plurality of said heat discharge slots, a plurality of heat discharge tubes and a plurality of heat receiving tubes, and wherein said heat receiving slots and said heat discharge slots alternate around the periphery of said central heat conductor.

Background

The present invention relates generally to refrigeration or cooling apparatus for freezers of the type that cool a cold space by removing heat from an interior freezer wall, and more particularly to low cost improvements in temperature distribution in cooled wall freezers, particularly ultra-low temperature freezers. By extending the actively cooled inner wall surface at low cost to areas not directly cooled by the main cooling device, an improved temperature distribution is achieved. Improved temperature distribution allows for more reliable and uniform cooling of the contents, as well as reduced operating costs. The present invention is applicable to conventional compression Rankine (Rankine) cycle refrigeration systems and Stirling (Stirling) cycle coolers or cryocooler systems.

Fig. 1-6 illustrate an ultra-low temperature (U L T) freezer that combines structures known in the art with the structures of the present invention as is known in the art, a U L T freezer typically has a vacuum insulated cabinet 10 closed by a vacuum insulated door 12, a double or triple gasket 14 attached to the door 12 provides a seal against heat and moisture from the surrounding environment.

Typically, the freezer is cooled by a combination of cooling devices, which are chillers connected to a refrigerant circuit. A chiller is a mechanical refrigeration machine that removes heat from a refrigerant and condenses the refrigerant. The cooler is connected to a refrigerant circuit having a refrigerant conduit containing a refrigerant that transfers heat from within or around the interior cooling space to the cooler. The term "conduit" is used in this specification to refer to a refrigerant conduit that is part of a refrigerant circuit that carries refrigerant through its internal passages. Due to the high pressure of the refrigerant, the conduits in the refrigerant circuit are usually mainly metal tubes. However, the refrigerant conduit can include other refrigerant channels, including channels formed in the cooler and channels in fittings, manifolds or through sheet metal, such as channels in sheet metal surrounding the freezer compartment of a conventional household refrigerator. Evaporative refrigeration equipment has a refrigerant conduit comprising an evaporation section in which the refrigerant receives heat by evaporation and a condensation section in which the refrigerant discharges heat by cooling and condensation.

The cooler 22 used with the present invention is mounted in the top compartment 16 of the cabinet 10, but some types of coolers can be located at the bottom of the freezer. The invention operates in connection with a cooler 22 known in the prior art and therefore shown symbolically. For example, the cooler 22 may be a Stirling cycle cooler or cryocooler, which is preferred, or a conventional compression Rankine cycle refrigeration system using a compressor and a heat exchanger/condenser.

The present invention is used in conjunction with a main refrigerant circuit of the type known in the art. The primary refrigerant circuit has a continuous refrigerant conduit 18 integrated into or thermally attached to the interior vertical side walls 20 of the freezer cabinet 10 for directly cooling those walls 20. Since the inner wall 20 is exposed to the interior air of the freezer and intercepts heat from the exterior of the freezer, the interior space adjacent to the wall 20 will receive the temperature of the wall 20. The opposite end of the refrigerant conduit 18 is connected to a cooler 22, shown schematically in fig. 2 to 5.

For obvious reasons, the cooling device described above and known in the art will be referred to subsequently as the main cooling device, and its main components are the main cooler 22 and the main refrigerant conduit 18.

Although prior art freezers of the type described have been successful in operation, they have problems that need to be eliminated. Practical considerations in manufacturing the refrigerant conduit that is thermally attached to the cabinet interior wall limit the area of the interior wall that is actively cooled by the primary cooling device. Typically, the top and bottom cabinet walls 24, 24 (not visible) of the interior space and the interior wall of the door 12 are not cooled because the main refrigerant conduit does not follow across and in thermal contact with the interior walls of the top and bottom cabinet walls 24, 12. The reason is that it is difficult to bend the tubular conduit into the necessary configuration. Conventionally, the entire main refrigeration duct is bent and shaped before it is attached to the outer surface of the inner cabinet wall. The main refrigerant conduit 18 needs to be continuously sloped downward from its top to avoid low points or traps (traps) that could cause vapor lock-up. Such a collecting portion is a pipe section slightly lower than the opposite end portion around it, which may allow liquid refrigerant to accumulate in the collecting portion. The accumulated liquid may prevent vapor phase movement through the collection portion, which may impair the performance of the primary cooling apparatus. Of course, it is technically possible to bend the tubular main refrigerant conduit around the corner between the side wall and the top or bottom wall in order to extend the refrigerant conduit above the top or bottom wall. It is also technically possible to form such a main refrigerant conduit with the required slope to avoid low points or traps. However, such a manufacturing process would add significant cost due to the difficulty in bending the tubular conduit in a manner that does not form flow restrictions, low points, or traps.

The result of some cabinet wall areas not being actively cooled by the main cooling device is a poor temperature distribution in the cooling space. Since there is usually no forced convection in a freezer whose inner walls are cooled by the cooling device, poor temperature distribution leads to temperature stratification within the cooling air in the freezer. Heat entering the cooled interior cabinet space through these uncooled surfaces must be removed by the actively cooled walls. This causes temperature gradients and stratification within the freezer, resulting in warmer areas that may damage the sample or product stored within the freezer. Warmer zones within the freezer are typically near the top due to the cumulative effect of convection in the cooled interior cabinet space and the lack of active cooling of the interior top cabinet walls. However, the cumulative effect of the interior cabinet space being so densely packed that convection is impeded, combined with the lack of active cooling of the interior bottom cabinet walls, can result in warmer areas near the interior bottom. An ideal freezer would be one that has no temperature gradient or stratification within the interior space so that the desired interior temperature displayed by the instrument would accurately represent the temperature of the entire contents of the freezer.

Another problem exists due to the spatial variation of temperature in the cooled space within the freezer. The cooling device must cool at least to the lowest temperature within the cooling space. If the operator of the freezer recognizes the presence of the above-described poor temperature profile and attempts to compensate for this problem by lowering the setpoint temperature of the control system of the freezer, the energy consumed by the freezer operation and its cost will increase. The cost of operating a chiller would be reduced if the present invention were able to reduce the spatial temperature distribution in the chiller. The cost will be reduced not only because there is little or no need to compensate for the problematic spatial temperature distribution, but also because the lowest temperature within the freezer will rise and the highest temperature will fall. An increase in the minimum temperature will mean that the main cooling device will require less energy to operate.

It is therefore an object and purpose of the present invention to simplify the construction of freezers by extending active cooling to the top and/or bottom interior walls without the need to bend the main refrigerant conduit into a configuration that attaches to both the side walls and the top and/or bottom wall of the interior cabinet wall of the freezer, thereby reducing the cost of manufacturing a cooled wall freezer.

It is another object and purpose of the present invention to reduce the energy cost of operating a chiller by substantially reducing or eliminating spatial variations in the temperature distribution within the chiller.

Disclosure of Invention

The invention adds a separate auxiliary thermosiphon thermally connected to the main cooling device by a thermal bridge to provide active cooling to components inside the freezer that are not directly cooled by the main cooling device. This thermally spreads the cooling function of the main cooling device by means of the auxiliary thermosiphon to the additional inner wall of the freezer cabinet without extending the main refrigerant conduit to this additional inner wall. The refrigerant of the secondary thermosiphon and the refrigerant of the primary cooling device circulate in separate fluid circuits that are completely separate. The auxiliary thermosiphon is not connected to the pump or compressor. The evaporator section of the main refrigerant conduit is connected to the secondary refrigerant conduit of the secondary thermosiphon by thermal bridges between the respective refrigerant conduits. The thermal bridge is simply a mechanical connection that can be installed after the main refrigerant conduit is installed on the wall of the liner. The thermal bridge is located at a higher elevation portion of the auxiliary thermosiphon, and the auxiliary refrigerant conduit extends downwardly from the thermal bridge into thermal connection with the interior wall of the cabinet. Thus, heat is transferred from the auxiliary thermosiphon to the main cooling device through the thermal bridge.

More specifically, the auxiliary thermosiphon of the present invention has an auxiliary refrigerant conduit with an auxiliary evaporator section in heat conductive connection with the inner wall of the freezer. The auxiliary thermosiphon contains an auxiliary refrigerant that is isolated from the main refrigerant. The auxiliary refrigerant conduit also extends upwardly to an auxiliary condensing section of the auxiliary refrigerant conduit at a height above the auxiliary evaporating section. The thermal bridge is in physical thermal contact with the auxiliary condensing section and in physical thermal contact with a portion of the main evaporating section for transferring heat from the auxiliary thermosiphon to the main refrigerant conduit through the thermal bridge.

Drawings

Fig. 1 is a perspective view of the exterior of a typical ultra-low temperature freezer embodying the present invention.

FIG. 2 is a perspective view of the ultra-low temperature freezer of FIG. 1, but with the outer casing and adjacent insulation removed to expose the inner walls that form the inner lining of its cabinet and also expose the primary cooling apparatus and the auxiliary thermosiphon of the present invention.

FIG. 3 is an enlarged view of a portion of the structure shown in FIG. 2 showing more detail of the thermal bridge connecting the primary cooling device to the auxiliary thermosiphon of the present invention.

Fig. 4 is an exploded view of the structure shown in fig. 2.

Fig. 5 is a top plan view of the embodiment shown in fig. 1-4.

Fig. 6 is a sectional view taken along line a-a in fig. 5.

Fig. 7 is an enlarged sectional view taken along line a-a in fig. 5, showing a segment of the embodiment as shown in fig. 2-6, and showing in detail the mounting bracket for thermally connecting the auxiliary thermosiphon with the horizontal inner wall of the freezer cabinet to hold the thermosiphon in the proper inclined orientation.

Figure 8 is a top plan view of the central thermal conductor of the thermal bridge of the present invention.

Figure 9 is a perspective view of a central thermal conductor of the thermal bridge of the present invention.

FIG. 10 is an enlarged cross-sectional view taken along line 10-10 of FIG. 5, illustrating the assembled thermal bridge of the present invention.

Figure 11 is a side view of a central thermal conductor of the thermal bridge of the present invention.

In describing the preferred embodiments of the present invention illustrated in the drawings, specific terminology will be resorted to for the sake of clarity. However, it is not intended that the invention be limited to the specific terms so selected and it is to be understood that each specific term includes all technical equivalents which operate in a similar manner to accomplish a similar purpose.

Detailed Description

Referring primarily to fig. 2-6, the present invention has an auxiliary thermosiphon formed from an auxiliary refrigerant conduit 26 containing an auxiliary refrigerant, the auxiliary refrigerant conduit 26 has an auxiliary evaporator section 28, the auxiliary evaporator section 28 being mounted in a distributed heat conductive connection to the freezer interior wall 24 that is not in thermal connection with the main refrigerant conduit 18, as shown, the auxiliary evaporator section 28 is thermally connected to the top interior cabinet wall 24.

The auxiliary refrigerant conduit 26 extends upwardly from the auxiliary evaporator section 28 to an auxiliary condenser section 30 of the auxiliary refrigerant conduit 26. The auxiliary condensing section 30 is positioned at a higher elevation than the auxiliary evaporating section 28. Although the ends 32 of the auxiliary refrigerant conduit 26 may be connected together to form a closed loop thermosiphon, it is preferred that only the ends 32 be more simply sealed after evacuation of the auxiliary refrigerant conduit 26 and introduction of the refrigerant charge.

The secondary refrigerant conduit 26 is connected to the primary refrigerant conduit 18 by a thermal bridge 34. The thermal bridge 34 is inserted in close physical contact with the outer surface of the auxiliary condensation section 30 and the outer surface of a portion of the main evaporation section 36 of the main refrigerant conduit 18. The thermal bridge 34 forms a heat-conducting connection that transfers heat from the auxiliary thermosiphon to the main refrigerant conduit 18 of the main cooling device. More specifically, the thermal bridge 34 transfers heat from the auxiliary condensing section 30 to the main evaporating section 36 through the thermal bridge 34 by conduction. In other words, the evaporation in the main refrigerant conduit 18 cools and condenses the refrigerant in the auxiliary refrigerant conduit 26 and transfers heat received from the auxiliary refrigerant to the main condensing section at or in the main cooler 22.

The auxiliary thermosiphon formed by the auxiliary refrigerant conduit 26 and the auxiliary refrigerant contained therein is completely independent of the main refrigerant conduit 18 and the main refrigerant contained therein, except for the physical connection through the thermal bridge. There is no fluid connection between the passage through the secondary refrigerant conduit 26 and the passage through the primary refrigerant conduit 18. The main refrigerant is isolated from the auxiliary refrigerant in the auxiliary thermosiphon. In practice, each refrigerant may use a different refrigerant, for example a refrigerant having a different equilibrium temperature.

Similar thermosiphons may also be similarly thermally connected to other interior walls, such as to the interior bottom wall of the freezer 10. Each auxiliary thermosiphon will preferably have its own thermal bridge that can be connected to the main refrigerant conduit 18 at any location along the evaporation section of the main refrigerant conduit 18. However, in order for the auxiliary conduit to act as a thermosiphon, condensation of the auxiliary refrigerant must occur at a higher level than evaporation of the auxiliary refrigerant, so that the condensed refrigerant can flow down to the auxiliary evaporation section and the evaporated refrigerant can flow up to the auxiliary condensation section. Therefore, the condenser section of each auxiliary thermosiphon must be at a higher elevation than the portion of the main evaporator section that is connected to the auxiliary condenser section by a thermal bridge. For this reason, it is preferable that the auxiliary condensing section 30 is a top end of the auxiliary refrigerant conduit 18. However, the secondary refrigerant conduit 18 may extend higher, but such extension would be an undesirable non-functional surplus.

The structure of the preferred thermal bridge 34 is best seen in fig. 3-11. The thermal bridge 34 has a central heat conductor 38, which is preferably constructed from an aluminum extrusion. At least one and preferably two heat receiving grooves 40 are formed longitudinally along the central heat conductor 38. Each heat receiving slot 40 has a cross-sectional configuration that matches at least a portion of the external cross-sectional configuration of the secondary condenser section 30 of the secondary refrigerant conduit 26. At least one and preferably two heat discharge slots 42 are also formed longitudinally along the central heat conductor 38. Each heat discharge groove 42 has a cross-sectional configuration that matches at least a portion of the external cross-sectional configuration of the primary evaporator section 36 of the primary refrigerant conduit 18. The matching surfaces improve physical contact and thus thermal conduction between the respective refrigerant conduits 18, 26 and the central heat conductor 38. Preferably, the longitudinal grooves 40 and 42 are parallel and on diametrically opposite sides of the central heat conductor 38 and alternate around the circumference between the heat receiving and heat discharging grooves.

The central heat conductor 38 and the refrigerant conduits 18, 26 are assembled together with the auxiliary condensation section 30 lying (lying) along the heat reception groove 40 and a portion of the main evaporation section 36 lying along the heat discharge groove 42. At least one and preferably a plurality of straps 44 are wrapped around and tightened so that they clamp the assembled refrigerant conduits 18, 26 and central heat conductor 38 tightly together. The bands 44 need not be thermally conductive, but it is desirable that they be thermally conductive. The band forces the refrigerant conduits 18, 26 into highly thermally conductive contact with the central thermal conductor 38. For example, a high strength metal strap (also referred to as a pallet wrap strap) can be pulled around the assembly, tightened with a tensioner, and then held in tension by a conventional sealer. Straps may also be attached to the top inner wall 24 to provide mechanical stability.

The use of the auxiliary thermosiphon of the present invention saves costs since it can be folded or bent and otherwise manufactured separately and separately from the manufacture and installation of the main refrigerant conduit and the main cooler. After installation of the main refrigerant conduit, the previously manufactured secondary thermosiphon is installed by simple manual mechanical manipulation to install the bracket and thermal bridge.

In a thermosiphon, heat flows from a low level to a high level. Not only must the auxiliary condensation section 30 at the thermal bridge be higher than the auxiliary evaporation section 28, but the auxiliary evaporation section 28 must also be gradually sloped downward from the thermal bridge in a manner that avoids low spots or traps. Thus, the mounting brackets 46 are spaced along the auxiliary evaporator end 28 in the thermal connection between the auxiliary evaporator end 28 and the top interior wall 24. The mounting bracket 46 has a gradual and spatially varying height and is arranged such that the thermosiphon always has a gradual downward flow trajectory from the thermal bridge 34 for the liquid refrigerant condensed at the thermal bridge 34. The mounting brackets 46 are arranged so that they support the configuration of the auxiliary evaporator sections in an orientation that is inclined to the horizontal and rises continuously upward from their lowest elevation to the thermal bridge. This arrangement provides a gentle slope so the condensed liquid refrigerant can follow down without a trap to prevent vapor from rising up the thermal bridge. The auxiliary evaporator section 28 and its attached mounting bracket 46 can be assembled and held against the inner cabinet wall 24 using aluminum or other thermally conductive adhesive tape, thermal paste, thermal adhesive, or a combination thereof.

The thermal bridge described above is but one of many possible configurations of thermal bridges that will function with the present invention. Its advantages are easy installation, high safety and high heat conductivity. However, other examples of thermal bridges exist. The thermal bridge can be formed by welding, brazing or soldering the respective refrigerant conduits together, preferably in a small bundle. However, this configuration has been found inconvenient due to the difficulty in supporting the refrigerant conduit in place for the bonding operation and the risk of damaging nearby structures due to the required heat source, such as a welding torch. If adhesives with sufficient thermal conductivity are used, they can be bonded together with the adhesive compound. Of course, other mechanical configurations may be used.

Preferably, the auxiliary refrigerant conduit is loaded to a pressure such that the vapor-liquid equilibrium temperature of the particular refrigerant is at the selected operating temperature of the chiller. Since the auxiliary refrigerant conduit of the auxiliary thermosiphon and the refrigerant it contains are completely separate and independent of the main refrigerant conduit and its refrigerant, the auxiliary refrigerant may be a different refrigerant than the main refrigerant. In addition, the auxiliary refrigerant can be loaded in the auxiliary thermosiphon to a pressure that causes the vapor-liquid equilibrium temperature of the auxiliary refrigerant to be at a different temperature than the vapor equilibrium temperature of the main refrigerant.

During operation, the primary cooling apparatus provides cooling heat rejection to the secondary condenser section 30 of the secondary thermosiphon through the thermal bridge 34. The auxiliary evaporator section 28 of the auxiliary thermosiphon attached to the top wall of the liner receives a downward flow of liquid refrigerant that is condensed at the auxiliary condenser section 30 of the auxiliary thermosiphon connected to the thermal bridge 34. The downward slope of the auxiliary thermosiphon only needs to be a few degrees to promote liquid flow to all parts of the auxiliary evaporator section. Since the refrigerant is near or in two-phase equilibrium, the secondary thermosiphon is essentially isothermal and provides a means of removing heat from the top portion of the liner (effective cooling). This advantageously reduces the temperature distribution within the freezer. In practical tests, the auxiliary thermosiphon reduced the temperature spatial distribution by about 30%.

List of reference numerals

10U L T freezer

12 cabinet door

14 cabinet door gasket

16 cabinet top chamber

18 main refrigerant conduit

20 vertical side wall of cabinet

22 main cooler

24 top inner cabinet wall

26 auxiliary refrigerant conduit

28 auxiliary evaporation section

30 auxiliary condensing section

32 auxiliary refrigerant conduit end

34 heat bridge

36 main evaporation section

38 central thermal conductor of thermal bridge

40 heat receiving groove of heat bridge

42 heat bridge heat discharge groove

44 band around thermal bridge

46 mounting bracket for auxiliary refrigerant conduit

The detailed description taken in conjunction with the drawings is intended primarily as a description of the presently preferred embodiments of the invention and is not intended to represent the only forms in which the present invention may be constructed or utilized. The description sets forth the designs, functions, means, and methods of implementing the invention in connection with the illustrated embodiments. However, it is to be understood that the same or equivalent functions and features may be accomplished by different embodiments that are also intended to be encompassed within the spirit and scope of the invention, and that various modifications may be resorted to without departing from the scope of the invention or the appended claims.