HU192453B - Heat transforming device particularly for coolers - Google Patents

Abstract

The present invention relates to a heat transformer, mainly for refrigeration equipment condenser and evaporator in the cooling circuit process body that carries the primary media involved connected to each other and that a condenser outlet for evaporator input an adjustable fluid delivery device, e.g. connected by a throttle valve and, if applicable Evaporated horse with hoe separator has the principle of way to evaporator (8) and / or the capacitor (13) and the like heat absorber, or stone release surfaces (9, 15) with heat pipes they have their largest surfaces without gaps linked.

Description

BACKGROUND OF THE INVENTION The present invention relates to heat transforming apparatus, particularly for refrigeration equipment. The heat-transfer apparatus according to the invention is preferably used for industrial, commercial, health and household equipment for cooling purposes and / or for cooling of closed spaces, tanks,

Known devices closest to the heat-transfer apparatus of the present invention are preferably used in cold stores for the storage of perishable goods, for the transport of perishable goods in refrigerators, for commercial purposes, for the cooling of chests, and refrigerated cabinets or chambers. It is used in medical institutions for the storage of biological materials (blood, tissue samples, organs for transplantation, etc.). Household refrigerators and freezers also use heat transformers.

The heat-transfer equipment used for the above-mentioned purposes is designed in such a way that the internal space to be cooled is cooled by means of a complicated pipe system with a heat-collecting surface. Such devices are widely used in the trade, for example, as Tyler freezer units. The pipe system and the bollards are installed either concentrically (ribbed pipe bundle) or extensively (eg duct plate). Such equipment is also manufactured, for example, by the German company BOSCH. It is typical of these devices that in the event of damage to the piping system, the entire refrigerant circuit stops, and the refrigerant may be trapped between the refrigerated material. For this latter reason, it has become a strict requirement that no toxic refrigerant be used in cold stores, chillers, household and food refrigeration equipment. For example, ammonia can only be used as a refrigerant in refrigeration equipment where the risk of poisoning in the event of damage to the refrigeration circuit is excluded, although ammonia is one of the most ideal refrigerant materials. (Evaporative heat above 300 cal / g, below 0 ° C; vapor pressure at 20 ° C: 8.7 bar.)

Domestic and commercial refrigeration equipment uses almost exclusively freon for safety, although the evaporative heat at 0 ° C is only 38 cal / g * (FI 2).

For cold stores or. where high refrigeration capacity or high efficiency is the decisive factor, an ammonia refrigeration circuit is used, but the actual refrigeration in the cooled space is different refrigerant, eg. salt. The salt is cooled with an ammonia cooler through a heat exchanger, which complicates the system and low efficiency.

It is an object of the present invention to provide a heat transformer using a very simple short and large cross-section tube as an evaporator instead of a complicated pipe system of the cooling circuit and the condenser. as a condenser, and with high heat transfer heat tubes, high surface area heat exchangers with increased heat transfer capacity are directly connected thereto. In the heat transfer transforming bercn2 so formed, cooling takes place in two cycles, i.e. one in the conventional evaporator, compressor, condenser and the other in the heat pipes. The refrigerant involved in the two cycles may be different. With such a heat-transfer device, it is possible to operate the refrigeration unit with the most efficient refrigerant (e.g. with ammonia or I-dioxide), but the evaporator can reach the cooled space without having to use a separate heat exchanger.

The design of the refrigeration apparatus of the present invention is based on that recognition; it is possible to increase the heat conductivity of the heat-collecting surfaces by a multiple of the heat pipe, so that the evaporator can be designed with smaller geometric dimensions.

The object described above has been accomplished by means of the apparatus described in the introductory part of the specification, by thermal contact with the heat-absorbing and / or heat-dissipating medium by means of high surface area fittings with increased heat conductivity.

In a preferred embodiment of the heat transfer apparatus of the present invention, the capacitor and / or evaporator of the primary refrigerant circuit is a short closed loop to which a large surface area (s) with increased heat conductivity are thermally connected to the heat pipes.

In another preferred embodiment of the heat-transfer apparatus of the invention, the heat transfer channels of the heat pipes are connected to channels suitable for transporting both liquid and vapor.

In a further preferred embodiment, the heat pipes are formed in single or interconnected designs using heat-resisting sheets.

The heat-transfer apparatus of the present invention may also be formed by forming a section or all of a condenser or evaporator loop in a two- or multi-layer conduit plate containing the heat pipes.

According to a further preferred embodiment of the thermal transformation apparatus according to the invention, a common radiator and / or radiator pipe can be formed (i.e. connected) to the lower part of the heat pipes connected to the εζ evaporator, which can be used for disinfecting the cooling surfaces.

The use of the various embodiments outlined above provides the opportunity for the refrigerant and the working fluids of the heat pipes to be different.

According to another possible embodiment of the heat-transfer apparatus, the heat pipes used may be simple thermosiphons (1 P. D. DONN-D. A. REAY "Heat Pipes" Technical Publication 1982).

The heat-transfer apparatus according to the invention may further be so designed. such that between the heat pipes and / or the pipe containing the heat pipes and the condenser and / or evaporator of the primary refrigerant circuit, the ter-21

192 453 are made by mechanically clamping surfaces together. The heat-transfer apparatus of the present invention may be formed by attaching to the parts of the compressor's lubricating side a large surface area having heat-conductivity enhanced heat tubes, thereby integrating the compressor thus formed into the condenser.

The heat-transfer apparatus according to the invention, which is mainly intended for refrigeration equipment, has a condenser and an evaporator, which are interconnected by a means for transporting the primary medium involved in the process of the refrigeration circuit. The condenser outlet to the evaporator inlet can be controlled by a fluid conveyor, e.g. connected by a throttle. The evaporator can be equipped with a fridge separator, if necessary. The novelty of the heat-transfer apparatus according to the invention lies in the fact that the evaporator and / or the condenser and their heat-absorbing and / or heat-absorbing devices. the heat transfer surfaces are connected by heat pipes to their largest surfaces without joints. The heat pipes may be provided with surface enhancing ribs and may form a structural unit.

The most important advantages of the thermal transformation apparatus according to the invention are as follows:

- Due to the very high heat transfer capacity of the heat pipes, the cooling rate could be nearly doubled compared to conventional heat-transfer units.

- Conventional refrigeration unit with approx. We could increase it by 20%.

- With the same cooling volume, we were able to use a compressor with a lower power output.

The air mixing fan used in conventional heat-transfer equipment was optional for the apparatus of the invention, which is advantageous in particular for industrial equipment as it can be made free of draft air.

- Unlike conventional dual-circuit cooling, only the primary circuit requires power because the secondary circuit heat pipes do not require auxiliary energy.

- Due to the very rapid heat transfer capacity of the heat pipes, when the chilled space is heated locally, the cooling power is concentrated on this warmer part without overcooling the other areas.

- In cold stores, the use of toxic refrigerant is possible without danger, since the evaporator can be separated from the cooled space airtight.

An exemplary embodiment of the thermal transformation apparatus of the present invention will be described in greater detail on the basis of the drawing, wherein:

Fig. 1 is a schematic sectional view of the structure of a conventional refrigerator, a

Figure 2 is a schematic sectional view of the use of the heat-transfer apparatus of the present invention in a refrigerator box,

Fig. 3 shows a schematic diagram of the circuit of the heat transformer according to the invention.

As can be seen in Figure 1, the known heat-transfer apparatus is known in connection with a cooling box.

Between the outer casing 1 and the inner casing 3, a thermal insulation layer 2 is provided. Below the storage space 4 is the evaporator tube system 6 with an evaporator heat-collecting surface 5. The fan 7 provides a shaper between the inner cover 3 and the load wall 4; channel through the internal air circulation. The disinfection heater 11 is thermally connected to the heat-collecting surface of the evaporator 5.

The system operates in such a way that the primary refrigerant evaporated in the evaporator tube system 6 cools the tube system 6 and cools the ambient air through the evaporator heat collecting surface 5. A constant exchange of air between the evaporator heat collecting surfaces 5 is provided by the fan 7 (at the same time as the cold air is transferred to a higher location).

Figure 2 also illustrates the heat-transfer apparatus of the present invention in more detail with reference to an example of a refrigerator box. The difference with the apparatus of Fig. 1, that is, a novelty of the invention, is that the strain pipe 8 is located at the upper edge of the cooling box. In this way, the heat pipes 10, together with the heat-absorbing ribs 9 forming the wall of the cargo space 4, are in close thermal contact. The disinfection heater 11 is connected directly to the heat pipes 10 at its lower end by thermal conductivity.

The operation of the apparatus shown in Figure 2 is as follows: The primary refrigerant in the evaporator tube loop 8 cools down by evaporation. This activates the heat pipes 10, which are in close thermal contact with the pipe loop 8, and because of their practically infinite thermal conductivity, the heat pipes cool down the heat-absorbing ribs 9, thereby achieving the same temperature throughout the wall of the boot space 4 '. As the entire volume becomes the same temperature and is removed from the heat, no separate air mixing fan is required. When the dewatering heater 11 is switched on, the heat pipes 10 which are connected to it immediately dissipate the heat on the wall of the cargo compartment 4, so that the dewatering is carried out in a very short time.

As the useful volume of the present invention is increased and the mass representing the heat inertia is reduced, both the rate of disinfection and refrigeration are greatly increased. Figure 2 shows that the heat pipes 10 are integral with the heat-absorbing ribs 9. In a further embodiment, the heat pipes may be interconnected by ducts carrying a heat transfer medium to better balance the temperature.

It is also possible for the heat pipes 10 to be formed in at least two-layer tubes in well-known plates and for the evaporator 8, the disinfectant 11 and / or 13

The condenser conduit 192 453 is formed in whole or in part in the conduit plate.

Since the primary cooling circuit and the heat pipes are only thermally connected to one another and their internal spaces are sealed, the working fluids in the cooling circuits and heat pipes may be different materials.

Any non-horizontal heat pipe with a colder upper end may also have a thermosiphon. 10

The heat pipes 10, 14 are applied to both the evaporator 8 and the capacitor 13 respectively. Mounted on 12 compressors using conventional fasteners. The compressor 12 can be formed as a compact unit on the capacitor 13 as shown in FIG.

Preferably, the heat sink ribs 15 of the condenser 13 extend into a domestic hot water tank 16 or air heating conduit. Figure 3 is a schematic diagram of the arrangement of Figure 2 for the sake of completeness. The evaporator 8 is connected to the inlet of the compressor 12. The refrigerant condensed by the compressor 12 liquefies into the condenser 13 and cools through the heat pipes 14 and the heat sink ribs 15. The refrigerant passes from the condenser outlet 13 through the pipe loop 17 and the throttle valve 18 to the evaporator 8. The compressor 12 and the capacitor 13 form a single compact unit. The water reservoir 16, which is used for the production of domestic hot water 30, is mounted on the upper part of the condenser 13 so that the heat pipes 14 and the heat discharge ribs 15 of the condenser 13 and the compressor 12 extend into the water space.

Claims (9)

A heat-transfer apparatus, in particular for refrigeration equipment, wherein a capacitor 40 and an evaporator are interconnected by a primary medium conveying the refrigerant circuit, and the condenser outlet to the evaporator inlet is controlled by a conveying medium, e.g. The damper is connected by means of a throttle valve 45 and optionally the evaporator logger has a fridge-separating heat sink, characterized in that the evaporator (8) and / or the condenser (13) and their heat-absorbing and / or heat exchanger (13). the heat transfer surfaces (9, 15) are interconnected by heat pipes (10, 14) with their largest surfaces without gaps. The heat transformation device according to claim 1, characterized in that the heat pipes (10, 14) form a structural unit with surface-extending ribs (9, 15). The heat transformation device according to claim 1 or 2, characterized in that the heat pipes (10, 14) are interconnected by ducts carrying a heat transfer medium. The heat transformation device according to claim 2 or 3, characterized in that the heat pipes (10, 14) are made of at least two-layer tubular plates and that optionally the evaporators (8) and / or the condenser (13) and / or the duct of the disinfection heater (11) is formed in whole or in part of the duct plate. 5. The heat transformation device according to any one of claims 1 to 3, characterized in that the primary cooling circuit and the working fluids used in the heat pipes (10, 14) are optionally different. 6. The heat transformation device according to any one of claims 1 to 4, characterized in that at least one of the heat pipes (10, 14) of the device is a thermosiphon. 7. The heat transformation device according to any one of claims 1 to 4, characterized in that the heat pipes (10, 14) are formed on both the evaporator (8) and the condenser (13) by means of conventional fasteners. 8. Referring to l · —7. The heat conversion device according to any one of claims 1 to 3, characterized in that the compressor (12) is formed as a compact unit with the capacitor (13). 9. In l · —8. The heat transformation device according to any one of claims 1 to 3, characterized in that the heat transfer ribs (15) of the condenser (13) extend into a domestic hot water tank (16) or an air heating channel.