RU2267071C2 - Heat-exchanging system - Google Patents

Abstract

FIELD: heat transfer equipment, particularly to carry heat for long distances, for instance refrigerators.

SUBSTANCE: heat-exchanging system comprises closed loop including main heat-exchanging channel, heat carrier agent pumping device, additional heat-exchanging channel and heat-carrier supply channel connecting the main and additional heat-exchanging channels. Heat carrier agent pumping device may withdraw heat carrier agent in vapor or vapor-and-liquid state from one heat-exchanging channel and supply above vapor or vapor-and-liquid heat carrier agent under elevated pressure into another heat-exchanging channel. Heat carrier agent supply channel is formed as channel with capillary partition closing the channel. During heat-exchanging system operation the capillary partition obstructs vapor penetration or vapor-and-liquid flow. The vapor penetration obstruction is defined by cooperation between meniscuses and inner surfaces of capillary channels formed in the partition. The vapor-and-liquid flow obstruction is defined by bubble meniscuses cooperation with inner surfaces of capillary channels of the partition. The heat carrier agent pumping device may withdraw vapor or vapor-and-liquid heat carrier agent from any heat-exchanging channel and pump above heat carrier agent under elevated pressure in another heat-exchanging channel.

EFFECT: increased efficiency of heat-exchanging system.

14 dwg, 18 cl

Description

The invention - a heat exchange system - relates to heat transfer devices, can be used to remove heat over long distances, and can also be used as a refrigerator. On the basis of this invention, various products and devices with thermoregulation for use in household and medicine can be developed.

A heat exchange system is known (RF Patent No. 21115869, F 25 B 21/02, F 28 D 15/02, 07/20/1998), containing a closed loop consisting of a main heat exchange channel, a coolant pumping device and an auxiliary heat exchange channel. The main and auxiliary heat exchange channels are connected by a coolant supply channel. In this case, the coolant pumping device is configured to discharge the coolant in the form of steam or a vapor-liquid medium from one of the heat exchange channels and to pump this coolant in the form of steam or a vapor-liquid medium with a higher pressure into another heat transfer channel. In the known device, the heat carrier through the feed channel enters the heat exchange channel with lower pressure in portions in the form of a liquid column, i.e. comes in the form of a vapor-liquid medium.

Since the vapor pressure in the heat exchange channels can vary greatly, the possibility of a breakthrough of large quantities of hot steam from one of the heat exchange channels to another heat exchange channel is not excluded, which reduces the efficiency of the heat exchange system.

The objective of the invention is to increase the efficiency of the heat exchange system.

The invention consists in the following.

The heat exchange system comprises a closed loop consisting of a main heat exchange channel, a coolant pumping device, an auxiliary heat exchange channel and a coolant supply channel connecting the main and auxiliary heat exchange channels, while the coolant pumping device is configured to discharge the heat carrier in the form of steam or vapor-liquid medium from one from heat transfer channels and pumping this coolant in the form of steam or a vapor-liquid medium with a higher pressure in others the heat transfer channel, and the coolant supply channel is made in the form of a channel with a capillary partition overlapping the channel, while during operation of the heat exchange system the capillary partition of the supply channel is resistant to steam penetration, determined by the interaction of menisci with the inner surface of the capillary microchannels of the capillary partition of the supply channel, or resistance overflow of a vapor-liquid medium, which is determined by the interaction of menisci of bubbles with the inner surface of capillary m krokanalov capillary flow channel walls.

The coolant pumping device can also be configured to discharge the coolant in the form of steam or a vapor-liquid medium from any heat transfer channel and pump this coolant in the form of steam or a vapor-liquid medium with a higher pressure into another heat transfer channel.

In addition, the coolant pumping device is made in the form of a pumping channel with a capillary septum overlapping the channel, and is also equipped with a heat device configured to carry out at least one of the following two modes of operation, the first mode of operation is to remove heat from the the main heat exchange channel of the surface of the capillary septum and / or from the layer of the capillary septum adjacent to this surface, and in the heat supply to the surface of the auxiliary heat transfer channel the surface of the capillary septum and / or to the capillary septum layer adjacent to this surface, and the second mode of operation is to remove heat from the surface of the capillary septum facing the auxiliary heat exchange channel and / or from the capillary septum layer adjacent to this surface and to supply heat to the surface of the capillary septum facing the main heat exchange channel and / or to the capillary septum layer adjacent to this surface, while the heat device can also be made with the ability to carry out simultaneously on both surfaces of the capillary septum, facing the main and auxiliary heat exchange channels, and / or in the layers adjacent to these surfaces, processes of supply or removal of heat.

The thermal device is also based on the use of a thermoelectric module, while one surface of the junctions of the thermoelectric module is connected by thermal contact with the surface of the capillary septum facing the main heat exchange channel, or with a layer of capillary septum bordering this surface, and the other surface of the junctions of the thermoelectric module is connected by a thermal contact with the surface of the capillary septum facing the auxiliary heat exchange channel, or with a layer of capillary over horns bordering this surface.

A pipe is installed in the heat exchange system connecting the auxiliary heat exchange channel with the capillary partition of the pumping channel.

A pipeline is also installed in the heat exchange system connecting the auxiliary heat exchange channel with the capillary wall of the pumping channel, and a capillary wall is installed in the pipe, and this capillary wall can occupy the entire internal volume of the pipeline.

In addition, the capillary septum in the supply channel occupies the entire internal volume between the main and auxiliary heat exchange channels.

According to the invention, a part of the capillary septum of the supply channel is connected by thermal contact with a part of the main heat exchange channel.

In addition, part of the inner surface of the main heat transfer channel is covered with a capillary structure connected to the capillary partition of the feed channel by a capillary bridge.

A heat exchange system containing a part of the coolant supply channel can be connected by thermal contact with a part of the capillary partition of the pumping channel, and a thermal contact between the part of the supply channel and part of the capillary partition can be arranged in a countercurrent circuit.

In addition, the coolant supply channel is laid inside the capillary septum of the pumping channel.

The coolant pumping device is made in the form of evaporative-condensation heat exchangers connected in series with a displacement channel between them, consisting of two capillary partitions that overlap the channel, and is equipped with a prefix for supplying and / or removing heat in the areas of the capillary partitions of the displacement channel.

The heat exchange system is also equipped with a heat device configured to supply heat to the surface of the capillary partition of the feed channel facing the main heat exchange channel or to the capillary septum layer adjacent to this surface, and / or heat removal from the surface of the capillary partition of the channel facing the main heat exchange channel filing or from a layer of capillary septum bordering this surface.

In addition, the closed loop is made up of an auxiliary heat exchange channel and at least two parallel lines, each of which consists of a coolant supply channel, a main heat transfer channel and a coolant pumping device.

The heat exchange system also contains a closed loop made up of an auxiliary heat exchange channel and at least two parallel lines, each of which consists of a coolant supply channel, a main heat exchange channel and a coolant pumping device, while between the capillary walls of the pumping channels various lines installed capillary bridge.

In addition, between the capillary partitions of the supply channels of various lines installed capillary bridge.

The heat exchange system can be made in such a way that the coolant pumping device is made in the form of an additional heat exchange channel and a pumping channel connected in series with a capillary partition that overlaps the channel, the additional heat exchange channel being located between the main heat exchange channel and the pumping channel, and the pumping device is equipped with a heat device configured to carry out at least one of the following two modes of operation, the first mode of operation of the conclusion is taken in the heat removal from the surface of the capillary septum facing the additional heat exchange channel and / or from the capillary septum layer adjacent to this surface, and in the heat supply to the capillary septum surface facing the auxiliary heat exchange channel and / or to the capillary septum layer adjacent to this surface, and the second mode of operation is to remove heat from the surface of the capillary septum facing the auxiliary heat exchange channel and / or from the capillary block layer a plate adjacent to this surface, and in the heat supply to the surface of the capillary septum facing the additional heat exchange channel and / or to the capillary septum layer adjacent to this surface, while the heat device can also be configured to simultaneously realize on both surfaces of the capillary septum facing the main and auxiliary heat transfer channels, and / or in the layers adjacent to these surfaces, the processes of supply or removal of heat.

An additional heat exchange channel may be connected by thermal contact with the cooling element.

The essence of the heat exchange system is illustrated using graphic materials:

- figure 1: presents a schematic diagram of a heat exchange system;

- figure 2: presents a device for pumping a coolant, made in the form of a pumping channel with a capillary septum overlapping the channel, and also equipped with a thermal device;

- figure 3: shows the section between the main and auxiliary heat transfer channels;

- figure 4: shows the supply channel of the coolant, made passing through the capillary partition of the pumping channel;

- figure 5: shows a coolant pumping device made in the form of evaporative-condensing heat exchangers connected in series with a displacement channel located between them, consisting of two capillary partitions;

- Fig.6: shows a heat exchange system equipped with a heat device configured to supply heat to the surface of the capillary partition of the feed channel facing the main heat transfer channel or to the capillary wall layer adjacent to this surface;

- Fig.7: shows a closed loop made up of an auxiliary heat exchange channel and at least two parallel lines;

- Fig. 8: shows a device in which a capillary bridge, which is a capillary structure, is installed between the capillary partitions of the pumping channels of various lines;

- Fig.9: shows a coolant pumping device made in the form of an additional heat exchange channel and a pumping channel connected in series with a capillary partition overlapping the channel, the additional heat exchange channel being located between the main heat exchange channel and the pumping channel;

- figure 10: shows the design of a chair equipped with a heat exchange system;

- Fig.11: presents the design of the bed containing the mattress and equipped with a heat exchange system, the design of which is presented in Fig.1;

- Fig: presents the design of the chair with the duct;

- Fig.13: presents the design of the refrigerator cabinet, consisting of a cabinet body, inside which a refrigerator is installed;

- Fig: shows the design of a thermal massage device containing a massaging element and a heat exchange system.

The heat exchange system comprises a closed circuit 1, which consists of a main heat exchange channel 2, a coolant pumping device 3, an auxiliary heat exchange channel 4 and a coolant supply channel 5 connecting the heat exchange channels 2 and 4. The coolant supply channel is made in the form of a channel with a capillary partition 6 overlapping channel. The capillary septum contains at least one capillary microchannel 7. The coolant 8 pumped along the circuit may in some sections be either steam 9 or vapor-liquid medium 10 or liquid 11. The vapor-liquid medium 10 consists of vapor bubbles 12 and liquid formations 13. Pumping device the coolant 3 is configured to discharge the coolant in the form of steam or vapor-liquid medium from one of the heat exchange channels and pumping this coolant in the form of steam or vapor-liquid media s with higher pressure into another heat exchange channel.

Consider the operation of the device for the case when the circulation of the coolant in the circuit is carried out clockwise, in this case, the main heat transfer channel functions as a steam generator (such a case is just considered in figure 1). So, in the main heat exchange channel, the process of vaporization is carried out, for this heat is supplied (shown in figure 1 by an arrow-strip). As a result of vaporization, steam or a vapor-liquid medium is formed, which are discharged by the device for pumping the coolant. Then, the coolant from the pumping device in the form of steam or a vapor-liquid medium with a higher pressure is supplied to the auxiliary heat exchange channel, where the condensation process is carried out. From the auxiliary heat exchange channel, the coolant through the coolant supply channel, made in the form of a channel with a capillary partition that overlaps the channel, is fed into the main heat transfer channel. At the same time, the coolant supply channel provides uniform coolant supply from the region with higher pressure to the region with lower pressure due to the interaction of menisci 14 of bubbles 15, overlapping the section of the capillary microchannel, with the inner surface of the capillary microchannels of the capillary partition of the feed channel. In this case, here and below, the case of wetting with a coolant of the inner surface is considered.

The design of the heat exchange system can be performed in this way, and also the amount of charged coolant in the heat exchange system can be such that during operation of the heat exchange system during condensation in one of the heat exchange channels, for example, in an auxiliary heat exchange channel, the condensate column formed is transported through the capillary the entire partition of the feed channel into the main heat transfer channel without completely filling the volume of the internal cavity of the main heat exchange channel (i.e., without disturbing the processes of vaporization and vapor transfer in the area from the main heat transfer channel to the pumping device). This mode of operation is satisfactory. The penetration of steam is already resistance, determined by the strength of the interaction of the menisci with the inner surface of the capillary microchannels of the capillary septum. In this case, with sufficiently small transverse dimensions of the capillary microchannels, the pairs may not be passed at all. This eliminates the breakthrough of hot steam into the main heat transfer channel, which functions as an evaporator and in which the pressure (temperature) is lower than in the auxiliary heat transfer channel, which functions as a condenser.

The design and refueling may be such that a vapor-liquid medium is formed during the condensation process in the auxiliary heat exchange channel. The capillary septum of the feed channel in this case also has a resistance to the overflow of the medium, which is determined by the interaction force of the meniscus of the bubbles with the inner surface of the capillary microchannels of the capillary septum. Bubbles can pass through the capillary septum, and if they are cooled in the area near the exit of the bubbles in order to reduce the volume of the bubbles (possibly down to zero), then the functioning of the supply channel becomes more efficient.

If a medium without bubbles enters the area in front of the capillary septum, then the capillary septum provides resistance to overflow only due to viscosity forces.

From the above it is clear how the device works when the main heat exchange channel functions as a condenser, and the auxiliary heat exchange channel as a steam generator.

The coolant pumping device may be configured to pump in any direction. Due to this, the main heat transfer channel can function either as a steam generator or as a condenser. During the operation of the main heat exchange channel as a condenser, the auxiliary heat exchange channel can function as a steam generator.

The coolant pumping device can be made in the form of a pumping channel 16 (Fig. 2) with a capillary baffle 17 that overlaps the channel, and is also equipped with a heat device 18 configured to carry out at least one of two operating modes. The first mode of operation is to remove heat from the capillary septum surface 19 facing the main heat exchange channel and / or from the capillary septum layer 20 bordering this surface, and to supply heat to the capillary septum surface 21 facing the auxiliary heat exchange channel and / or to the layer 22 of the capillary septum adjacent to this surface, and the second mode of operation is to remove heat from the surface 21 of the capillary septum facing the auxiliary heat exchange channel and / or Layer 22 m capillary walls bordering on this surface, and heat input to the heat exchanger facing the main surface 19 of the capillary channel walls and / or to a layer 20 of capillary walls bordering on this surface. In this case, the heat device can also be configured to simultaneously carry out heat supply or removal processes on both surfaces 19 and 21 of the capillary septum facing the main and auxiliary heat exchange channels and / or in layers 20 and 22 adjacent to these surfaces. When the thermal device is operating in the first mode, steam or vapor-liquid medium is removed from the main heat exchange channel due to the condensation process on the capillary septum surface 19 facing the main heat exchanger channel or in the capillary septum layer 20 bordering this surface. After the condensation process, the coolant is transferred through the capillary septum. Due to heat supply, vaporization takes place on the surface 21 of the capillary septum facing the auxiliary heat exchange channel or in the layer 22 of the capillary septum adjacent to this surface. In this case, due to the capillary forces created by the formed menisci, the coolant is pumped into the region with a higher pressure. The generated steam is transferred to the auxiliary heat exchange channel.

The heat device 18 can be made using thermoelectric module 23 (Fig. 2), while one surface of the junctions 24 of the thermoelectric module is connected by thermal contact 25 to the surface 19 of the capillary septum facing the main heat exchange channel, or to the layer 20 bordering this surface, and the other surface of the junctions 26 of the thermoelectric module is connected by thermal contact 27 to the surface 21 of the capillary septum facing the auxiliary heat-exchange channel, or to a layer 22 bordering this oh surface.

In the heat exchange system, a pipe 28 (FIG. 2) can be installed connecting the auxiliary heat exchange channel with the capillary partition of the pumping channel. In the pipeline 28 can be installed capillary wall 29 (figure 2), and this capillary wall can occupy the entire internal volume of the pipeline. This allows, in the case of the operation of the auxiliary heat exchange channel as a condenser, to direct part of the condensate directly to the capillary septum and thereby increase the efficiency of the device by reducing the consumption of cooling capacity.

A capillary septum in the supply channel can be installed next to the auxiliary heat exchange channel (this is shown in figure 2). In this case, the uniformity of the condensate supply to the main heat exchange channel is also increased. The capillary septum in the supply channel can occupy the entire internal volume between the main and auxiliary heat exchange channels. Figure 3 shows the section 30 between the main and auxiliary heat transfer channels. This entire section can be occupied by a capillary septum 6. In this case, the uniformity of the condensate supply to the main heat exchange channel is also increased.

Part 31 of the capillary septum of the supply channel can be connected by thermal contact with a part of the main heat transfer channel (figure 3). This makes it possible to supply cooled coolant to the main heat exchange channel; in this case, the efficiency of the feed channel also increases, since vaporization in front of the main heat transfer channel is excluded, which can lead to useless displacement of the coolant from the main heat transfer channel.

A portion of the inner surface of the main heat transfer channel may be coated with a capillary structure 32. This improves the operation of the heat exchange system when the main heat transfer channel functions as a steam generator.

The capillary structure of the main heat exchange channel can be connected by a capillary bridge 33, which is a capillary structure, with a capillary partition of the supply channel. This increases the uniformity of the coolant supply to the main heat exchange channel when it functions as a steam generator.

A part of the coolant supply channel can be connected by thermal contact with a part of the capillary partition of the pumping channel, moreover, the thermal contact of the part of the supply channel and part of the capillary partition can be arranged in a counterflow circuit. Figure 4 shows that this can be realized, in particular, if the supply channel of the coolant to run through the capillary partition of the pumping channel. Figure 4 shows that the connection by thermal contact of the surfaces of the junctions of the thermoelectric module with the surfaces of the capillary septum facing the respective heat exchange channels, or with layers adjacent to these surfaces, can be accomplished by making grooves 34 and 35 on part of the surface of the capillary septum 17, connected to the inner surface of the channel 16. In section 36, a part of the coolant supply channel is connected by thermal contact with a part of the capillary partition of the pumping channel. This embodiment of the pumping channel and the feed channel can improve the efficiency of the heat exchange system by reducing the consumption of cooling capacity.

The coolant pumping device can be made in the form of evaporator-condensation heat exchangers 37 and 38 connected in series (Fig. 5) with a displacement channel 39 located between them, consisting of two capillary partitions 40 and 41, overlapping the channel, and also equipped with a prefix 42 for supplying and / or heat removal in areas of the capillary septum of the displacement channel, namely, in layers 43, 44, 45 and 46. There is a cavity 47 between the capillary partitions; there are also areas 48 (located between the capillary baffle 40 and the evaporative-condensing heat exchanger 38) and 49 (located between the evaporative-condensing heat exchanger 37 and the capillary baffle 41). The device also includes a heat device 50, designed to remove heat from one evaporative condensation heat exchanger and supply heat to another evaporative condensation heat exchanger and vice versa. As a thermal device, a thermoelectric module can be used. The coolant pumping device can provide coolant pumping in any direction. We describe the way of working when organizing the circulation of the coolant in a clockwise direction; in this case, the auxiliary heat exchange channel 4 functions as a condenser, and the main heat exchange channel 2 can function as a steam generator. Let's start with the stage of the coolant inlet from region 49 to cavity 47 (this stage of operation is just presented in Fig. 5). During this stage, the coolant from region 48 is transferred under pressure from the vapor generated in the capillary microchannels of the layer 43 of the capillary septum 40 to the evaporative-condensing heat exchanger 38, where it is vaporized by supplying heat from the heat device 50. From the evaporative-condensing heat exchanger 38 the heat carrier in the form of steam or vapor-liquid mixture is transferred to the auxiliary heat exchange channel 4 and condenses; then the coolant through the feed channel 5 is fed into the main heat exchange channel 2, where vaporization occurs. Then, the heat carrier is transferred from the main heat exchange channel to the evaporative condensation heat exchanger 37, where condensation occurs as a result of heat removal by the heat device 50. The heat carrier from the evaporative condensation heat exchanger 37 is supplied to the displacement channel, namely, it is introduced through the capillary wall 41 into the cavity 47. At the stage displacement (this stage is not shown) the coolant from the cavity 47 is displaced through the capillary septum 40 to the region 48, this occurs under the influence of vapor pressure generated in illary microchannels of the layer 45 of the capillary septum 41. In this case, the coolant coming from the evaporative condensation heat exchanger 37 is accumulated in the region 49. The flow of the coolant from the cavity 47 to the region 49 is prevented by the formation of steam inclusions in the layer 45 located on the side of the cavity 47. In this case, the processes of vaporization in the evaporative condensation heat exchanger 38, condensation in the heat exchange channel 4, vaporization in the heat exchange channel 2 and condensation in the evaporative condensation continue This heat exchanger 37. Then the transition to the stage of inlet. In the process, there is an alternation of the described stages.

The heat exchange system may be equipped with a heat device 51 (Fig. 6), configured to supply heat to the surface 52 of the capillary wall of the supply channel facing the main heat exchange channel or to the capillary wall layer 53 adjacent to this surface and / or heat removal with facing the main heat transfer channel surface 52 of the capillary septum of the supply channel or from the layer 53 of the capillary septum adjacent to this surface. With this design, without changing the direction of circulation of the coolant along the circuit, it is possible to organize the functioning of the main heat transfer channel either as a steam generator or as a condenser. We begin the description of the operation from the moment when the process of vaporization is carried out in the heat exchange channel 2 (this stage of operation is not reflected in Fig. 6). For example, providing a temperature of + 5 ° С on surface 19 or in layer 20 (numerical values are purely illustrative), and temperature + 40 ° С on surface 21 or in layer 22, it is possible to carry out condensation in auxiliary heat transfer channel 4 at a temperature of +38 ° C, and in the heat exchange channel 2 vaporization at a temperature of + 7 ° C. The heat exchange channel 2 at this moment carries out cooling of the object 54, which is in thermal contact with the heat exchange channel 2. At this time, the supply channel functions as a device for depressurizing and ensuring an even supply of coolant. Using a heat device 51, heat can be removed from the surface 52 of the capillary septum or from the layer 53 adjacent to this surface. Then, in the second stage (this stage is shown in FIG. 6), using this design, it is possible to carry out the condensation process in the main heat exchange channel 2. For example, by providing a temperature of + 15 ° С on the surface 19 and in the layer 20, and in the layer on the surface 21 22 temperature + 50 ° C, it is possible to carry out condensation in the heat exchange channel 4 at a temperature of + 48 ° C. Providing heat supply to the surface 52 or to the layer 53 at a temperature of + 50 ° C, it is possible in the heat exchange channel 2 to carry out the condensation process at a temperature of + 48 ° C. The heat exchange channel 2 at this moment heats the object 54. At this time, the supply channel functions as a device for generating steam.

The closed loop 1 can be made up of an auxiliary heat exchange channel 4 and at least two parallel lines (Fig. 7), for example, two lines 55 and 56, each of which consists of a coolant supply channel, a main heat exchange channel, and coolant pumping devices. On this design, they can either carry out a steam formation process in both main heat transfer channels (while carrying out the condensation process in the auxiliary heat transfer channel), either carry out a condensation process in both main heat transfer channels, or carry out a steam formation process in one main heat transfer channel, and a process in the other condensation. The latter is presented in Fig.7; in this case, the object 57 is heated, and the object 58 is cooled. It is possible to switch operating modes by simply changing the current direction in thermoelectric modules, for example, switch to the operating mode when the main heat exchange channel 2 of line 55 functions as a steam generator, and the main heat exchange channel 2 of line 56 functions as a condenser. The device works better if a capillary bridge, which is a capillary structure, is installed between the capillary partitions of the pumping channels of various lines. The embodiment shown in FIG. 8 satisfies this requirement. Here, two pumping channels are made in one housing 59 containing a capillary insert 60. In this case, one part 61 of the capillary insert is the capillary septum of line 55, and the other part 62 is the capillary septum of line 56. The central part 63 acts as a capillary bridge. In this embodiment, both feed channels are also made in one housing 64 containing a capillary insert 65. In this case, one part 66 of the capillary insert is the capillary partition of the feed channel of line 55, and the other part 67 is the capillary partition of line 56. The central part 68 functions as a capillary the bridge.

The coolant pumping device can be made in the form (Fig. 9) of an additional heat exchange channel 69 and a pumping channel 16 connected in series with a capillary partition 17 overlapping the channel, the additional heat transfer channel being located between the main heat exchange channel 2 and the pumping channel, and the device is equipped with a heat device 18, configured to implement at least one of two modes of operation. The first mode of operation is to remove heat from the capillary septum surface 19 facing the additional heat-exchange channel and / or from the capillary septum layer 20 bordering this surface, and to supply heat to the capillary septum surface 21 facing the auxiliary heat-exchange channel and / or to the layer 22 of the capillary septum adjacent to this surface, and the second mode of operation is to remove heat from the surface 21 of the capillary septum facing the auxiliary heat exchange channel and / or from the capillary septum layer 22 adjacent to this surface and in the heat supply to the capillary septum surface 19 facing the additional heat exchange channel and / or to the capillary septum layer 20 bordering this surface. In this case, the thermal device can also be configured to simultaneously carry out heat supply or removal processes on both surfaces 19 and 21 of the capillary septum facing the additional and auxiliary heat-exchange channels, and / or in layers 20 and 22 adjacent to these surfaces. When the thermal device is operating according to the first mode, steam or vapor-liquid medium is removed from the main heat exchange channel due to the condensation process on the additional heat exchange channel. From the additional heat exchange channel, condensate is diverted to the pumping channel and transferred through the capillary septum. Due to heat supply, vaporization takes place on the surface 21 of the capillary septum facing the auxiliary heat exchange channel or in the layer 22 of the capillary septum adjacent to this surface. In this case, due to the capillary forces created by the formed menisci, the coolant is pumped into the region with a higher pressure. The generated steam is transferred to the auxiliary heat exchange channel. Here, condensation is carried out, the coolant is then transferred through the feed channel and fed into the main heat exchange channel. An additional heat exchange channel can be connected by thermal contact with a cooling element (not shown in Fig. 9), for example, with a cooling element (evaporator) of a compressor refrigeration unit.

The heat exchange system can be used in an armchair (chair, sofa) for heating or heat removal purposes. Figure 10 presents the design of the chair 70, containing a pillow 71, a back 72 and a head restraint 73. The chair is equipped with a heat exchange system made in the form of a closed loop 1, consisting of a main heat exchange channel 2, a device for pumping heat carrier 3, an auxiliary heat exchange channel 4 and a supply channel heat carrier 5 connecting the main and auxiliary heat exchange channels. In this case, the main heat transfer channel is installed in the pillow, and / or in the back, and / or in the headrest of the chair. The main heat transfer channel can be installed in a removable lining located on the pillow and / or on the back of the chair (not shown in figure 10).

The inventive heat exchange system can be applied in bed. In Fig.11 shows the design of the bed 74 containing the mattress 75. The bed is equipped with a heat exchange system, the design of which is presented in Fig.1. In this case, an air duct 76 is laid in the mattress, inside of which the main heat exchange channel 2 is installed. Moreover, an air pumping device 77 and a heater 78 can also be installed in the air duct. The mattress can be made permeable in the region from the upper surface 79 of the mattress to the inner cavity 80 of the air duct. Figure 11 shows conventionally the channels of permeability 81, providing permeability. Due to the permeability, mass transfer is ensured between the air in the cavity of the duct and the air in the region located above the surface of the mattress; thanks to this, temperature and humidity are regulated in this area. The duct does not have to be closed. It can be made open. Similar to the latter design is the design of the seat 70 with the duct (Fig). The proposed designs can be used as a car seat, sofa, sofa, etc.

The inventive heat exchange system can be used in the design of the refrigerator cabinet (Fig. 13), consisting of a cabinet body 82, inside which a refrigerating chamber 83 is installed. The refrigerating chamber body can be made of a heat-conducting material, for example, an aluminum alloy. There is a door 84. The main heat exchange channel 2 is made in the housing of the refrigeration chamber, in this embodiment, the heat transfer tubes 85 of the main heat transfer channel are soldered outside to the housing of the refrigeration chamber. A refrigerator is located inside the heat insulator 86. The auxiliary heat exchange channel 4 is made in the rear wall 87 of the cabinet. In this embodiment, the tubes 88 of the auxiliary heat exchange channel are soldered to the rear wall of the cabinet. The back wall of the cabinet can be made of aluminum alloy. A coolant pumping device 3 and a coolant supply channel 5 were also installed. The heat generated inside the refrigerating chamber enters the refrigerating chamber body and then flows through the heat-conducting housing of the refrigerating chamber to the tubes 85 of the main heat exchange channel. Due to the thermal conductivity of the rear wall, heat is removed from the tubes 88 of the auxiliary heat exchange channel and then due to convective heat transfer is discharged from the rear wall into the external environment. Due to the sufficiently large area of the rear wall, you can do without a fan. Such a refrigerator can be built into wall furniture. The back wall can be made profiled (wavy, ribbed) in order to increase the heat transfer surface.

The inventive heat exchange system can be used in a thermal massage device. A possible design of the thermal massage device is shown in Fig. 14. The presented design option contains a massaging element 89 and a heat exchange system. In this case, the main heat exchange channel 2 is installed in the massaging element and has thermal contact with it. On Fig shows that the pipeline connecting the main heat exchange channel with the pumping channel, can be made of flexible bellows 90, which can be made of metal (beryllium bronze, steel, titanium, etc.). Part 91 of the pipeline connecting the main heat exchange channel to the supply channel can be located inside the bellows pipe and can be made of Teflon (fluoroplastic) or silicone rubber, so it has flexibility. Such a thermal massage device allows both cooling and heating a part of the body at the point of contact with the massaging element.

Claims (18)

1. A heat exchange system comprising a closed loop consisting of a main heat exchange channel, a coolant pumping device, an auxiliary heat exchange channel, and a coolant supply channel connecting the main and auxiliary heat exchange channels, while the coolant pumping device is configured to discharge the coolant in the form of steam or vapor-liquid media from one of the heat exchange channels and pumping this coolant in the form of steam or a vapor-liquid medium with a higher pressure into another heat exchange channel, and the coolant supply channel is made in the form of a channel with a capillary partition that overlaps the channel, while during operation of the heat exchange system the capillary partition of the feed channel resists the penetration of steam, determined by the interaction of menisci with the inner surface of the capillary microchannels of the capillary partition of the feed channel, or resistance to overflow of a vapor-liquid medium, which is determined by the interaction of the meniscus of the bubbles with the inner surface of the capillary microchannels of the capillary septum of the feed channel. 2. The heat exchange system according to claim 1, characterized in that the coolant pumping device is configured to discharge the coolant in the form of steam or a vapor-liquid medium from any heat transfer channel and pump this coolant in the form of steam or a vapor-liquid medium with a higher pressure into another heat transfer channel . 3. The heat exchange system according to claim 1, characterized in that the coolant pumping device is made in the form of a pumping channel with a capillary septum overlapping the channel, and is also equipped with a heat device configured to carry out at least one of the following two modes of operation: the first mode of operation is to remove heat from the surface of the capillary septum facing the main heat exchange channel and / or from the layer of the capillary septum adjacent to this surface, and to supply heat to the a heat-transferring channel to the surface of the capillary septum and / or to the layer of the capillary septum adjacent to this surface, and the second mode of operation is to remove heat from the surface of the capillary septum facing the auxiliary heat-exchange channel and / or from the layer of the capillary septum bordering this surface, and in the heat supply to the surface of the capillary septum facing the main heat exchange channel and / or to the capillary septum layer adjacent to this surface, while t The thermal device can also be configured to simultaneously carry out heat supply or removal processes on both surfaces of the capillary septum facing the main and auxiliary heat-exchange channels and / or in the layers adjacent to these surfaces. 4. The heat exchange system according to claim 3, characterized in that the thermal device is made using a thermoelectric module, while one surface of the junctions of the thermoelectric module is connected by thermal contact with the surface of the capillary septum facing the main heat exchange channel, or with a layer of capillary septum bordering with this surface, and the other surface of the junctions of the thermoelectric module is connected by thermal contact with the surface of the capillary septum facing the auxiliary heat mennomu channel, or with a layer of capillary walls bordering on this surface. 5. The heat exchange system according to claim 3, characterized in that a pipeline is installed connecting the auxiliary heat exchange channel with the capillary partition of the pumping channel. 6. The heat exchange system according to claim 3, characterized in that a pipeline is installed connecting the auxiliary heat exchange channel with the capillary baffle of the pumping channel, a capillary baffle is installed in the pipeline, and this capillary baffle can occupy the entire internal volume of the pipeline. 7. The heat exchange system according to claim 1, characterized in that the capillary septum in the supply channel occupies the entire internal volume between the main and auxiliary heat exchange channels. 8. The heat exchange system according to claim 1, characterized in that part of the capillary septum of the supply channel is connected by thermal contact with part of the main heat transfer channel. 9. The heat exchange system according to claim 1, characterized in that part of the inner surface of the main heat transfer channel is coated with a capillary structure. 10. The heat exchange system according to claim 1, characterized in that the capillary structure of the main heat transfer channel is connected to the capillary partition of the feed channel by a capillary bridge. 11. The heat exchange system according to claim 3, characterized in that the part of the coolant supply channel is connected by a thermal contact to a part of the capillary partition of the pumping channel, and the thermal contact of the part of the supply channel and part of the capillary partition can be arranged in a counterflow circuit. 12. The heat exchange system according to claim 3, characterized in that the coolant supply channel is laid inside the capillary partition of the pumping channel. 13. The heat exchange system according to claim 1, characterized in that the coolant pumping device is made in the form of evaporative-condensing heat exchangers connected in series with a displacement channel between them, consisting of two capillary partitions that overlap the channel, and is equipped with an attachment for supply and / or removal heat in the areas of the capillary partitions of the displacement channel. 14. The heat exchange system according to claim 1, characterized in that it is equipped with a heat device configured to supply heat to the surface of the capillary septum of the supply channel facing the main heat exchanger channel or to the capillary septum layer adjacent to this surface, and / or heat removal with the surface of the capillary septum of the feed channel facing the main heat exchange channel or from the layer of the capillary septum adjacent to this surface. 15. The heat exchange system according to claim 1, characterized in that the closed loop is made up of an auxiliary heat exchange channel and at least two parallel lines, each of which consists of a coolant supply channel, a main heat exchange channel and a coolant pumping device . 16. The heat exchange system according to claim 3, characterized in that the closed loop is made up of an auxiliary heat exchange channel and at least two parallel lines, each of which consists of a coolant supply channel, a main heat exchange channel and a coolant pumping device while a capillary bridge is installed between the capillary partitions of the pumping channels of various lines. 17. The heat exchange system according to claim 15, characterized in that a capillary bridge is installed between the capillary partitions of the supply channels of the various lines. 18. The heat exchange system according to claim 1, characterized in that the coolant pumping device is made in the form of an additional heat exchange channel and a pumping channel connected in series with a capillary partition that overlaps the channel, the additional heat exchange channel being located between the main heat exchange channel and the pumping channel, as well as the device the pumping device is equipped with a heat device configured to carry out at least one of the following two modes of operation, the first mode of operation is from heat water from the surface of the capillary septum facing the additional heat exchange channel and / or from the layer of the capillary septum adjacent to this surface, and in the heat supply to the surface of the capillary septum facing the auxiliary heat exchange channel and / or to the capillary septum layer bordering this surface, and the second mode of operation is to remove heat from the surface of the capillary septum facing the auxiliary heat exchange channel and / or from the capillary septum layer, face adjacent to this surface, and in the heat supply to the surface of the capillary septum facing the additional heat exchange channel and / or to the capillary septum layer adjacent to this surface, while the heat device can also be configured to realize simultaneously on both surfaces of the capillary septum facing to the main and auxiliary heat transfer channels, and / or in the layers adjacent to these surfaces, the processes of supply or removal of heat.

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