RU2115869C1 - Refrigerator - Google Patents

Abstract

FIELD: refrigerating engineering. SUBSTANCE: refrigerator includes thermoelectric battery and heat-transfer agent circulating system which consists of chamber where evaporation and condensation cavities are divided by capillary-porous checker; cavities are connected through passages of objects to be heated and to be cooled. Surfaces of hot and cold junctions are connected forming thermal contact with housings of evaporation and condensation cavities. Surface of capillary-porous checker in evaporation cavity or in both cavities is connected with inner surface of housing in area of thermal contact with surface of junctions by separate sections. EFFECT: enhanced efficiency and serviceability of refrigerator at any orientation in space. 6 cl, 5 dwg

Description

 The invention relates to refrigeration, in particular to the design of refrigerators, for example, domestic household refrigerators or low-temperature thermostats for thermostabilization of electronic components.

 A refrigerator device is known in which hot junctions of a thermoelectric battery are immersed in a sealed tank with a coolant, and the circulation system is formed by two tubes, one of which is thermally insulated, and the other is a channel of a heated object - a radiator [1]. The disadvantage of this refrigerator is its inability to work with any orientation in space, for example, when the thermoelectric battery is located above the channel of the heated object.

 A known refrigerator, selected as a prototype, containing a thermoelectric battery and a system for circulating the coolant through cold junctions, a channel of a cooled object, hot junctions and a channel of a heated object with a portion of the heat carrier flow from the outlet of the channel of the heated object to the entrance to hot junctions through cold junctions of an additional section [ 2].

 The disadvantage of this design is, firstly, its low efficiency. This is explained by the fact that not all the amount of cold produced in the coolant on cold junctions goes to cooling the channel of the cooled object. The proof of this is the fact that the temperature of the coolant at the entrance to the cold junctions (equal to the temperature of the coolant at the outlet of the channel of the heated object) is higher than the temperature of the coolant at the outlet of the channel of the cooled object. A part of the cold produced per unit time, which is not further used to cool a cooled object, is defined as an inefficiently used part of the cooling capacity of a thermoelectric battery. In the prototype device, it is equal to the product of the amount of coolant circulating through the cold junctions per unit time, its specific heat and the difference between the temperature of the coolant at the entrance to the cold junctions and the temperature of the coolant at the outlet of the channel of the cooled object.

 Secondly, the known design is operable only when the thermoelectric battery is located under the heated object, but above the cooled object. This disadvantage leads, for example, to inconvenience in the layout of the elements of a domestic refrigerator. This is due to the fact that the channel of the cooled object must be placed in the upper part of the refrigerator, because only in this case, due to the natural convection of air inside the refrigerator, the best heat transfer from the entire internal volume of the cabinet to the channel of the cooled object takes place. If the channel of the cooled object is placed in the upper part of the cabinet, then the channel of the heated object, with which heat is discharged into the environment, is forced to place it above the cabinet, which makes the household refrigerator cumbersome. When the channel of the heated object is located evenly over the entire height of the cabinet, we will be forced to place the channel of the cooled object in the lower part of the refrigerator, which impairs heat transfer.

 The aim of the invention is to increase the efficiency and performance in any orientation in space.

 This goal is achieved by the fact that in the design of the refrigerator containing a thermoelectric battery and partially filled with a coolant system of circulation of the coolant through junctions of the thermoelectric battery and channels of the cooled and heated objects, the circulation system of the coolant is equipped with a chamber in which condensation and evaporation cavities are formed, separated by a capillary-porous nozzle while the evaporation cavity through the channels of the heated and cooled objects is connected to the condensation cavity, surface of hot and cold junctions of the thermoelectric battery connected with providing thermal contact with the camera body, respectively in the evaporator and the condensation zones of the cavities in the vaporization chamber or in each individual compound accomplished surface portions of the capillary-porous nozzle and the inner surface of the housing in the area of thermal contact. To ensure thermal contact, a heat pipe may be used. The connection of the individual parts of the surface of the capillary-porous nozzle and the inner surface of the housing can be carried out using studs made on the inner surface and in contact with the surface of the capillary-porous nozzle; the spikes can be made with slots, while the surface of the capillary-porous nozzle in the cavity can be covered with a film. The inner surface of the channel of the cooled object can be made capillary-porous.

 Comparative analysis with the prototype allows us to conclude that the inventive refrigerator is characterized in that the coolant circulation system is equipped with a chamber in which the condensation and evaporation cavities are separated by a capillary-porous nozzle, while the evaporation cavity is connected through the channels of the heated and cooled objects to the condensation cavity, the surface hot and cold junctions of the thermoelectric battery are connected to provide thermal contact with the camera body, respectively, in the zones of of the vapor and condensation cavities, and in the evaporation cavity or in both cavities, the surface of the capillary-porous nozzle is made connected in separate sections with the inner surface of the housing in the area of thermal contact with the surface of the junctions.

 1 and 2 show two versions of the refrigerator; figure 2 shows the use of a heat pipe; figure 3, 4 and 5 shows a diagram of the connection using the spikes: the implementation of spikes with slots (figure 4 and 5), coating the surface of the capillary-porous nozzle with a film (figure 5).

 The refrigerator contains a thermoelectric battery 1 and a coolant circulation system consisting of a chamber 2 and channels of a heated 3 and a cooled 4 objects. A capillary-porous nozzle 5 is installed inside the chamber 2, dividing the chamber into a condensation 6 and an evaporation 7 cavity. In this case, the evaporation cavity 7 is connected via pipelines 8 through the channels of the heated 3 and cooled 4 objects with the condensation cavity 6. The thermoelectric battery 1 is connected with the surfaces of the cold 9 and hot 10 junctions to ensure thermal contact with the chamber body 2, respectively, in the zones of condensation 6 and evaporation 7 cavities. Moreover, in the evaporation cavity or in each cavity, the connection of the individual parts of the surface of the capillary-porous nozzle and the inner surface of the housing in the area of thermal contact with the surface of the junctions is made (Fig. 1).

 To ensure thermal contact of the surface of the junctions of the thermoelectric battery with the camera body can be used heat pipe 11 (figure 2).

 The connection of the individual parts of the surface of the capillary-porous nozzle and the inner surface of the housing in the area of thermal contact with the surface of the junctions can be carried out using spikes 12 made on the inner surface of the housing and in contact with the surface of the capillary-porous nozzle (Fig. 3, 4 and 5).

 The spikes 12 can be made with slots 13 (figure 4), which form channels connecting the sections of the capillary-porous nozzle in contact with the spikes with the cavity volume.

 In this case, the surface of the capillary-porous nozzle 5 can be coated with a film 14 on the outer parts of the surface of the capillary-porous nozzle (relative to the spikes) (Fig. 5).

 The inner surface of the channel 4 of the cooled object can be coated with a capillary-porous structure.

 The refrigerator operates as follows. When you turn on the thermoelectric battery 1, the heat released on the hot junctions 10 through the thermal contact and through the camera body enters the connection points with the surface of the capillary-porous nozzle, which are made in separate sections. Here, vaporization takes place on the resulting evaporating menisci. From the evaporation cavity 7, steam flows through a pipe 8 into the channel 3 of the heated object, condensing in which it gives off the heat of condensation. When the cross section of the channel of the heated object in some place is completely blocked by condensate, then the formed column of liquid under the influence of vapor pressure is transferred further along the channel of the heated object, undergoing further heat discharge. After exiting the channel of the heated object, the condensate flows through the pipe 8 to the channel 4 of the cooled object, where vaporization occurs due to a decrease in the vapor pressure of the coolant in the condensation cavity 6, which takes place due to heat removal from the inner surface of the housing through thermal contact to cold junctions 9. During vaporization latent heat of vaporization is taken in the channel of the cooled object, which leads to heat removal from the cooled object. The resulting vapor enters through a conduit 8 into a condensation cavity, where it condenses on the surface of the housing in the area of thermal contact with the surface of the cold junctions of the thermoelectric battery. In the process of condensation, the amount of condensate increases, forming accumulations in separate areas; and when the height of the cluster reaches a gap in the cavity between the capillary-porous nozzle and the inner surface of the body, the droplet-like accumulations of condensate are absorbed by the capillary-porous nozzle. Condensate can also simply flow down the inner surface or fall in separate drops under the action of mass forces on a capillary-porous nozzle. If in the condensation cavity the surface of the capillary-porous nozzle is made connected in separate sections with the inner surface of the housing in the area of thermal contact, then there is a continuous process of condensate drainage to the capillary-porous nozzle.

 Further, the condensate is pumped by capillary forces through the capillary-porous nozzle to the evaporating menisci formed on the surface of the capillary-porous nozzle in the evaporation cavity. Thus, the process of circulation of the coolant is closed. The operation of the device is generally described.

 Providing a coolant circulation system with a chamber in which the condensation and evaporation cavities are formed, separated by a capillary-porous nozzle, and connecting the evaporation cavity through the channels of the heated and cooled objects with the condensation cavity, as well as connecting thermal surfaces of the hot and cold junctions of the thermoelectric battery with the housing chambers respectively in the zones of the evaporative and condensation cavities and the implementation in the evaporative or in each cavity of the connection By separate sections of the surface of the capillary-porous nozzle and the inner surface of the housing in the area of thermal contact, they increase the efficiency of the device and make it operable for any orientation in space, i.e. at any location of the channel of the cooled object relative to the thermoelectric battery and the channel of the heated object. The increase in the efficiency of the device is due to a significant decrease in the ineffectively used part of the cooling capacity (equal to the product of the amount of circulating coolant per unit time, its specific heat and the difference between the temperature of the coolant at the outlet of the channel of the heated object and the temperature of the liquid during vaporization in the channel of the cooled object). In the proposed device, heat from the channel of the cooled object to the cooled inner surface of the housing in the condensation cavity is transferred by steam, therefore, the amount of circulating coolant is significantly less than in the prototype device with the same heat exchange surfaces and thermal loads in the channels of the cooled object. Since the amount of circulating coolant is significantly reduced, the inefficiently used part of the cooling capacity is also significantly reduced.

 The coolant is pumped through the channels of the heated and cooled objects and through the pipelines connecting them to each other due to the difference in vapor pressures in the evaporation and condensation cavities, which are determined by the temperatures of hot and cold junctions, respectively. Therefore, the device is operable for any orientation in space.

 The implementation of spikes with slots increases the efficiency of the device, since in this case the vaporization surface increases in the evaporation cavity due to the fact that the slots allow additional steam removal from the evaporating menisci of the capillary-porous nozzle located under the spikes, and in this case the condensation surface increases , simultaneously, the slots facilitate the transport of condensate to the capillary-porous nozzle.

 Coating the surface of the capillary-porous nozzle with a film on areas external to the spikes also increases the efficiency of the device, since in the evaporation cavity the film reduces heat transfer from steam to the capillary-porous nozzle under the film, and in the condensation cavity the film excludes vaporization on the surface of the capillary-porous nozzle and, therefore , reduces the thermal load on cold junctions.

 The coolant enters the channel of the cooled object in batches, and in order to keep the entire surface of the channel of the cooled object wet between the processes of the arrival of the next portion, the inner surface of the channel of the cooled object is made capillary-porous. In this case, the incoming portion of the coolant in the form of a liquid column moves along the entire length of the channel of the cooled object and impregnates the capillary-porous structure of its surface. The excess also in the form of a column of liquid enters the condensation cavity and is then pumped through the capillary-porous nozzle.

 Consider a refrigerator in which, in both cavities, the individual parts of the surface of the capillary-porous nozzle are connected to the inner surface of the housing in the area of thermal contact with the surface of the junctions. If the current direction in the thermoelectric battery is changed to the opposite, then the processes in the chamber cavities and in the channels of the heated and cooled objects will qualitatively change. There will be an inversion between the processes of condensation and evaporation, the direction of circulation of the coolant will also change. Heat will be generated in the channel of the cooled object, and heat absorption in the channel of the heated object. For example, at a fixed temperature of the channel of the heated object, by changing the current strength and its direction in the thermoelectric battery, you can change the temperature of the channel of the cooled object, it will take values both lower and higher values of the temperature of the channel of the heated object.

 Literature.

 1. Kolenko E. A. Thermoelectric cooling devices. -L .: Nauka, 1967, p. 80-81.

 2. A. p. N 309214, F 25 B 21/02, 1971, BI N 22.

Claims (6)

 1. A refrigerator containing a thermoelectric battery and a coolant circulation system through the junctions of the thermoelectric battery and channels of the cooled and heated objects, characterized in that the circulation system is provided with a chamber in which the condensation and evaporation cavities separated by a capillary-porous nozzle are formed, while the evaporation cavity is connected through channels of heated and cooled objects with a condensation cavity, and the surfaces of hot and cold junctions of a thermoelectric battery are connected to especheniem thermal contact with the housing chamber, respectively in the evaporator and the condensation zones of the cavities, the cavities in the evaporator or in both cavities capillary-porous surface of the nozzle is formed separate portions connected to the inner surface of the housing in thermal contact with the junction surface.  2. The refrigerator according to claim 1, characterized in that a heat pipe is used to heat contact the surface of the junctions of the thermoelectric battery with the camera body.  3. The refrigerator according to claim 1, characterized in that the connection of the individual parts of the surface of the capillary-porous nozzle and the inner surface of the housing in the area of thermal contact with the surface of the junctions is carried out using spikes made on the inner surface of the housing and in contact with the surface of the capillary-porous nozzle.  4. The refrigerator according to claims 1 and 3, characterized in that the spikes are made with slots.  5. The refrigerator according to claims 1, 3 and 4, characterized in that the surface of the capillary-porous nozzle in the cavity is covered with a film.  6. The refrigerator according to claim 1, characterized in that the inner surface of the channel of the cooled object is made capillary-porous.

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