RU2162576C2 - Refrigerating unit of domestic compression refrigerator - Google Patents

Abstract

FIELD: refrigerating engineering. SUBSTANCE: condenser of proposed refrigerator is made in form of flat coil mounted vertically on metal sheet. Evaporator is made in form of rectangular box consisting of two aluminum sheets connected together forming passages between them for evaporation of refrigerant; it is provided with refrigerant inlet and outlet. Condenser surface is coated with heat-conducting absorbent. Condenser is provided with water dispensing and collecting chutes. secured in its upper and lower parts, respectively. Evaporator box is placed in rectangular hermetic casing filled with non-freezing cold-accumulating liquid. Movable support of compressor suspension is kinematically linked with rod of water pump rigidly secured to housing. Water pump is provided with water reservoir and two check valves fitted in its suction and discharge lines. Discharge pipe line is connected with dispensing chute and section pipe line is laid in water reservoir. Kinematic linked of compressor movable support with water pump rod may made in form of connecting rod with hinges. EFFECT: reduced power requirements. 4 cl, 1 dwg

Description

 The present invention relates to mechanical engineering, more specifically it relates to the production of household refrigeration appliances (BHP). It can be used at the factories of the Russian Association of Household Refrigeration Manufacturers "Holod-Byt", as well as other factories producing BHP with reduced energy consumption while ensuring a given cooling capacity, i.e. with low specific energy consumption.

 Known devices for a similar purpose, for example, BHP "Snowflake M" with forced blowing of the condenser. They are described in the journal "Refrigeration", N 2 for 1991, S. 8/1 /. In this BHP there is a heat-insulating cabinet and a door with a seal, a compressor with an engine, a condenser with a casing, a fan with an impeller working synchronously with the compressor, used to intensify the heat transfer of the condenser by increasing convection. The main disadvantage of this BHP should be attributed to the low heat transfer rate of its capacitor. Heat transfer is carried out only by convection of air and radiation from heated surfaces. The consequence of this drawback is the increase in condensation pressure, which leads to an increase in the load on the compressor motor and, ultimately, to an increase in its energy consumption, as well as an increased noise level from the fan.

 A device for a refrigeration unit of a household compression refrigerator is known. It is described, for example, in the book / 2 / on p. 99. This device contains a compressor with an electric motor and its automatic control system, compressor suspension, discharge and suction pipelines, a condenser, a filter drier, a capillary tube and an evaporator, the evaporator, as well as the condenser, with natural convective heat transfer. In this case, the condenser is a continuation of the discharge pipeline, it is a flat coil of pipe mounted on a vertical metal sheet, and the evaporator is made in the form of a rectangular box, which consists of two aluminum sheets bonded to each other with placement of channels for refrigerant evaporation between them and provided with entry points and refrigerant outlet. In this device of the BHP refrigeration unit, the compressor motor operates in intermittent mode with a rather high overload coefficient. This mode of operation of the motor causes its windings to heat up to a high temperature. A significant amount of electricity is spent on heating, which leads to a decrease in the efficiency (efficiency) of the compressor motor (according to / 2 /, p. 132, to values of 0.5-0.7), to an increase in their consumption of electricity to ensure a given cooling capacity of BHP . The coefficient of working time (krv) of such BHP is about 0.5. To maintain the set temperature and cooling capacity, the automatic temperature control system (CART) of BHP often includes a compressor motor, which leads to an increase in the power consumption of BHP. The disadvantage of BHP of such a design is the low heat exchange rate of its capacitor, which implements the process of heat exchange with the environment only by natural convection of air and radiation from its heated surfaces. It does not involve the most efficient evaporation cooling method. Although it is known ("Elementary Textbook of Physics" / Ed. By P. P. Landsberg. - Vol. 1, "Science". - 1967, p. 524/3 /), that evaporation causes cooling of the liquid, and at the same time , and surrounding bodies. In this case, the heat of vaporization is borrowed from the liquid itself. However, intense heat is generated inside the condenser of such BCP during condensation of refrigerant vapor, and this heat is removed from its outer surface in an inefficient way. This leads to an increase in condensation pressure, as a result of which the load on the compressor motor increases and its energy consumption increases.

 Thus, the main disadvantage of this known design of BHP is that it has a low efficiency of the compressor motor, low efficiency of the evaporator and condenser, which results in high energy consumption to obtain the desired cooling capacity.

 In essence and the majority of technical features, the closest analogue to the claimed invention is the device of the refrigeration unit of a household compression refrigerator described in / 2, p. 99 /, therefore it is taken by us as a prototype.

 A simple combination of the technical features of known devices (analogues and prototype) will not allow to reduce the energy consumption of the refrigeration unit while providing them with a given cooling capacity.

 The claimed technical solution is free from the disadvantages inherent in both analogues and prototype.

 The purpose of the proposed technical solution is to reduce energy consumption during the production of cold in domestic refrigeration appliances.

 This goal is achieved by the fact that in the known device of the refrigeration unit of a household compression refrigerator containing a compressor with an electric motor and its automatic control system, a compressor suspension, discharge and suction pipelines, a filter drier, a capillary tube, an evaporator and a condenser, the condenser being a vertically mounted on a metal sheet a flat coil made of pipe, and the evaporator is made in the form of a rectangular box, which consists of two fastened x is between aluminum sheets with the interposition of channels for evaporating refrigerant, and provided with entry and places its output in order to reduce power consumption of the compressor motor in the production of cold in BHP surface coated with a thermally conductive capacitor adsorbent. The capacitor itself is equipped with dispensing and water collecting trays, respectively mounted in its upper and lower parts. The evaporator box in the device is placed in a rectangular sealed casing, which is filled with non-freezing cold-accumulating liquid. In this case, the movable bearings of the compressor suspension are kinematically connected to the rod of the water pump, which is rigidly fixed to the body, and the pump itself is equipped with a tank of water and two check valves installed on its suction and pressure pipes, and the pressure pipe is connected to the dispensing tray, and the suction pipe is placed in a container of water. Moreover, the kinematic connection of the movable support of the compressor with the rod of the water pump, which is fixed to the body, can be made in the form of a connecting rod with hinges, and for uniformity of moistening of the heat-conducting adsorbent, the dispensing tray can be equipped with holes in the bottom. In addition, for aromatization and disinfection of the air evaporated from the surface of the condenser, moisturizing the room in which the device is installed, replaceable containers with appropriate ingredients can be fixed inside the water tank by means of clamps.

 The essence of the proposed technical solution is illustrated by drawings.

 In FIG. 1 shows a refrigeration unit of a domestic compression refrigerator. It consists of a compressor with an electric motor 1 and its automatic control system (ACS) (self-propelled guns not shown in the drawing), compressor suspension 2, discharge 3 and 4 suction pipelines, a desiccant filter, a capillary tube (not shown in the drawing), an evaporator 5 and capacitor 6. Moreover, the capacitor 6 is a vertically mounted flat coil 7 from a pipe 8 on the metal sheet 7, the outer surface of which is coated with a heat-conducting adsorbent 9 (Fig. 2). The capacitor 6 itself is equipped with a dispensing 10 and water collecting trays 11, respectively mounted on its upper and lower parts. In the unit, the evaporator 5, made in the form of two aluminum sheets bonded to each other with placement of channels between them for evaporating the refrigerant and provided with places for its input and output 3, 4, is placed in a rectangular sealed casing 13. The space around the evaporator 5 and the casing 13 is filled with non-freezing cold-accumulating liquid 14. The movable support of the compressor suspension kinematically using a connecting rod 15 by hinges 16 and 17 is connected to the stem 18 of the water pump 19, which is rigidly attached to the housing. The pump 19 itself is equipped with a tank of water 20 and two check valves 21 and 22 mounted on its suction 23 and pressure head 24 pipelines. Moreover, the pipe 24 is connected to the dispensing tray 10 of the condenser 6, and the pipe 23 is connected to the tank 20, in which, for flavoring and disinfection of the air evaporating from the surface of the condenser moisturizing the room in which it is installed, replaceable containers are fixed inside the tank with water by means of clamps ingredients (clamps and containers are not shown in the drawing). In this device, the discharge pipe 5 is designed to transfer refrigerant from the compressor 1 through the condenser 6 to the evaporator 5, between which a capillary tube is installed (not shown in the drawing). It is designed to realize the effect of throttling. Condenser 6 is designed to cool superheated refrigerant vapors and condensate in it at high pressure. As a result, their specific energy consumption is reduced in the production of cold. The condenser 6 in this mode of operation of the compressor motor 1 should ensure efficient heat transfer from the superheated refrigerant vapor inside it to the environment surrounding it (in this case, the heat-conducting porous adsorbent 9, in the pores of which there is water) with no increase in condensation pressure inside it. What should happen only in case of its effective operation is a significant improvement in the process of heat exchange of the condenser. To increase the heat transfer rate, the surface of the condenser 6 is covered with a heat-conducting adsorbent 9, which is designed to absorb the water supplied to it by the dispensing tray 10 and cool the superheated refrigerant vapor inside the condenser 6. In this case, cooling - heat exchange of the condenser agent heated by the vapor and the environment should occur by natural convection air, emitting from its heated surfaces and the evaporation of water, which, evaporating from the pores of the heat-conducting adsorbent 9, is itself due to this cooling tsya, and cools the heat-conducting adsorbent 9, its surrounding. The high thermal conductivity of the adsorbent, the metal sheet 7 and the flat coil from the pipe 8, allows efficient cooling of the refrigerant vapor inside the pipe of the coil 8, which ultimately allows not to increase the high condensation pressure of the agent vapor and, thereby, reduces the load on the compressor motor 1, increases it Efficiency, as a result of which energy is saved when receiving cold. The process of evaporation of water from the adsorbent 9 when it is heated reduces its amount. If the adsorbent 9 is not fed with water, this will lead to a deterioration in the heat exchange of the condenser 6 with the environment due to the fact that its cooling will occur only by natural convection and radiation, which, ultimately, will increase the energy consumption of the compressor 1. To reduce this indicator, the capacitor 6 is equipped with dispensing and water collecting trays 10, 11, which are mounted respectively on its upper and lower parts. From the upper tray, through the holes in its bottom, water, as it evaporates, should flow to the heat-conducting adsorbent 9, thereby allowing efficient cooling of the condenser 6 and, ultimately, to reduce the energy consumption of BHP. Excess water under the action of its own weight flows from a vertically mounted metal sheet 7 into the lower tray 11, from which they must enter the tank with water 20 to ensure the continuity of the cooling process, and hence the continuity of the energy-saving process. The compressor design has one irremovable property - the presence of unbalanced masses, due to which during its operation there are inertia forces that cause compressor vibrations. To damp inertial loads, the compressor is mounted on a fixed casing through the springs of its suspension 2, which serve to absorb vibrations, however, the compressor casing with an electric motor oscillates. The kinematic connection of the movable bearings 24 of the compressor with the electric motor 1 with the rod 18 of the water pump 19, which is rigidly fixed to the housing, and the possible implementation of this connection in the form of a connecting rod 15 and hinges 16 and 17, ensures the smooth operation of the pump 19 when the compressor is running with the electric motor 1. The pump 19 must pump water from the tank with water 20 through the check valve 22 and pipe 24 and feed it to the dispensing tray 10 of the condenser 6 to absorb water with the adsorbent 9 of the condenser 6, subsequent evaporation and cooling reducing refrigerant vapor to a condensation temperature at a vapor pressure that provides economical operation of the compressor motor and, thereby, increasing the efficiency of the electric motor and saving its energy consumption.

 The refrigeration unit of a household compression refrigerator operates as follows.

 Pour water into the tank 20 and turn on the compressor 1 motor. While working, the compressor draws in refrigerant vapors through the suction pipe 4, compresses them, and they heat up, and through the discharge pipe 3 feeds them into the condenser 6. When the compressor 1 is working, due to the available in it unbalanced masses, inertia forces arise. Since the compressor is mounted on a fixed casing through the springs of its suspension 2, due to the action of inertia, the compressor casing with the electric motor 1 oscillates. These vibrations through the hinges 16 and 17 by the connecting rod 15 are transmitted to the rod 18 of the water pump 19, which is rigidly fixed to the housing. The rod 18 of the pump 19, moving up and down, pumps water from a tank of water 20 through a non-return valve 21 and a pipe 23 and feeds it through a non-return valve 22 and a pipe 24 to the dispensing tray 10 of the condenser 6. Water under its own weight through the holes in the bottom of the dispensing tray 10 (not shown in the drawing) enters the heat-conducting adsorbent 9 (Fig. 2) of the condenser 6. Since the adsorbent 9 is made of porous cermet, the water is absorbed by it. Excess water, seeping through the pores of the adsorbent 9, flows into a tray 11 installed in the lower part of the condenser 6, and then into a container of water 20. Then, the water is again pumped 19 to the dispensing tray 10. Then the cycle is repeated many times.

 Compressed by the compressor 1 to a high pressure, the refrigerant vapor entering the condenser 6 has a high temperature. They sequentially, heating the condenser (pipe 8, metal sheet 7, adsorbent 9 and water located in the pores of the adsorbent), while themselves giving off heat, they are cooled, and because of this they condense. The condensation process during cooling proceeds intensively at a low condensation pressure. This is because the cooling of the condenser 6 occurs by natural convection of air, radiation from its heated surfaces and evaporation of water from the pores of the heat-conducting adsorbent 9. Even the high temperature of the air outside the BHP does not cause an increase in the condensation pressure, since in this case the process of water evaporation is intensified from the pores of the adsorbent and it continues to cool the condenser efficiently. Moreover, taking into account that inside the water tank 20, removable containers with the corresponding ingredients are fixed by means of clamps (they are not shown in the drawing), the evaporation of water from the surface of the condenser 6 leads to aromatization and disinfection of the air that evaporates from the surface of the condenser moisturizing the room in which it installed.

 Ongoing operation of the compressor and injection of refrigerant vapor by it moves condensate through the filter drier and capillary tube (not shown in the drawing) to the evaporator 5. At the outlet of the capillary tube to the evaporator (not shown in the drawing), the refrigerant pressure decreases from the condensing pressure to the boiling pressure. The liquid refrigerant boiling in the evaporator 5 absorbs heat from its environment (in this case, from the heat-conducting porous adsorbent 9, the pores of which are filled with water). Since the evaporator 5 is made in the form of two aluminum sheets fastened together with the placement of channels between them for evaporating the refrigerant and is provided with places for introducing and discharging the refrigerant 3, 4, the entire surface of the evaporator 5 is intensively and uniformly cooled. The rectangular shape of the box 13 of the evaporator 5 allows you to evenly transfer the resulting cold into the medium to be cooled (cold storage liquid 14) and further, into the chamber 25 of the low-temperature compartment of BHP.

The operation of the compressor with electric motor 1 and the cooling process continue until the desired BHP mode is reached. Given the large mass of liquid 14, as well as the low temperature of its cooling (for example, an aqueous solution of calcium chloride when the salt content in the solution 29.9% freezes at a temperature of -55 ^o C, and cooling can be carried out to a temperature close to freezing), then until the BHP mode is reached, the compressor with electric motor 1 operates for a long time. The cold storage liquid (intermediate coolant) 14 accumulates cold and cools to a low initial storage temperature of the products. When this temperature is reached, CAPT (it is not shown in the drawing) turns off the compressor 1 motor. The CART will restart the compressor 1 motor after the accumulated cold has been used up. To re-enable the compressor motor 1, the temperature in the low-temperature chamber 25 should increase (due to heat influx from outside to inside the BHP) to an allowable extremely high storage temperature of the products.

Since the range of minus temperatures for storing products before re-starting is large (and can be on the order of -55 ^o and - up to -15 ^o and higher), with a small amount of heat gain from outside to inside the BHP, the time period between turning on and off the electric motor is quite large. The BHP compressor electric motor operates in a continuous mode, in which the motor overload coefficient and the temperature of heating of its windings are significantly reduced, which increases the efficiency of the engine and BHP as a whole.

 Thus, the use of this refrigeration unit of a household compression refrigerator can reduce energy consumption while ensuring a given cooling capacity, i.e. produce household refrigeration appliances with reduced specific energy consumption.

Sources of information
1. V.A. Boyarkin, I.G. Uporova, G.S. Aliyev. Intensification of heat transfer in the condenser of a domestic refrigerator // Refrigeration equipment. - N 2, 1991, p. 8.

 2. V.B. Weinberg and V.L. Vine. Household compression refrigerators. - M.: - Food industry. - 1974, p. 99-101.

 3. Elementary textbook of physics. / Ed. P.S. Landsberg. - TL, - M.: - Science. - 1967, p. 524.

Claims (4)

 1. The refrigeration unit of a household compression refrigerator, comprising a compressor with an electric motor and its automatic control system, a compressor suspension, discharge and suction pipelines, a filter drier, a capillary tube, an evaporator and a condenser, the condenser being a vertically mounted flat coil made of metal sheet pipes, and the evaporator is made in the form of a rectangular box, which consists of two aluminum sheets fastened to each other with placement Between them there are channels for refrigerant evaporation and is equipped with places for its entry and exit, characterized in that the surface of the condenser is covered with a heat-conducting adsorbent, and the condenser is equipped with dispensing and water-collecting trays, respectively fixed in its upper and lower parts, the evaporator box is placed in a rectangular tight a casing filled with non-freezing cold-accumulating liquid, while the movable bearings of the compressor suspension are kinematically connected to the rod of the water pump rigidly fixed to the housing, and the pump itself is equipped with a tank with water and two check valves installed on its suction and pressure pipelines, and the pressure pipe is connected to the dispensing tray, and the suction is placed in the tank with water.  2. The device of the refrigeration unit of a household compression refrigerator according to claim 1, characterized in that the kinematic connection of the compressor movable support to the rod of the water pump fixed to the device body is made in the form of a connecting rod with hinges.  3. The device of the refrigeration unit of a household compression refrigerator according to claims 1 and 2, characterized in that for the uniformity of moistening of the heat-conducting adsorbent, the dispensing tray is provided with openings in the bottom.  4. The device of the refrigeration unit of a household compression refrigerator according to claims 1 to 3, characterized in that for the aromatization and disinfection of the air evaporated from the surface of the condenser moisturizing the room in which it is installed, replaceable containers with the corresponding ingredients are fixed inside the water tank by means of clamps.

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