RU37810U1 - REFRIGERATOR - Google Patents

Description

A utility model relates to the field of cooling and maintaining the required temperature of a medium in a limited volume at a certain ambient temperature without the use of additional energy or with a small amount of additional energy.

Known refrigerator described in the application for the invention of Russia "Refrigerator No. 94005794, F 25D 11/00, 1/00, s. 02/18/94, op. 10.20.95. (see copy of description).

In the well-known refrigerator, the low-temperature and cooling chambers are made with a through channel to which a pipe is connected, which communicates with the external environment, equipped with a dust filter and dampers made with the possibility of full and partial opening and closing.

Additional cooling of the low-temperature and cooling chambers is carried out by external air supplied through a through channel with a nozzle with flaps and a dust filter and miscible with air of the low-temperature and cooling chambers.

However, this solution, designed to cool the air inside the chambers, has a drawback: the outside air, entering the low-temperature and cooling chambers where the products for cooling are located, dries them, worsening their taste. In addition, the filter is an obstacle to the passage of outside air, and it constantly grows as the filter becomes dirty, so you can not do without forced flow formation, and therefore additional energy costs. If the filter cells are large and do not show significant resistance to the flow of external air, then the filter will be ineffective in terms of air purification.

Known underground refrigerator described in the patent for the invention of Russia "Underground refrigerator No. 2129190, F 25D 13/00, E02D 29/00, B65 / G 5/00 C. 05/05/95, op. 04/20/99. (see copy of description).

In a well-known underground refrigerator including a chamber, its walls, a heat-insulating layer, a seasonal cooling system, an intermediate layer of moistened material with a certain freezing temperature is laid between the heat-insulating layer and the walls of the chamber. Refrigerator

MKI-7: F25D 1/00

Additional cooling of the chamber is carried out using an intermediate layer of moistened material that completely freezes in winter, gradually thaws in summer, from surrounding warmer soil, which does not reach thawing at the walls of the chamber, which reduces the rate of energy consumption due to the use of a winter supply of cold in summer.

However, this solution, designed to cool the air inside the chambers, is a drawback: air cooling occurs as a result of accumulation of cold in the winter, that is, the cooling process is extended in time, at least for the season of the year, and is not advisable for ordinary household refrigerators.

The well-known "Conditioner described in the USSR author's certificate No. 1161791, F 24 F 1/02, s. 02/10/84, op. 06/15/85. (see copy of description).

Additional cooling of the conditioned air is carried out by forced blowing through the heat exchanger with the help of a fan of cold outdoor air mixed with the conditioned.

In the known air conditioner comprising a housing with two compartments, the first compartment is in communication with the atmosphere through a recuperative heat exchanger by a channel with a shutter in the form of shutters located at the outlet of the channel into the atmosphere, an outdoor temperature sensor is installed at the entrance to the first compartment, connected to a fan made reversible.

However, this solution, designed to cool air-conditioned air, has the drawback: additional cooling of the air-conditioned air is carried out by forced blowing through the heat exchanger using a fan of cold outdoor air mixed with air-conditioning, which complicates the principle of cooling and does not reduce energy consumption.

The well-known "Conditioner described in the author's certificate of the USSR No. 1413367, F 24 F 1/02

Additional cooling of the conditioned air is carried out due to the forced circulation of the cooling medium - external air and the cooled medium, which is taken into a special channel, passes through a heat exchanger, is cooled by the cooled medium, without mixing with it, and is returned to the room through another special channel.

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However, this solution, designed for cooling air-conditioned air, has a drawback: additional cooling of the air-conditioned air is carried out outside the room where this air is located. Forced circulation is necessary for the cooling medium and for the cooled medium, which complicates the principle of cooling and increases energy consumption.

The closest, in technical essence, to the claimed refrigerator is the refrigerator described in the USSR copyright certificate "Thermoelectric refrigerator No. 734481, F 25D 9/00, s. 01.16.76, op. 05/15/80, and selected as a prototype (see copy of description).

In the well-known thermoelectric refrigerator, the hot junctions of the cooling device (thermopile) are cooled in the heat exchanger of the secondary chamber, blown through the channels of the secondary chamber by an external air fan, due to heat exchange, which allows the refrigerator to operate as a cold accumulator in the coldest time of the day.

The well-known thermoelectric refrigerator contains a lockable thermally insulated chamber, a cooling device — a thermopile, a thermocouple cooler, is equipped with an additional cooling device — an additional chamber with a thermally insulated body and a system of heat-insulated sectional dampers, in which an additional cooler is installed — a heat exchanger for cooling the hot junctions of the thermopile, with a tight fit to the end wall of the housing of the additional chamber, while in the two side walls of the core channels and thermal insulation of the additional chamber are made channels, one of which is connected to the air duct, through which the air is driven by a fan, the other with the atmosphere, and the dampers are mounted in the channels of the additional chamber with the possibility of overlapping their sections.

This solution is designed to cool the hot junctions of the cooling device (thermopile), and not the air in the chamber and not the products themselves. Its disadvantage is that the use of heat exchange with a fan increases the cooling capacity of the cooling device, by ensuring a temperature difference at the poles of the battery, but at the same time increases the energy consumption and reduces the life of the refrigerator.

The purpose of the claimed utility model is to eliminate this drawback, in particular, increase the refrigeration capacity of the refrigerator while

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reducing energy consumption, improving the operational capabilities of the refrigerator, increasing the overall service life of the refrigerator, increasing the useful area of the rooms in which the refrigerator is used, as well as the possibility of applying new design solutions when using the refrigerator built into the outer wall.

This goal is achieved in that the refrigerator, according to the first embodiment, contains a lockable thermally insulated chamber, a cooling device with a cooler, an additional cooling device with an additional cooler and with adjustable channels passing through the wall of the thermally insulated chamber, for circulation of the medium cooled by outside air, according to a utility model, equipped with a sensor - a relay - a temperature controller, an additional cooling device is made with a working unit that includes a setpoint, execute noe device and regulating device, an aftercooler arranged in thermally insulated chamber regulated channels are sealed and the inlet and outlet of the aftercooler, communicating directly with the outside air circulating in the cavity and overlapping the additional coolant regulating device by means of an apparatus of the set point signal.

In this case, the refrigerator is installed in the wall of the building at the border between the external environment and the room, so that part of the outer surface of the thermally insulated chamber is in contact with the room air, and part with the outside air.

In addition, the additional cooler is made in the form of a special membrane made of heat-conducting material, which seals the thermally insulated chamber hermetically as a partition into two parts - the cavity of the refrigerating chamber with a cooler and the cavity of the additional cooler for circulating outside air in it, or the additional cooler is made in the form of a tubular cavity of heat-conducting materials for circulating outside air in it, in turn, a tubular cavity of heat-conducting materials can be combined with a cooler cradle device.

In this case, the working unit contains a controller consisting of internal and external containers with non-freezing liquid, an actuator consisting of a rod of an internal container, a rod of an external container, a cam of an internal container, a cam of an external container, a roller, a pusher, a tensioner, and a control device consisting of two dampers connected to each other for parallel operation, one of which

opens and closes the inlet of the additional cooler, and the other opens and closes its outlet, or the working unit contains a setter consisting of internal and external containers with non-freezing liquid, an actuator consisting of a rod of an internal tank, a rod of an external tank, a compensator with a slider, an internal cam containers, roller, roller compensator, pusher, tensioner, adjusting device, consisting of two shutters connected to each other for parallel operation, one of which opens and closes in one of the additional cooler, and the other opens and closes its outlet, or the working unit contains a controller consisting of two temperature sensors for the external and internal, an actuator with a two-channel control unit, a control device consisting of two shutters, one of which opens and closes the input of the additional cooler, and the other opens and closes its outlet, or the working unit contains a setter consisting of two temperature sensors for the external and internal, the actuator is adaptive a control unit, a regulating device consisting of two dampers, one of which opens and closes the input of the additional cooler, and the other opens and closes its output, or the working unit contains a controller consisting of two outdoor and indoor temperature sensors, an actuator with a two-channel control unit , a regulating device consisting of a forced circulation unit installed on one of the adjustable channels of the additional cooler, or the working unit contains a controller, consisting s of the two temperature sensors external and internal actuating device with an adaptive control unit, a regulating device consisting of a forced circulation unit installed on one of the channels further controlled cooling.

In addition, the goal is achieved in that, the refrigerator, according to the second embodiment, comprising a lockable thermally insulated chamber, a cooling device with a cooler, an additional cooling device with an additional cooler and with adjustable channels made in the wall of the thermally insulated chamber, for circulation of the medium cooled by the outside air , according to a utility model, is equipped with a sensor - a relay - a temperature controller, an additional cooling device is made with a working unit, including a setpoint, and a filling device and a regulating device, with a tank with a liquid non-freezing cooling medium installed outside the building and, in turn, cooled by outside air, with an additional cooler located in

a thermally insulated chamber made in the form of a tube of heat-conducting materials associated with the formation of a closed system with a tank with a liquid non-freezing cooling medium, at least two tubular elements acting as adjustable channels for the circulation of liquid non-freezing cooling medium, which are hermetic inlet and outlet of an additional cooler and overlapping by a regulating device with the help of an actuator at the signal of the setter.

In this case, the refrigerator is installed in the wall of the building at the border between the external environment and the room, so that part of the outer surface of the thermally insulated chamber is in contact with the room air, and part is in the outside air, and the tube of heat-conducting materials is combined with the cooler of the cooling device.

In addition, the working unit contains a regulator, consisting of an internal container with non-freezing liquid, an actuator with a rod of the internal container, a regulating device mounted on one of the adjustable channels, or the working unit contains a regulator, consisting of an internal temperature sensor, an actuator with a limit unit a control device, a control device mounted on one of the adjustable channels, or the working unit contains a setter consisting of two temperature sensors for the external and internal an actuator with a two-channel control unit, a regulating device with a forced circulation unit installed on one of the adjustable channels, or the working unit contains a controller consisting of two outdoor and indoor temperature sensors, an actuator with an adaptive control unit, a regulating device with a forced unit circulation installed on one of the adjustable channels.

Due to the fact that, for both the first and second options, the additional cooler is placed in the refrigerator’s chamber along with the cooler, it cools itself and cools the chamber when passing through it controlled convective (without the use of electricity) or forced (using a small amount of electricity ) flow of additional cooling medium, the refrigerating capacity of the refrigerator increases.

For both the first and second options, the working unit, which is part of an additional cooling device, including a control unit, an actuator and an adjusting device, is so structurally designed and so controls the operation of the additional cooler that at a certain outdoor temperature

air, only an additional cooler works in the chamber, the cooler is turned off, which reduces energy consumption and increases the overall life of the refrigerator.

In the proposed utility model, the refrigerator can be installed in the outer wall of the building (structure), i.e. on the border between the outside air and the indoor air, which increases the usable area of the rooms in which the refrigerator is used, as well as expands the possibility of applying new design solutions when using the refrigerator built into the external wall.

Thus, the combination of the claimed features can significantly reduce the average annual energy consumption, improve the operational capabilities of the refrigerator, increase the overall life of the refrigerator and increase the useful area of the premises.

The inventive "Refrigerator have novelty, differing from the prototype of the above features, and ensures the achievement of the technical result perceived by the applicant.

The inventive "Refrigerator can be widely used in refrigeration, therefore, meet the criterion of industrial applicability.

The essence of the proposed "Refrigerator is illustrated by drawings, which show:

in FIG. 1 is a general diagram of a refrigerator;

in FIG. 2 is a general diagram of a refrigerator chamber with an additional cooler in the form of a membrane for a cooling medium — outdoor air;

in FIG. 3 - the same, with an additional cooler in the form of a tubular cavity;

in FIG. 4 is a diagram of combining an additional cooler in the form of a tubular cavity with a cooler;

in FIG. 5 is a diagram of a fluid-mechanical working unit for a cooling medium — outdoor air;

in FIG. 6 is a diagram of a fluid-mechanical working unit with a compensator for a cooling medium — outdoor air;

in FIG. 7 is a diagram of a working unit with a two-channel control unit for a cooling medium - outdoor air;

in FIG. 8 is a diagram of a working unit with an adaptive control unit for a cooling medium — outdoor air;

in FIG. 9- diagram of the working unit with a two-channel control unit and with a forced circulation unit for the cooling medium - outdoor air;

in FIG. 10 is a diagram of a working unit with an adaptive control unit and with a forced circulation unit for a cooling medium - outdoor air;

in FIG. 11 is a general diagram of a refrigerator with an additional cooler in the form of a tube with a liquid non-freezing medium;

in FIG. 12 is a diagram of combining a cooler with an additional cooler in the form of a tube;

in FIG. 13 is a diagram of a liquid-mechanical working unit for an additional cooler with a cooling liquid non-freezing medium;

in FIG. 14 is a diagram of a working unit with a limit control unit for a cooling liquid non-freezing medium;

in FIG. 15 is a diagram of a working unit with a two-channel control unit and with a forced circulation unit for a cooling liquid non-freezing medium;

in FIG. 16 is a diagram of a working unit with an adaptive control unit and with a forced circulation unit for a cooling liquid non-freezing medium;

in FIG. 17 is a diagram of a two-channel control unit;

in FIG. 18 is a diagram of an adaptive control side;

in FIG. 19 is a diagram of a limit control unit;

in FIG. 20 is a graphical diagram of the operation of the refrigerator with the inclusion of an additional cooler at TNV Tkdon

in FIG. 21 is a graphical diagram of the operation of the refrigerator with the inclusion of an additional cooler at TNV Tk

The refrigerator 1 is installed in the opening of the outer wall 2 of the building (structure) and has a thermally insulated chamber 3 containing a cooling device 4, a sensor - a temperature regulator relay 5, an additional cooling device 6 (Fig. 1)

The thermally insulated chamber 3, from the side located inside the building (indoors), is closed by a door (cover) 7. In the wall 8 of the thermally insulated chamber 3, located outside the building, hermetically adjustable channels 9 are made for the circulation of the cooling medium (Fig. 1).

The cooling device 4 is a refrigeration unit 10 (in the embodiment, the refrigeration unit consists of a compressor, a condenser, an adjustable valve) installed outside the thermally insulated chamber 3 and a cooler 11 (in the example

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execution evaporator) installed inside the thermally insulated chamber 3, which is included in the work and disconnected from the work on the signal of the sensor - temperature controller relay 5 (figure 1).

The additional cooling device 6 for the refrigerator 1, according to the first embodiment, contains an additional cooler 12 located in the thermally insulated chamber 3 so that the adjustable channels 9 are the input and output of the additional cooler 12, the working unit 13 of the additional cooling device 6, with a setpoint 14, an actuator 15, a regulating device 16 (Fig. 1).

The additional cooler 12, according to the first embodiment, can be made in the form of a special membrane 17 made of heat-conducting material, dividing the thermally insulated chamber 3 hermetically as a partition into two parts - the cavity of the refrigerating chamber 18 with the cooler 11 and the cavity of the additional cooler 19. In the cavity of the additional cooler 19, adjustable channels 9 circulates outside air (Fig. 2).

The additional cooler 12 may also be made in the form of a tubular cavity 20 of heat-conducting material. Outside air circulates in the tubular cavity 20 through adjustable channels 9 (Fig. 3).

The tubular cavity 20 of the heat-conducting material, in turn, can be combined with the cooler 11 (Fig. 4).

The working unit 13 may include a controller 14, consisting of an inner 21 and an outer 22 containers with non-freezing liquid, an actuator 15, consisting of a rod 23 of the inner container 21, a rod 24 of the outer container 22, a cam 25 of the inner container 21, a cam 26 of the outer container 22, roller 27, pusher 28, tensioner 29, adjusting device 16, consisting of two shutters 30, 31 (shutter 31 in Fig. 5 not shown) connected to each other for parallel operation, one of which opens and closes the input 32 of the additional cooler 12 and the other opening and closes its exit 33 (output 33 in Fig. 5 is not shown) (Fig. 5).

The working unit 13 may include a controller 14, consisting of an inner 21 and an outer 22 containers with anti-freezing liquid, an actuator 15, consisting of a rod 23 of the inner container 21, a rod 24 of the outer container 22, a compensator 34 with a slider 35, a cam 25 of the inner container 21, roller 27, roller of compensator 36, pusher 28, tensioner 29, adjusting device 16, consisting of two shutters 30, 31 (shutter 31 in Fig. 6 not shown) connected to each other for

parallel operation, one of which opens and closes the input 32 of the additional cooler 12, and the other opens and closes its output 33 (output 33 in Fig. 6 is not shown) (Fig. 6).

The working unit 13 may include a controller 14, consisting of two temperature sensors, external 37 and internal 38, an actuator 15 with a two-channel control unit 39, a control device 16, consisting of two shutters 30, 31, one of which opens and closes the input 32 of the additional cooler 12, and the other opens and closes its exit 33 (Fig. 7).

The working unit 13 may include a regulator 14, consisting of two temperature sensors, external 37 and internal 38, an actuator 15 with an adaptive control unit 40, a control device 16, consisting of two shutters 30, 31, one of which opens and closes the input 32 of the additional cooler 12, and the other opens and closes its exit 33 (Fig. 8).

The working unit 13 may include a controller 14, which consists of two temperature sensors outside 37 and inside 38, an actuator 15 with a two-channel control unit 39, a control device 16 with a forced circulation unit 41 (in the example, a fan) installed on one of the adjustable channels 9 additional cooler 12 (Fig. 9).

The working unit 13 may include a controller 14, consisting of two temperature sensors outside 37 and inside 38, an actuator 15. with an adaptive control unit 40, a regulating device 16 with a forced circulation unit 41 (in the example, a fan) installed on one of the adjustable channels 9 additional cooler 12 (Fig. 10).

The additional cooling device 6 for the refrigerator 1, according to the second embodiment, comprises a working unit 13 of the additional cooling device 6, with a setter 14, an actuator 15, an adjusting device 16, a container 42 with liquid non-freezing cooling medium 43 installed outside the wall 2 of the building. An additional cooler 12, located in the thermally insulated chamber 3, is made in the form of a tube 44 of heat-conducting materials, associated with the formation of a closed system with a capacity of 42 with liquid non-freezing cooling medium 43, at least two tubular elements 45, acting as adjustable channels 9, which are tight input and output of an additional cooler and

overlapping control device 16 using the actuator 15 at the signal of the master 14 (Fig. 11).

An additional cooler 12 in the form of a tube 44 of heat-conducting materials can be combined with a cooler 11 (Fig. 12).

The working unit 13 contains a controller 14, consisting of an internal reservoir 46 with anti-freezing liquid, an actuator 15 with a stem 47 of the inner reservoir 46, a control device 16 mounted on one of the adjustable channels 9 (Fig. 13).

The working unit 13 may include a controller 14, consisting of an internal temperature sensor 38, an actuator 15 with a limit control unit 48, a regulating device 16 mounted on one of the adjustable channels 9 (Fig. 14).

The working unit 13 may include a controller 14, consisting of two temperature sensors, external 49 and internal 38, an actuator 15 with a two-channel control unit 39, a control device 16 with a block

forced circulation 50 (in the example of the pump) installed on one of the adjustable channels 9 (Fig. 15).

The working unit 13 may include a controller 14, which consists of two temperature sensors, external 49 and internal 38, an actuator 15 with an adaptive control unit 40, a control device 16 with a forced circulation unit 50 (in the embodiment, a pump) installed on one of the adjustable channels 9 (Fig. 16).

The two-channel control unit 39 contains contact groups Kl, K2 connected in series to the circuit and comparing elements Cl, C2, each of which controls a specific contact group (C1 - K1), (C2 - K2), respectively (Fig. 17).

Adaptive control unit 40 contains contact groups Kl, K2, KZ, connected K1 and K2 in parallel, and KZ in series with this pair contains comparative elements Cl, C2, СЗ, each of which controls a specific contact group (C1 - K1), (C2 - K2), (SZ - KZ), respectively (Fig. 18).

The limit control unit 48 contains a contact group K1 connected in series with a comparing element C1, controlling a contact group (C 1 - K1) (Fig. 19).

The operation of the refrigerator is carried out as follows, in addition to transferring the cold from the cooling medium of the cooler 11 to the air in the chamber 3, cooling and maintaining the temperature of the air in the chamber 3 are additionally carried out, not miscible with the air in the chamber 3 and cooled by the outside air, circulating through the cavity of the additional cooler 12, installed in the chamber 3. The circulation, cooled by the outside air, of the medium may be natural or forced. As the medium circulating through the additional cooler 12, external air or a cooling liquid non-freezing medium is used.

The operation of the refrigerator 1 can be controlled by the sensor with a temperature regulator 5, which enables and disables the cooler 11 through the cooling unit 10 and the working unit 13 of the additional cooling device 6, which turns on and off the additional cooler 12 with the medium cooled by the outside air, so that the sensor is a relay-regulator temperature 5 set a specific operating temperature range (Tkon - Tkok) operation of the cooler 11, while the upper limit of the working temperature range Tkon work cooler 11 determines the moment of its turning on, and the lower limit of the operating temperature range Tkok of operation of the cooler 11 determines the moment of turning it off, the working unit 13 sets a certain working temperature interval (Tkdon - Tkdok) of the additional cooler 12, while the upper value of the working temperature range Tkdon of the additional cooler 12 determines the moment of its inclusion and is adjusted below the upper limit of the working temperature range Tkon of operation of the cooler 11, but above the lower limit of the working temperature range The operating temperature of the cooler 11, the lower value of the operating temperature range Ткдок of the additional cooler 12 determines the moment it is turned off and is set below the lower limit of the operating temperature interval Ткок of the operation of the cooler 11, when the temperature Tk in the chamber 3 rises to the upper limit of the operating temperature range Ткон operation of the cooler And, it, the cooler 11, turns on and transfers the cold to the air in the chamber 3, cooling it to the lower limit of the operating temperature range Tkok of the operation of the cooler 11, at which the cooler 11 stops working, and when the outdoor temperature Tnv drops to the upper temperature range Tkdon of the additional cooler 12, the working unit 13 includes an additional cooler 12, which transfers cold to the air in the chamber 3, with a further decrease in the outdoor temperature Tnv, as the air temperature reaches chamber 3 of the lower value of the operating temperature range

cooler 12, the working unit 13 turns off the additional cooler 12, stopping the transfer of cold to the chamber 3 through the additional cooler 12, when the temperature Tk in the chamber 3 rises, the working block 13 will turn on the additional cooler 12 again and turn it off when lowering, repeating such cycles until since then. until the outdoor air temperature Tnv becomes higher than the upper value of the operating temperature range Tkdon of the additional cooler 12, after which the air temperature Tk in the chamber 3 rises to the upper limit of the working temperature range Tkon of operation of the cooler 11 and will turn on again and turn off the cooler 11, repeating such cycles until the temperature of the outside air Tnv drops, and the working unit 13 starts again turning on and off the additional cooler 12 (Fig. 20).

The operation of the refrigerator 1 can be controlled by a sensor with a temperature regulator 5, which enables and disables the cooler 11 through the refrigeration unit 10 and the operating unit 13 of the additional cooling device 6, which turns on and off the additional cooler 12 with the medium cooled by the outside air, similar to the method described above, but in the zone outdoor temperature Тнв, exceeding the upper value of the operating temperature range Ткдон of an additional cooler 12, the working unit 13 includes additional cooling cooler 12 and operates according to the method described above, when the air temperature Tk in the chamber 3 rises to values exceeding the value of the outdoor temperature Tnv, and turns off the additional cooler 12 when the air temperature Tk in the chamber 3 decreases to values equal to or lower than the outdoor temperature Tnv (Fig. 21).

The control of an additional cooler 12 with a cooling medium - outside air can be carried out by the working unit 13 without using electricity in such a way that, according to the signal of the setter 14, the actuator 15 and the regulating device 16 of the two shutters 30, 31 are connected to each other for parallel operation, at the same time, one opens the input 32 of the additional cooler 12, and the other - the output 33 of the additional cooler 12, which ensures the natural circulation of outdoor air at a lower temperature by additional body cooler 12 and the required temperature in the chamber 3.

With an increase in the temperature of the outside air Tnv, the volume of non-freezing liquid in the outer container 22 increases and displaces the stem 24, the cam 26 pivotally connected to it moves and closes the shutter 30 through the roller 27 and the pusher 28 regardless of the position of the cam 25. When the temperature of the outdoor air Tnv decreases

the cam 26 becomes in a position where the pusher 28 will move under the action of the cam 25. With an increase in the air temperature Tk in the chamber 3, the non-freezing liquid of the inner container 21 will displace the rod 23 and move the cam 25 to the position where the pusher 28 will allow the shutter 30 to open under the tensioner 29. When the air temperature Tk decreases in the chamber 3, the rod 23 will move together with the cam 25. Press the pusher and close the shutter 30, the device (Fig. 5).

The control of an additional cooler 12 with a cooling medium - outside air can be carried out by the working unit 13 without using electricity in such a way that, according to the signal of the setter 14, an actuator 15 with a compensator 34 and a regulating device 16 of two shutters 30, 31 are connected to each other with the other for parallel operation, while one of them opens the input 32 of the additional cooler 12, and the other - the output 33 of the additional cooler 12, which ensures the natural circulation of external air of reduced temperature perature of the aftercooler 12 and the desired temperature in the chamber 3.

With increasing air temperature Tk in the chamber, a non-freezing liquid of the inner container 21 will displace the rod 23 and move the cam 25 to the position where the compensator 34 and the pusher 28 will allow the shutter 30 to open under the action of the tensioner 29. When the temperature Tk of the air in the chamber 3 decreases, the rod 23 of the inner container 21 moves with cam 25, pushes pusher 28 through compensator 34, and closes shutter 30.

When the outdoor temperature Tnv rises above the air temperature Tk in the chamber 3, the non-freezing liquid in the outer container 22 will displace the rod 24, raise the slider 35c with the compensator 34, which, under the influence of the cam 25, will move into the slider 35, push the pusher 28 through the roller 27 and close the shutter 30. When lowering the outside temperature Tnv, the stem 24 of the outer container 22 together with the slider 35 and the compensator 34, which moves together with the roller 27 and the pusher 28 on the cam 25 under the action of the tensioner 29 will open the shutter 30.

When the temperature of the outdoor air Tnv drops below a predetermined temperature Tk in the chamber 3, the rod 24 will be drawn into the outer container 22, and the slider 35 will cease to move, reaching the lowest position (Fig. 6).

The control of an additional cooler 12 with a cooling medium - external air can be carried out by the working unit 13 in such a way that, at the signal of the setter 14, an actuator 15 with a two-channel control unit is activated

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39 and a regulating device 16 of two dampers 30, 31 connected to each other for parallel operation, one opening the input 32 of the additional cooler 12, and the other opening the output 33 of the additional cooler 12, which ensures the natural circulation of low-temperature outside air through an additional cooler 12 and the required temperature Tk in the chamber 3, while using electricity only to shut off and (or) regulate the flow of the cooling medium circulating through the additional cooler 12, which is not mixed with camera environment 3.

At a high outdoor temperature, according to the signal from the outdoor temperature sensor 37, the two-channel control unit 39 of the contact group K2 breaks the power supply circuit of the control device 16, while the shutters 30.31 remain closed. After lowering the outdoor temperature Tnv below Tkdon, the outdoor temperature sensor 37 sends a corresponding signal to the two-channel control unit 39, which, using the contact group K2, closes the part of the power supply circuit of the regulating device 16, controlled by the outdoor temperature sensor 37. When the temperature of the air Tk in the chamber 3 rises above Tkdok from the internal temperature sensor 38, a corresponding signal is supplied to the two-channel control unit 39, which closes the contact power group of the regulating circuit K1 device 16, controlled by an internal temperature sensor 38 and supplies power to a control device 16, which in turn will open the shutters 30, 31. The cooler outside air will enter the inlet channel 32 of the additional cooler 12 and, when heated, from warmer air in the chamber 3, under the action of free convection it will rise to the output channel 33. When the air temperature Tk in the chamber 3 decreases, the internal temperature sensor 38 gives the corresponding signal and the two-channel control unit 39 will stop the electric supply Itani to the control device 16, which in turn closes the valve 30, 31 (FIG. 7).

The control of an additional cooler 12 with cooling medium - external air can be carried out by the working unit 13 in such a way that, at the signal of the setter 14, an actuator 15 with an adaptive control unit 40 and an adjusting device 16 of two shutters 30, 31 are connected to each other for parallel operation, at the same time, one opens the input 32 of the additional cooler 12, and the other - the output 33 of the additional cooler 12, which ensures the natural circulation of outdoor air at a lower temperature by additional body cooler 12 and the required temperature in the chamber 3, while using electricity only for

overlapping and (or) regulating the flow of the cooling medium circulating through the additional cooler 12, not mixing with the medium of the chamber 3.

The control is carried out in a manner similar to that described in FIG. 7. with the exception that instead of the two-channel control unit 39, the adaptive control unit 40 operates. The adaptive control unit 40 compares the temperature Tk in the chamber 3 with the temperature of the outdoor air Tnv based on signals from the sensors outside 37 and the inside 38. When the outdoor temperature Tnv is lower than the air temperature Tk in the chamber 3, the power supply circuit of the regulating device 16 is closed by the short circuit contact group and when the circuit is closed by the contact group K1. controlled in the adaptive control unit 40 from the internal temperature sensor 38, the shutters 30.31 open to allow the outdoor air to circulate through the additional cooler 12. At an outdoor temperature Tg higher than the air temperature Tk in the chamber 3, the power supply circuit of the control device 16 is opened by the short circuit contact group and the response of the control device 16, that is, the opening or closing of the shutters 30.31 will depend on the state of the other contact groups Kl, K2 of the power circuit of the control device 16 (FIG. 8).

The control of an additional cooler 12 with a cooling medium - outside air can be carried out by the working unit 13 in such a way that, from the setter 14, the signal is transmitted to an actuator 15 with a two-channel control unit 39, whose signal is used to control a regulating device 16 with a forced circulation unit 41 mounted on one from the adjustable channels 9 of the additional cooler 12, which ensures the forced circulation of the outside air of low temperature Тнв through the additional cooler 12 and the necessary the temperature Tk in the chamber 3, using electric energy to ensure forced circulation, to shut off and (or) regulate the flow of the cooling medium circulating through the additional cooler 12, which is not mixed with the medium of the chamber 3.

The control is carried out in a manner similar to that described in FIG. 7. with the exception that the two-channel control unit 39 supplies power to the control device 16 with the forced circulation unit 41 mounted on the output adjustable channel 9. Under the action of the forced circulation unit 41, cooler external air will enter the adjustable adjustable input channel 9 of the additional cooler 12 . With an increase in outdoor temperature Tnv above

Tkdon or when the air temperature Tk in the chamber 3 decreases below Tkdok, the outdoor temperature sensor 37 or the internal temperature sensor 38 supplies a corresponding signal to the control device 16, which in turn will turn off the forced circulation unit 41 (Fig. 9).

The control of an additional cooler 12 with a cooling medium - external air can be carried out by the working unit 13 in such a way that, from the setter 14, the signal is transmitted to the actuator 15 with an adaptive control unit 40, the signal of which controls the regulating device 16 with the forced circulation unit 41 installed on one of the adjustable channels 9 of the additional cooler 12, which ensures the forced circulation of external air of low temperature through the additional cooler 12 and the necessary temperature Tk in the chamber, while using electric energy to provide forced circulation, to shut off and (or) regulate the flow of the cooling medium circulating through the additional cooler 12, which does not mix with the medium of the chamber 3.

The control is carried out in a manner similar to that described in FIG. 7, 8. except that the adaptive control unit 40 supplies power to the control device 16 with the forced circulation unit 41 mounted on the output adjustable channel 9. Under the action of the forced circulation unit 41, cooler outside air will enter the adjustable adjustable input channel 9 of the additional cooler 12. With a decrease in the temperature of the water Tk in the chamber 3 below the temperature of the outdoor air Tnv, with a simultaneous increase in the temperature of the outdoor air Tnv above the temperature Tkdon and with a decrease in temperature Tc tours air in the chamber 3 below the temperature sensors Tkdok outer 37 and inner 38 is fed corresponding temperature signals to the adaptive control unit 40, which disconnects power from the control device 16 with forced circulation unit 41 (FIG. 10).

Management can be carried out without the use of electricity by the working unit 13 of an additional cooler 12 connected with a tank 42 with a liquid non-freezing cooling medium 43 installed outside the wall 2 of the building, which in turn is cooled by the air of the external environment, so that, according to the signal from the setter 14, an actuator 15 and a regulating device 16. installed on one of the adjustable channels 9 of the additional cooler 12, than

Smmitmy

provide natural circulation of liquid non-freezing cooling medium 43 of a reduced temperature through an additional cooler 12 and the required temperature in the chamber 3 (Fig. 11).

The control is carried out without using electricity by the working unit 13 of the additional cooling device 6 with an additional cooler 12 in the form of a tube 44 connected to a tank 42 with a liquid non-freezing cooling medium 43 installed outside the wall 2 of the building above the additional cooler 12 in the form of a tube 44, which in turn is cooled outdoor air. The tubular element 45 of the input adjustable channel 9 in the tank 42 should be lower than the tubular element 45 of the output adjustable channel 9, and the level of liquid non-freezing cooling medium 43 in the external tank 42 should be higher than the tubular elements 45 of the input and output adjustable channels 9. With increasing air temperature Tk in the chamber 3 above a certain temperature Tkdon, the rod 47 of the inner container 46 will open the regulating device 16. If the temperature Tnv of the liquid non-freezing cooling medium 43 in the outer container 42 is lower than the temperature spirit Tk in the chamber 3, then the liquid non-freezing cooling medium 43 due to natural convection will begin to circulate from the outer tank 42 through an adjustable channel 9 through an adjusting device 16 to an additional cooler 12 in the form of a tube 44 and then again through the output adjustable channel 9 to the outer tank 42 .When the air temperature Tk in the chamber 3 decreases to a certain value Tcdock, the stem 47 of the inner container 46 will close the control device 16 and the circulation will stop. If the temperature Тnv of the liquid antifreeze cooling medium 43 in the outer container 42 is higher than the air temperature Тk in the chamber 3, then the natural circulation of the liquid antifreeze cooling medium 43 will not occur, since the warmer liquid antifreeze cooling medium 43 will be in the outer container 42, structurally located above the level of the additional cooler 12, in which the colder liquid non-freezing cooling medium 43 will remain (Fig. 13).

The control can be carried out by the operating unit 13 of the additional cooler 12 in the form of a tube 44 connected to a tank 42 with a liquid non-freezing cooling medium 43 installed outside the wall 2 of the building, which in turn is cooled by the ambient air, so that the signal from the setter 14 is transmitted to the executive a device 15 with a limiting control unit 48, the signal of which controls a regulating device 16 mounted on one of the adjustable channels 9 of the additional cooler 12, which ensures natural circulation liquid non-freezing

low temperature cooling medium 43 through an additional cooler 12 in the form of a tube 44 and the required temperature Тk in the chamber 3, while using electric energy only to shut off and (or) regulate the flow of liquid non-freezing cooling medium 43 circulating through the additional cooler 12, which is not mixed with the chamber medium 3.

The control is carried out in a manner similar to that described in FIG. 13, except that the control device 16 is opened and closed by a signal from the limit control unit 48, which, in turn, is triggered by the internal temperature sensor 38.. When the temperature of the air in the chamber 3 rises above Ткдок, the corresponding signal arrives from the internal temperature sensor 38 to the limit control unit 48, which closes the power supply circuit of the control device 16, controlled by the internal temperature sensor 38, and supplies power to the control device 16, which in turn, it will open the adjustable channel 9. The colder liquid non-freezing cooling medium 43 will flow through the input adjustable channel 9 to the cooler 12 in the form of a tube 44 and, when heated b, from warmer air in chamber 3, it will rise under the action of free convection into the adjustable output channel 9. When the temperature Tk in the chamber 3 decreases, the internal temperature sensor 38 gives a corresponding signal and the limit control unit 48 will cut off the power supply to the control device 16. which in turn will close the adjustable channels 9 (Fig. 14).

The control can be carried out by the operating unit 13 of the additional cooler 12 in the form of a tube 44 connected to a container 42 with a liquid non-freezing cooling medium 43 installed outside the wall 2 of the building, which in turn is cooled by the air of the external environment, so that the signal from the setter 14 is transmitted to the executive a device 15 with a two-channel control unit 39, the signal of which controls a control device 16 with a forced circulation unit 50 installed on one of the adjustable channels 9 of the additional cooler 12 in the form of a tube 44, which ensures forced circulation of a low-temperature liquid non-freezing cooling medium 43 through an additional cooler 12 in the form of a tube 44 and the required temperature Тk in the chamber 3, while using electric energy to provide forced circulation, to shut off and (or) regulate the flow of circulating additional cooler 12 liquid non-freezing cooling medium 43. not mixed with the medium of the chamber 3.

The control is carried out in such a way that when the temperature of the liquid non-freezing cooling medium 43 in the outer tank 42 is higher than Tkdon, upon the signal from the outside temperature sensor 49, the two-channel control unit 39 of the contact group K2 breaks the power supply circuit of the control device 16, while the forced circulation unit 50 does not work. After lowering the temperature Tnv of the liquid anti-freezing cooling medium 43 below Tkdon, the outdoor temperature sensor 49 sends a corresponding signal to the two-channel control unit 39, which, with the contact group K2, closes the power supply circuit of the control device 16, controlled from the outdoor temperature sensor 49. When the temperature of the air in the chamber 3 rises above Ткдок from the internal temperature sensor 38, the corresponding signal enters the two-channel control unit 39, which closes part of the electric circuit with the contact group K1 the throttling of the control device 16, controlled from the internal temperature sensor 38 and supplies power to the control device 16 with the forced circulation unit 50. The colder liquid non-freezing cooling medium 43 will circulate under the action of the forced circulation unit 50 through the adjustable input channel 9, via an additional 12 V cooler in the form of a tube 44, via an adjustable output channel 9. When the air temperature Tk in the chamber 3 decreases to Tcdoc and lower, the internal temperature sensor 38 gives a corresponding signal and vuhkanalny control unit 39 stops supplying power to the control device 16 with forced circulation unit 50 and the liquid circulation of unfrozen cooling fluid 43 ceases (Fig. fifteen).

The control can be carried out by the operating unit 13 of the additional cooler 12 in the form of a tube 44 connected to the outer tank 42 with a liquid non-freezing cooling medium 43 installed outside the wall 2 of the building, which in turn is cooled by the ambient air, so that the signal from the setter 14 is transmitted to an actuator 15 with an adaptive control unit 40, the signal of which controls the regulating device 16 with a forced circulation unit 50 installed on one of the adjustable channels 9 additional cooling sprinkling 12 in the form of a tube 44, which ensures the forced circulation of a low-temperature liquid non-freezing cooling medium 43 through an additional cooler in the form of a tube 44 and the required temperature Тk in the chamber 3, while using electric energy to provide forced circulation, to shut off and (or) regulate the flow circulating

by an additional cooler 12 in the form of a tube 44 of a liquid non-freezing cooling medium 43 that does not mix with the medium of the chamber 3.

The control is carried out in a manner similar to that described in FIG. 15, except that the actuator 15 with the adaptive control unit 40 compares the readings in the setter 14 of the two outdoor temperature sensors 49 and the internal 38, while if the temperature Тnv of the liquid non-freezing cooling medium 43 in the external tank 42 is higher than the air temperature Тk in the chamber 3 contact group KZ in the adaptive control unit 40 opens part of the power circuit of the regulating device 16 and the actuation of the regulating device 16, that is, turning on or off the forced circulation unit 50 t depends on the state of other contact groups K1 and K2 of the power supply circuit of the regulating device 16. If the temperature Тнv of the liquid non-freezing cooling medium 43 in the outer tank 42 is lower than the air temperature Тk in the chamber 3, the contact group КЗ in the adaptive control unit 40 closes a part of the power circuit of the regulating device 16с the forced circulation unit 50 and the actuation of the control device 16, that is, turning on or off the forced circulation unit 50 will depend on the state of the contact group K1 (FIG. 16).

For all figures, the two-channel control unit 39 is designed to control the regulating device 16 and operates as follows. The control device 16 is triggered (opens the shutters 30, 31 or adjustable channels 9 or turns on the forced circulation unit 41 or 50) at a time when a certain voltage is applied to it, i.e. contact groups K1 and K2 are closed. The dampers 30, 31 or adjustable channels 9 are closed, and the forced circulation unit 41 or 50 is turned off if voltage is not supplied to the control device 16, i.e., at least one of the contact groups (K1 or K2) has opened the circuit. The comparing element C2, controlling the contact group K2, sets a certain upper temperature value Tkdon. The signal from the external temperature sensor 37 or 49, which detects the temperature Тнв of the outdoor air or liquid non-freezing cooling medium 43, enters the two-channel control unit 39 to the comparing element C2, where it is compared with the upper temperature Ткдон. If the temperature Тнв of outdoor air or liquid non-freezing cooling medium 43 drops below the upper temperature Ткдон, then the electric circuit in the contact group K2 closes and the voltage reaches the contact group K1. If the temperature Tnv of outdoor air or liquid

non-freezing cooling medium 43 increases to the upper temperature Tkdon or higher, then the electric circuit in the contact group K2 opens.

The comparing element C1 set a certain lower value of the air temperature Tkdok. The signal from the internal temperature sensor 38 fixing the temperature Tk in the chamber 3, enters the two-channel control unit 39 to the comparison element C1, where it is compared with the lower temperature Tkdok. At a time when the temperature Tk in the chamber 3 rises to values exceeding the lower value of the air temperature Tkdok, the electric circuit in the contact group K1 closes and the voltage is supplied to the control device 16. If the air temperature Tk in the chamber 3 falls below the lower air temperature Tkdok, then the electric circuit in the contact group K1 opens (Fig. 17).

For all figures, the adaptive control unit 40 is designed to control the regulating device 16 and operates as follows. The control device 16 is triggered (opens the shutters 30, 31 or adjustable channels 9 or turns on the forced circulation unit 41 or 50) at a time when a certain voltage is applied to it, i.e. contact groups K2 or KZ, as well as contact group K1 are closed. The dampers 30, 31 or adjustable channels 9 are closed, and the forced circulation unit 41 or 50 is turned off if voltage is not supplied to the control device 16, i.e. in the contact groups K2 and KZ at the same time or in the contact group K1 the circuit has opened. The comparing element C2 sets a certain upper value of the air temperature Tkdon. The signal from the external temperature sensor 37, 49, which detects the temperature Тнв of the outdoor air or liquid non-freezing cooling medium 43, is supplied to the adaptive control unit 40 to the comparing element C2, where it is compared with the upper air temperature Ткдон and to the comparing element СЗ. If the temperature Тнв of outdoor air or liquid non-freezing cooling medium 43 falls below the upper value of the air temperature Ткдон, then the electric circuit in the contact group K2 closes and the voltage reaches the contact group K1. If the temperature Тнв of the outdoor air or liquid non-freezing cooling medium 43 rises to the upper air temperature Ткдон or higher, then the electric circuit in the contact group K2 opens.

Comparing element C1 set a certain lower value of the air temperature Tkdok. The signal from the internal temperature sensor 38, which fixes the air temperature Tk in the chamber 3, enters the adaptive control unit 40 to the contact group C1,

where it is compared with the lower value of the air temperature Tkdok and the contact group SZ. At a time when the air temperature Tk in chamber 3 rises to values exceeding the lower value of the air temperature Tkdok, the electric circuit in contact group K1 closes and the voltage is supplied to the regulating device 16. If the air temperature Tk in chamber 3 falls below the lower air temperature Tkdok , then the electric circuit in the contact group K1 opens.

In the comparing element C3, the signals from the external temperature sensor 37.49 fixing the temperature Tv of the outdoor air or liquid non-freezing medium 43 are compared and from the internal temperature sensor 38 fixing the temperature Tk in the chamber 3. If the air temperature Tk in the chamber 3 rises to values exceeding the temperature Тnv of external air or liquid non-freezing cooling medium 43, the electric circuit in the contact group KZ is closed and the voltage reaches the contact group K1. If the temperature Tk in the chamber 3 drops to values below the temperature Tnv of the outdoor air or liquid non-freezing cooling medium 43, then the electric circuit in the contact group KZ opens.

Limit control unit 48 is designed to control the regulating device 16 and operates as follows. The regulating device 16 is triggered (opens the adjustable channels 9) at a time when a certain electric voltage is supplied to it, i.e. contact group K1 is closed. The adjustable channels 9 are closed if voltage is not supplied to the control device 16, i.e., the contact group K1 has opened the circuit. The comparing element C1, which controls the contact group K1, sets a certain lower temperature value Ткдок .. The signal from the internal temperature sensor 38, which fixes the air temperature Тк in chamber 3, enters the limit control unit 48 to the comparing element С1, where it is compared with the lower temperature Ткдок . At a time when the air temperature Tk in the chamber 3 rises to values exceeding Tkdok. the electric circuit in the contact group K1 closes and the voltage is supplied to the control device 16. If the air temperature Tk in the chamber 3 drops below Tcdoc, then the electric circuit in the contact group K1 opens.

The inventive Refrigerator, in comparison with the prototype, increase the refrigeration capacity of the refrigerator while reducing energy consumption, due to the fact that, both for the first and second options

of the refrigerator, an additional cooler is located in the refrigerator chamber along with the main cooling element, it cools itself and cools the chamber when an adjustable convective (without the use of electricity) or forced (using a small amount of electricity) additional cooling medium flows through it.

The inventive Refrigerator, in comparison with the prototype, increase the overall service life of the refrigerator, due to the fact that, for both the first and second options, the working unit, which is part of an additional cooling device, including a control unit, an actuator and an adjusting device, it is structurally made and so controls the operation of the additional cooler that at a certain outdoor temperature, only the additional cooler works in the chamber, the main one rests.

The inventive Refrigerator, in comparison with the prototype, increase the useful area of the rooms in which the refrigerator is used, as well as expand the possibility of applying new design solutions through the use of a refrigerator built into the outer wall.

Thus, the combination of the claimed features can significantly reduce the average annual energy consumption, improve the operational capabilities of the refrigerator, increase the overall life of the refrigerator and increase the useful area of the premises.

Authorsf Z is Kiselev A.V.

& UuЈ- Porsev A.M.

Konoplev V.A.

Claims (18)

1. A refrigerator containing a lockable thermally insulated chamber, a cooling device with a cooler, an additional cooling device with an additional cooler and with adjustable channels passing through the wall of the thermally insulated chamber, for circulating a medium cooled by outside air, characterized in that it is equipped with a sensor - relay-regulator temperature, an additional cooling device is made with a working unit, including a setter, an actuator and a regulating device, an additional hladitel placed in thermally insulated chamber to directly cool the products present in it, adjustable channels are sealed and the inlet and outlet of the aftercooler, communicating directly with the outside air circulating in the cavity and overlapping the additional coolant regulating device by means of an apparatus of the set point signal. 2. The refrigerator according to claim 1, characterized in that it is installed in the wall of the building at the boundary between the external environment and the room so that part of the outer surface of the thermally insulated chamber is in contact with the room air, and part with the outside air. 3. The refrigerator according to claim 1, characterized in that the additional cooler is made in the form of a special membrane of heat-conducting material, which seals hermetically, as a partition, the thermally insulated chamber into two parts - the cavity of the refrigerating chamber with a cooler and the cavity of the additional cooler for circulating outside air in it . 4. The refrigerator according to claim 1, characterized in that the additional cooler is made in the form of a tubular cavity of heat-conducting materials for circulating outside air. 5. The refrigerator according to claim 3, characterized in that the tubular cavity of the heat-conducting materials is combined with the cooler of the cooling device. 6. The refrigerator according to claim 1, characterized in that the working unit comprises a setter consisting of internal and external containers with non-freezing liquid, an actuator consisting of a rod of an internal container, a rod of an external container, a cam of an internal container, a cam of an external container, a roller, a pusher, a tensioner, a regulating device consisting of two shutters connected to each other for parallel operation, one of which opens and closes the inlet of the additional cooler, and the other opens and closes its outlet. 7. The refrigerator according to claim 1, characterized in that the operating unit comprises a setter consisting of internal and external containers with non-freezing liquid, an actuator consisting of a rod of an internal container, a rod of an external container, a compensator with a slider, a cam of the internal container, a roller, compensator roller, pusher, tensioner, adjusting device, consisting of two dampers connected to each other for parallel operation, one of which opens and closes the inlet of the additional cooler, and the other opens and closes is his way out. 8. The refrigerator according to claim 1, characterized in that the operating unit comprises a setter consisting of two temperature sensors for external and internal, an actuator with a two-channel control unit, a control device consisting of two shutters, one of which opens and closes the input of the additional cooler , and the other opens and closes its exit. 9. The refrigerator according to claim 1, characterized in that the operating unit comprises a setter consisting of two temperature sensors for external and internal, an actuator with an adaptive control unit, a control device consisting of two dampers, one of which opens and closes the input of the additional cooler , and the other opens and closes its exit. 10. The refrigerator according to claim 1, characterized in that the operating unit comprises a setter consisting of two temperature sensors for external and internal, an actuator with a two-channel control unit, a control device consisting of a forced circulation unit installed on one of the adjustable channels of the additional cooler . 11. The refrigerator according to claim 1, characterized in that the operating unit comprises a setter consisting of two temperature sensors for external and internal, an actuator consisting of an adaptive control unit, a control device consisting of a forced circulation unit installed on one of the adjustable channels additional cooler. 12. A refrigerator containing a lockable thermally insulated chamber, a cooling device with a cooler, an additional cooling device with an additional cooler and with adjustable channels made in the wall of the thermally insulated chamber, for circulating a medium cooled by outside air, characterized in that it is equipped with a sensor - relay-regulator temperature, an additional cooling device is made with a working unit including a setter, an actuator and a regulating device with a liquid tank non-freezing cooling medium installed outside the building and, in turn, cooled by external air, with an additional cooler placed in a thermally insulated chamber for direct cooling of products located in it, made in the form of a tube of heat-conducting materials associated with the formation of a closed system with a liquid tank non-freezing cooling medium, not less than two tubular elements acting as adjustable channels for the circulation of liquid non-freezing cooling medium, sealed by the inlet and outlet of an additional cooler and overlapping by a regulating device using an actuator at the signal of the setter. 13. The refrigerator according to claim 12, characterized in that it is installed in the wall of the building at the boundary between the external environment and the room so that part of the outer surface of the thermally insulated chamber is in contact with the room air, and part with the outside air. 14. The refrigerator according to claim 12, characterized in that the tube of heat-conducting materials is combined with the cooler of the cooling device. 15. The refrigerator according to claim 12, characterized in that the operating unit comprises a setter consisting of an internal container with non-freezing liquid, an actuator with a rod of the internal container, a control device mounted on one of the adjustable channels. 16. The refrigerator according to claim 12, characterized in that the operating unit comprises a setter consisting of an internal temperature sensor, an actuator with a limit control unit, a control device mounted on one of the adjustable channels. 17. The refrigerator according to claim 12, characterized in that the operating unit comprises a setter consisting of two outdoor and indoor temperature sensors, an actuator with a two-channel control unit, a control device with a forced circulation unit, mounted on one of the adjustable channels. 18. The refrigerator according to claim 12, characterized in that the operating unit comprises a setter consisting of two temperature sensors for external and internal, an actuator with an adaptive control unit, a regulating device with a forced circulation unit mounted on one of the adjustable channels.