RU2044966C1 - Refrigerating unit - Google Patents

Abstract

FIELD: refrigerating engineering. SUBSTANCE: refrigerating unit has absorber 1, generator 2, condenser 3, evaporator 4 and connecting pipelines. Unit has also additional refrigerating circuit with generator 6, condenser 7 and evaporator 8 connected in parallel with main refrigerating circuit. Novelty in design of refrigerating unit is provision of additional refrigerating circuit and connection of the latter in parallel with main circuit which provides their independent operation. EFFECT: enlarged operating capabilities. 2 cl, 3 dwg

Description

 The invention relates to refrigeration, and more particularly to a device for absorption refrigeration units intended for use in domestic refrigerators or freezers.

 A device for absorption cooling with two refrigeration circuits is known, comprising a generator, a condenser, an evaporator and an absorber in each circuit, while the second refrigeration circuit generator operates by heat exchange with the absorber and condenser of the first refrigeration circuit. This device is designed for air conditioning in a building. The refrigerant circuits of the device are structurally connected to each other, and therefore do not have autonomy in operation. The cooling capacity of the device is determined by the power of the generator of the first refrigeration circuit.

 Known refrigeration unit of the refrigerator "Crystal-9M", consisting of an absorber, generator, condenser, evaporator and pipelines connecting them. In this unit, the generator has a heater with two power levels, the switching of which is carried out by a thermostat depending on the temperature in the refrigerator. The minimum cooling capacity of this unit is limited by the maximum power of the heater.

 The purpose of the invention is to further increase the cooling capacity of the unit.

 The goal is achieved by the fact that in the known refrigeration unit, consisting of an absorber, generator, condenser, evaporator and pipelines connecting them, an additional refrigeration circuit is established, consisting of a generator, condenser and evaporator, connected in parallel with the main refrigeration circuit. Both refrigeration circuits get autonomy in operation and the total cooling capacity of the unit is composed of the cooling capacity of the evaporators of each circuit.

 Placing an additional refrigeration circuit in the dimensions of a known refrigeration unit imposes stringent requirements for its arrangement. In order to increase compactness, the evaporators of the refrigeration circuits are placed in two planes, while the evaporator of the additional refrigeration circuit is made by mirror reflection of the evaporator of the main refrigeration circuit.

 In FIG. 1 shows a general diagram of a refrigeration unit; in FIG. 2 general view of the unit from the side of the rear wall of the refrigerator; in FIG. 3 arrangement of evaporators in the low-temperature compartment of the refrigerator.

 The refrigeration unit (Fig. 1) consists of an absorber 1, in the lower part of which at the same time a collector of a water-ammonia solution, a generator 2, a condenser 3, an evaporator 4 with a heat exchanger 5, and also pipelines connecting them are located.

 The composition of the additional refrigeration circuit includes a generator 6, a condenser 7 and an evaporator 8 with a heat exchanger 9.

 Generators 2 and 6 and heat exchangers 5 and 9 have a common connection with the absorber 1. Both generators are located on the rear wall of the refrigerator and are insulated under a common casing 10 (Fig. 2).

 Evaporators of the main 4 and additional 8 refrigeration circuits are introduced into the low-temperature compartment through a cutout in the rear wall of the refrigerator and at the outlet from it are insulated as a single unit 11 (Fig. 3). The surfaces of the evaporators located in the low-temperature compartment have additionally developed ribbed surfaces 12 and 13, while the pipes of the evaporators of both circuits, passing along the rear wall of the refrigerator, are united by a common plate 14 and a ribbed surface 15.

Evaporators of refrigeration circuits are placed in two planes: in the low-temperature compartment (Fig. 3) this is a plane inclined to the horizon plane by 2-3 ^° to ensure the discharge of ammonia, in the area where evaporators 4 and 8 go into heat exchangers 5 and 9 (Fig. 3). 2) the vertical plane. The evaporator 8 with the heat exchanger 9 of the additional circuit is made in the form of a mirror image of the evaporator 4 with the heat exchanger 5 of the main circuit and is located with some displacement under the main circuit, which ensures a tight arrangement of the evaporators without crossing pipelines.

 Each of the refrigeration circuits works according to the same scheme.

 The main refrigeration circuit (Fig. 1) works as follows.

 When you turn on the main refrigeration circuit, the ammonia-water solution in the generator 2 is heated to a boil. The resulting ammonia water enters the condenser 3, where the ammonia vapor condenses, and the liquid ammonia enters the evaporator 4. The ammonia pressure in the evaporator is lower than in the condenser, and the liquid ammonia entering the evaporator evaporates, cooling the corresponding compartment or chamber of the refrigerator.

 During evaporation, ammonia diffuses into hydrogen, which is also supplied to the evaporator from the absorber 1 through pipeline 16. The resulting vapor-gas mixture of hydrogen and ammonia, together with the residues of non-vaporized liquid ammonia, passes through the vapor-gas heat exchanger 5 and through pipeline 17 it enters the solution collector, from where it rises up the absorber where ammonia vapors from the gas-vapor mixture are absorbed by a weak aqueous ammonia solution entering the absorber from the generator 2 through line 18. Purified hydrogen vapor from ammonia comes from abs the orber through line 16 again to the evaporator 4. The process is repeated.

 In the same way, an additional refrigeration circuit works when the generator 6 is turned on.

 The effectiveness of the proposed refrigeration unit is determined by the following advantages.

 A refrigeration unit having two refrigeration circuits connected in parallel provides greater cooling capacity and, accordingly, can create lower temperatures in refrigerated chambers or allow a larger freezer volume.

The refrigeration unit, having two refrigeration circuits connected in parallel, provides the possibility of operating in the operating mode of only the main refrigeration circuit; in the operation mode of only the additional refrigeration circuits, in the simultaneous operation of both refrigeration circuits, which creates additional opportunities for expanding its functional tasks. These may include, for example, the following:
when installing both evaporators in one chamber, the inclusion of an additional circuit for quick cooling the chamber;
the use of each refrigeration circuit to cool individual chambers.

Claims (2)

 1. REFRIGERATING UNIT, consisting of an absorber, generator, condenser, evaporator and pipelines connecting them, characterized in that the unit has an additional refrigeration circuit consisting of a generator, condenser and evaporator, connected in parallel with the main refrigeration circuit.  2. The unit according to claim 1, characterized in that the evaporators of the refrigeration circuits are arranged in two planes, while the evaporator of the additional refrigeration circuit is made by mirror reflection of the evaporator of the main refrigeration circuit.

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