SU1372159A1 - Air conditioner with adjustable cold-making capacity - Google Patents

Abstract

The invention extends the range of control of the cold performance of an air conditioner. A hermetic partition (GP) 8, installed with the possibility of longitudinal movement, separates the heat exchanger 1 into cavities (P) 9 and 10 of low and high pressure. The capillary tube (QD) 4 is wound on the heat exchanger along its length and is connected to the inlet 3 of the evaporator and through P 10 to the outlet 2 of the condenser. The output 6 of the evaporator communicates with the compressor through P 9. The air conditioner is equipped with restrictive stops 11 and 12, which exclude the possibility of overlapping the GP 8 of the inlets and outlets 7 and 2.6 of the condenser and the evaporator. Compensation element, which m. made in the form of a spring 13, equipped with a regulating screw, is located in P 9 and interacts with the HP 8. When the heat load on the air conditioner changes, pressure in P 9 and 10 changes, resulting in a corresponding displacement of the HP 8 and changing the surface of the contact P 9 and 10 with the middle part 5 CT 4, with the heat supply to CT 4 changing to a lesser or greater degree, which leads to a corresponding change in the flow rate of the circulating refrigerant and the cooling capacity of the air conditioner. 4 hp f-ly, 5 ill. (L with vj you ate with

Description

The invention relates to a technique of ventilation and air conditioning.

The aim of the invention is to expand the range of regulation of cold performance.

FIG. 1 is a schematic diagram of a heat exchanger with an air conditioner capillary tube; in FIG. 2, node I in FIG. one; in fig. 3 - node II in FIG. one; in fig. 4 — node III in FIG. one; in fig. 5 - heat exchanger and capillary tube, having a heat insulating coating.

The variable-capacity air conditioner contains an evaporator — and a condenser for a vapor compression refrigeration machine (not shown), a heat exchanger 1 and a condenser 4 connected to the outlet 2 and to the evaporator inlet 3 a capillary tube 4 that contacts its middle part 5 with the heat exchanger 1, and the output 6, the evaporator is communicated via a compressor (not shown) to the inlet 7 of the condenser.

The heat exchanger 1 is provided with a hermetic septum 8 installed with the possibility of longitudinal movement and separating the heat exchanger 1 to the low and high pressure cavities 9 and 10, restrictive stops 1 and 12 and a compensation element made, for example, in the form of a spring 13 with an adjusting screw 14.

The capillary tube 4 is connected to the outflow 2 of the condenser through the high-pressure cavity 10 and wound onto the heat exchanger 1 along its length.

The evaporator outlet 6 communicates with the compressor through the low pressure cavity 9, and the spring 13 is located in the latter and interacts with the movable partition 8.

The heat exchanger 1 can be provided with a spiral groove 15, and the capillary tube 4 is located in the latter.

The movable partition 8 on the side of the low pressure cavity 9 can be made with a developed heat exchange surface 16.

The heat exchanger 1 and the capillary tube 4 can be equipped with a heat insulating coating 17.

The variable-capacity air conditioner operates as follows.

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In the high-pressure cavity 10 of the heat exchanger 1, a liquid refrigerant is supplied through the outlet 2 of the condenser, which is discharged from the condenser of the cooling tank and which enters the capillary tube 4.

In the low pressure cavity 9, through the outlet 6 of the evaporator is supplied, and through the inlet 7 of the condenser, through the compressor, vaporized refrigerant removed from the evaporator of the air conditioning chiller is removed.

Making the movable partition 8 sealed eliminates the possibility of refrigerant spills between cavities 9 and 10.

A compensation element made, for example, in the form of a spring 13 serves to compensate for the difference between the high condensing pressure in the cavity 10 and the low evaporation pressure in the cavity 9.

Restrictive stops 11 and 12 exclude the possibility of blocking the movable partition 8 of the inlets and outlets 2.6 and 7 of the condenser and the evaporator.

When the heat load on the air conditioner changes, the pressure in the cavities 9 and 10 changes, resulting in a corresponding movement of the movable partition 8 and a change in the contact surface of the cavities 9 and 10 with the middle part 5 of the capillary tube 4, and supplying heat to the capillary tube 4 changes to a lesser or greater degree, resulting in a corresponding change in the flow rate of the circulating refrigerant and the cooling capacity of the air conditioner.

For example, when the evaporator load decreases (the air inlet temperature decreases), the temperature and evaporation pressure of the refrigerant also decrease, causing pressure in the low-pressure cavity 9 and moving the movable partition 8 to the side.

As a result of the increase in the volume of the high-pressure cavity 10, more heat is supplied to the capillary tube 4 from the side of the refrigerant in the cavity 10, which leads to a decrease in the density of the vapor-liquid mixture flowing in the capillary tube 4, to a decrease in radar flow and coolant performance and air conditioning I of the air conditioner .

In addition, when the load on the condenser of the refrigerating machine increases (when the air temperature increases at the inlet to the condenser), the condensation pressure increases, the volume of the high-pressure cavity 10 increases and the flow rate of the refrigerant through the capillary tube 4 decreases as the heat exchange between the high-pressure cavity 10 changes pressure with refrigerant and capillary tube 4.

A decrease in the refrigerant flow, in turn, leads to a decrease in the condensation pressure and to ensure the safe operation of the air conditioner at elevated temperatures of the cooling air condenser.

Claims (3)

1. A variable-capacity air conditioner containing an evaporator and a condenser of a vapor compression refrigeration machine, a heat exchanger and a capillary tube connected to the condenser outlet and the evaporator inlet, in contact with the heat exchanger, the evaporator output communicating through the compressor to the condenser inlet that is visible five about five d In order to expand the range of regulation, the heat exchanger is equipped with a hermetic partition, installed with the possibility of longitudinal movement and separating the heat exchanger in the low and high pressure cavities, restrictive stops and compensating element, the capillary tube is connected to the outlet of the condenser through the high pressure cavity is wound to the heat exchanger along its length, the evaporator outlet communicates with the compressor through the low pressure cavity, and the compensation element is located in the latter and interconnects Procedure with movable partition. 2. An air conditioner according to claim 1, characterized in that the heat exchanger is provided with a spiral groove and a capillary tube is located in the latter. 3. An air conditioner according to claim 1, characterized in that the partition on the side of the low pressure cavity is made with a developed heat exchange surface. A. An air conditioner according to claim 1, characterized in that the compensation element is in the form of a spring equipped with a control screw. 5, an air conditioner according to claim 1, characterized in that the heat exchanger and the capillary tube are provided with a heat insulating coating. FIG. and  I. I  /four FIG. five