RU2244853C2 - Method of and device for cooling of compressor - Google Patents

Abstract

FIELD: mechanical engineering; compressor building.

SUBSTANCE: invention relates to evaporation cooling system of spiral compressors. According to proposed method, compression heat is removed from working zone of compressor by evaporating cooling heat carrier which is then condensed and directed for cooling, if required temperature of compressor working zone is exceeded, heat carrier boiling temperature is changed and maintained at level lower than required cooling temperature of compressor units by changing pressure in compressor cooling system. Proposed compressor contains housing, compression circuit, closed evaporation cooling system including outer jacket enclosing compressor housing, collector-condenser arranged higher than cooled surfaces and communicating through channels with heat carrier input in jacket and output and with device to decrease pressure.

EFFECT: improved cooling of compressor and efficiency.

8 cl, 1 dwg

Description

The invention relates to the field of compressor engineering, and in particular to evaporative cooling systems, for example, scroll compressors.

A known method of cooling the compressor by removing heat from the working area of the compressor (SU 414430 A, 07.15.1974, F 04 B 39/06), in which the heat of compression is removed by evaporation of the refrigerant from an absorption diffusion machine heated in a generator by gas compressed in a compressor. The gas compressed in the compressor enters the discharge pipe. While cooling, the gas heats the refrigerant of the absorption diffusion machine in the generator, evaporating in the evaporator, the refrigerant removes the heat of compression from the compressor working area.

At present, the compressor is cooled by either flowing liquid (water, oil) or air as forced cooling by free convection of air.

A known device for cooling a sealed compressor (SU 533750 A, 10/30/1976, F 04 B 39/06) containing an evaporator filled with a working fluid and placed in the compressor oil bath, the evaporator and condenser is made in the form of a closed loop-shaped tube.

Known scroll compressor (US 5217360 A, F 04 C 29/04, 06/08/1993), which implements a method of cooling the compressor in a closed system, including the removal of compression heat from the compressor working area by supplying coolant to the compressor working area, cooling the coolant and direction of the cooled coolant back to cooling. The twisted part of the spiral impeller blade is designed so that the pressure between the suction side and the discharge side affects part of its rear surface. The compressor includes a device for adjustment and cooling.

The device allows guaranteed supply of the required amount of oil to reduce friction and, as a result, to reduce the amount of heat released in the compressor working area and to cool it. However, it does not solve the problem of heat transfer enhancement during cooling. The issue of intensification of the cooling process and increase of efficiency remains relevant for compressor technology, for example, for scroll compressors.

A known compressor and a cooling method implemented therein (SU 985417A, 12/30/1982, F 04 B 39/06), closest in technical essence to the claimed one and adopted as a prototype, in which the compressor comprises a cylinder with suction and discharge valves and installed in it with the formation of a compression chamber, a piston having an internal cavity communicated with a gap between the piston and the cylinder by means of throttle nozzles, and provided with a casing forming a cooling cavity with the piston and having a check valve on the side of the compression chamber. The walls of the piston and the casing, limiting the cooling cavity, are provided with annular grooves, axially displaced relative to one another and having a V-shape in longitudinal section, and the cooling cavity is partially filled with liquid, and the casing in the check valve area is equipped with a pipe in communication with internal cavity. In this device, evaporation and condensation occurs in the same place, therefore, during evaporation, heat is removed, and during condensation it is released again. Boiling coolant occurs at the same temperature and does not depend on the parameters and compressor operation, which may vary. This does not allow efficient cooling of the compressor.

The known method of cooling and devices for its implementation do not provide effective cooling of the compressor, which leads to overheating of the nodes and, therefore, to reduce the efficiency compressor.

The technical result to which the invention is directed is to increase the cooling efficiency of the compressor and increase its efficiency.

The technical result is achieved in a method of cooling a compressor in a closed cooling system, including the removal of compression heat from the compressor working zone by evaporating the cooling medium, condensation and the direction of the condensed medium again to cool, when the required temperature of the compressor working zone is exceeded, the boiling temperature of the medium is changed and it is kept below the required cooling temperatures of compressor units by changing the pressure in the compressor cooling system.

In addition, the condensation of the coolant is carried out outside the working area of the compressor and above it.

In addition, the boiling point of the coolant is kept below the required cooling temperature of the compressor units by 10-15K.

In addition, the movement of the liquid phase of the cooling fluid and its vapors in a closed cooling system is carried out by natural circulation.

The technical result is also achieved in a compressor containing a housing, a compression circuit, a closed evaporative cooling system, while the closed evaporative cooling system includes an outer jacket covering the compressor housing, a collector-condenser located above the cooled surfaces and communicated by channels with the coolant inlet and outlet from it, as well as with a device that reduces the pressure.

In addition, the cooling system includes a heat exchanger for condensing the vapor phase of the cooling fluid.

In addition, the collector-capacitor is made in the form of a torus, covering the compressor housing.

In addition, the collector-condenser is in communication with a pressure reducing device, for example, with a compressor system having a pressure below atmospheric.

The drawing shows a longitudinal section of the cooled part of the compressor and its cooling system.

In the method of cooling the compressor, including the removal of compression heat from the working area of the compressor by evaporating the cooling fluid and condensing it in a closed cooling system to maintain a given temperature of the working surface when changing, for example, operating parameters or environmental conditions, the boiling point of the coolant is changed, keeping it lower the required cooling temperature of the compressor units by 10-15K by changing the pressure in the compressor cooling system, while the condensation of the vapor phase was estvlyayut compressor outside the working zone above it, i.e. the movement of the coolant and its vapors in a closed cooling system is carried out by natural circulation.

The compressor includes a housing 1, a compression circuit 2, a closed evaporative cooling system, which includes an outer jacket 3, covering the housing 1, a collector-condenser 4 located above the cooled surfaces and communicated by channels 6 and 7, respectively, with the coolant entering the jacket 3 and leaving her. The cooling system contains an additional heat exchanger 8 for condensation of the vapor phase of the cooling fluid. The collector-capacitor 4 is made in the form of a torus covering the compressor housing 1 and is in communication with a pressure reducing device, for example, with a compressor system where the pressure is below atmospheric (not shown).

The compressor cooling system operates as follows. The cooling system is filled, for example, with a boiling liquid (oil, alcohol solutions, etc.), the boiling point of which is 10-15K lower than the required cooling temperature (operating temperature) of the compressor units. When boiling, the maximum heat transfer coefficient is observed, which significantly intensifies heat transfer. The boiling process is isothermal and thus the ambient temperature does not affect compressor cooling. The vapor-liquid mixture from the jacket 3 rises along the channel 7 into the collector-condenser 4, made in the form of a torus, covering the compressor housing located above its working area. In the collector-condenser 4, the coolant is separated into liquid and vapor (gas) phases. Here, the vapor phase condenses. If the entire vapor phase cannot be condensed in the collector-condenser 4, then it enters the additional heat exchanger 8, in which it is completely condensed. Condensed liquid is supplied through channel 6 due to natural circulation to the cooled compressor units. To reduce the boiling point and, consequently, the condensation temperature, the collector-condenser 4 is connected to a pressure reducing device. The device designed to lower the pressure can be the same compressor, if the collector-condenser 4 is connected through a piping system with shut-off or control valves to its suction pipe, where the pressure is below atmospheric, or if the collector-condenser 4 is also through a piping system with a shut-off or control valves to connect to the section of the air (gas) path of the compressor, where the speed of movement of the compressible gas is maximum. For example, by reducing the flow rate of gas sucked into the compressor by means of control valves located on the suction pipe, it is possible to reduce the gas pressure in the duct section between the compressor and control valves, where the collector-condenser 4 is connected. When the pressure in the cooling system decreases, the boiling point of the liquid used in as a coolant cooling the compressor, while maintaining high heat transfer intensity. A decrease in the boiling point leads to an increase in the temperature difference between the cooled parts of the compressor and the boiling coolant. The change in pressure is carried out by changing the gas flow rate in the compressor suction pipe using shutoff or control valves.

Thus, changing the boiling point of the coolant and keeping it below the required cooling temperature of the compressor units by changing the pressure in the cooling system allows to increase the cooling efficiency of the compressor and, consequently, its efficiency, while increasing the efficiency and reliability of the compressor.

 The heat generated during condensation in the collector-condenser 4 can be used to heat water in hot water systems, such as field hospitals, or for heating rooms in which a compressor is installed.

Claims (8)

1. A method of cooling a compressor in a closed cooling system, including the removal of compression heat from the compressor working zone by evaporation of the cooling medium, condensation and direction of the condensed medium again for cooling, characterized in that when the required temperature of the compressor working zone is exceeded, the boiling point of the medium is changed and maintained below the required cooling temperature of the compressor units by changing the pressure in the compressor cooling system. 2. The compressor cooling method according to claim 1, characterized in that the condensation of the cooling coolant is carried out outside the compressor working area and above it. 3. The method of cooling the compressor according to claim 1 or 2, characterized in that the boiling point of the coolant is kept below the required cooling temperature of the compressor units by 10-15 K. 4. The method of cooling the compressor according to claim 1 or 2, or 3, characterized in that the movement of the liquid phase of the cooling fluid and its vapor in a closed cooling system is carried out by natural circulation. 5. A compressor comprising a housing, a compression circuit, a closed evaporative cooling system, characterized in that the closed evaporative cooling system includes an outer jacket covering the compressor housing, a collector-condenser located above the cooled surfaces and communicated by channels with the coolant inlet and outlet from the jacket her, as well as with a device that reduces the pressure. 6. The compressor according to claim 5, characterized in that the cooling system comprises a heat exchanger for condensing the vapor phase of the cooling medium. 7. The compressor according to claim 5 or 6, characterized in that the collector-capacitor is made in the form of a torus, covering the compressor housing. 8. The compressor according to claim 5, characterized in that the collector-capacitor is in communication with a pressure-reducing device, for example, with a compressor system having a pressure below atmospheric.