CS207321B2 - Compressor set - Google Patents

Abstract

1434927 Refrigeration SVENSKA ROTOR MASKINER AB 24 April 1973 [27 April 1972] 19655/72 Heading F4H A refrigeration plant including a condenser 14 and an evaporator 16 is provided with independent low-pressure and high-pressure meshing-screw compressors 10A, 10B driven by electric motors 26 through a step-up gear 28 and directly, respectively. Oil from a separator 12 and cooler 18 is fed by a pump 20 to the compressors, the quantity supplied to the compressor 10A being restricted to be sufficient only for lubrication. The compressor 10B is of the oil-flooded type in which the oil additionally serves to cool the refrigerant during its compression. To cool gaseous refrigerant compressed by the compressor 10A, liquid refrigerant is supplied to the compressor through a conduit 34 from the condenser 14.

Description

BACKGROUND OF THE INVENTION The present invention relates to a compressor package, particularly used in refrigeration systems comprising a condenser, an evaporator, and a compressor package comprising a first low pressure compressor and a second high pressure compressor.

In large refrigeration systems such as those used for freezers, the refrigerant can be compressed from 0.1 MPa absolute pressure. It has already been recognized and known in the early days of the development of such devices that in order to achieve satisfactory efficiency it is necessary to perform this compression in two stages. It has also been found that it has been sufficient to use as a first stage a compressor having a relatively low compression ratio, for example: 1, thus reducing the volume supplied to the second stage compressor to substantially one third of the evaporator leaving gas volume, · Second stage compressor or main compressor. Both compressors can be of the same or different types.

In recent years, screw compressors have been increasingly used in the refrigeration field because of the fact that, due to their size, screw compressors are able to process large volumes of gas at high compression ratios. In the design of high-performance compressors, these compressors are provided with a device for injecting relatively large amounts of oil into the process chamber for cooling, sealing and lubrication.

Large amounts of oil increase ventilation losses, which - as is well known - increase very rapidly with speed. This requires the use of oil-injected screw compressors at rather lower speeds, for example with a main rotor tooth speed of about 30 m / s.

Until now, if screw compressors were used in both stages of the refrigeration unit compression unit, they were either high-performance, oil injected, or the first stage compressor was dry, with synchronization. The disadvantage of such compressor sets was that in both cases the efficiency of the compressor was the first compression stage. rather low, for example 55%.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a refrigeration compressor package. equipment that. would achieve high adiabatic efficiency of the first compression stage compressor and thereby. and the compressor unit as a whole, using a screw-type compressor of a simple design, saving space as a first stage compressor.

According to the invention, a compressor assembly comprising an independent first and second screw compressor with a main and a secondary rotor in engagement forming a low and high pressure compression stage, each screw compressor having one rotor driven by a drive motor and a second rotor driven by direct contact of its engagement surfaces with the engagement surfaces of the first rotor, the principle being that the main rotor drive of the low pressure screw compressor is adapted via the gearbox to the fast first engine, and the main rotor drive of the high pressure screw compressor is adapted by the second engine directly, than the ratio of the radius of the main rotor of the high-pressure compressor to the main rotor of the low-pressure compressor, and the low-pressure compressor is connected by a piping of the oil pump for lubricating oil supply at least in an amount sufficient to lubricate the interfacing surfaces of the main and minor rotors of the low pressure screw compressor.

Further, according to the invention, the speed ratio of the first motor and the second motor is at least twice that of the rotors of the high pressure screw compressor and the low pressure screw compressor.

Finally, according to the invention, the low-pressure screw compressor is connected via a conduit to a coolant precipitator, for its supply to the grooves between the main and sub-rotors of the low-pressure screw compressor.

The screw compressor comprises two screw rotors engaged in parallel axes, housed in the compressor housing. One of the screw rotors is the main with the convex wheels and the other is the secondary with the concave wheels. The compressor casing has cylindrical peripheral walls and end faces and is provided with a low-pressure and a high-pressure port of the pressurized environment.

An advantage of the arrangement according to the invention is that since the first compressor contains only a small amount of oil, this oil does not cause considerable ventilation losses. Therefore, the first compressor can run at a much higher speed than the oil-flooded compressor - for example, a peripheral speed of the main rotor of 70 m / s, resulting in smaller compressor dimensions.

Further, due to the low compression ratio, the load on the radial bearings is also low, which allows the use of antifriction bearings of sufficiently small dimensions to provide space between the motor housings, but still of acceptable service life.

The first low pressure screw compressor is driven at a speed such that the peripheral speed of its main rotor is at least twice the peripheral speed of the main rotor of the second high pressure screw compressor. In order to drive the low pressure screw compressor to the desired high speed, it is in many cases advisable to place a gear between the first drive device, for example an electric motor, and the low pressure screw compressor. However, the cost of this gear transmission is higher than that it can be compensated by reducing the low pressure screw compressor.

The amount of oil supplied to the working chamber of the low pressure screw compressor is so small that it has substantially no cooling effect. Therefore, it is also often desirable to cool a low pressure screw compressor, for example by pumping liquid refrigerant from the high pressure compression stage of the assembly and injecting it into the rotor grooves of the low pressure screw compressor at such a compression stage and at such a rate. If necessary, the gaseous refrigerant extruded from the low pressure screw compressor can be cooled in the intercooler before it enters the high pressure screw compressor.

In the following, the invention will be described by way of example with reference to the accompanying drawing, in which a cooling device provided with a compressor assembly according to the invention is shown schematically.

The apparatus shown in the drawing relates to a compressor assembly comprising a low pressure compressor 10A and a high pressure compressor 10B. Typically, the apparatus further comprises an oil separator 12, a precipitator 14, an evaporator 16, an oil cooler 18 and an oil pump 20, the compressors 10A, 10B, the oil separator 12, an precipitator 14 and an evaporator 16 are connected one after the other to form a closed refrigerant circuit. A throttle valve 22 is connected between the collector 14 and the evaporator 16.

Both compressors 10A, 10B are screw compressors with the main and slave rotors engaged. Each screw compressor 10A, 10B is driven by motors 28, 26 ‘for example by electric motors. In this case, the two motors 26, 26 ‘move at the same speed. The low pressure screw compressor 10A is driven by the first motor 26 via a 28 to high speed gear whose output speed is, for example, two to three times higher than the input speed. The high pressure screw compressor 10B is driven directly by the second 26 ‘motor.

In the illustrated embodiment, oil pump oil 20 is fed to both screw compressors 10A, 10B through lines 30, 32. The amount of oil fed to the low pressure compressor 10A is limited so that it at least does not significantly exceed the amount necessary to sufficiently lubricate the relatively moving rotor contact surfaces. of screw compressors 10A, 10B. At the same time, a certain sealing effect can be automatically obtained. The high pressure screw compressor 10B is ignited by oil, which not only has a lubricating and sealing effect, but also serves to cool the coolant during its sealing effect. High pressure oil screw screw are well known and are described, for example, in British Patent Nos. 832,386 and 1,171,291. In such compressors, the mass of the oil stream flowing through the screw compressor is greater than the mass of the compressed gas stream. The amount of oil fed to the high pressure screw compressor 10B is several times greater than the amount of oil fed to the low pressure screw compressor 10A. In order to cool the refrigerant gas compressed by the low pressure compressor 10A, liquid refrigerant is supplied from the collector 14 via line 34. Liquid refrigerant is injected into the working chamber of the low pressure screw compressor 10A at such a compression stage and at a rate that discharge temperature, the value of which is determined to correspond to the actual thermodynamic cycle. At the same time, the temperature of the low pressure screw compressor 10A is maintained at such a level that the thermal deformation of the rotors and housing will not cause any problems.

The rotors of the low pressure screw compressor 10A 'are mounted in rolling bearings. On the drawing . Also shown are inlet and outlet openings for a coolant, such as water, circulating through the precipitator 14 and the oil cooler 18.

One or both. screw compressors 10A, 10B may be provided with power control sliders, and the high pressure screw compressor 10B may also be cooled by injecting liquid coolant in addition with injection oil cooling.

Claims (3)

Subject A compressor assembly comprising an independent first and a second screw compressor with a main and a secondary rotor engaged, forming a low-pressure and a high-pressure compression stage, each screw compressor having one rotor driven by a drive motor and the other directly driven by its engagement surfaces with the engagement surfaces of the first characterized in that the main rotor drive of the low pressure screw compressor (10A) is provided via the gearbox (28) to the fast first motor (26) and the main rotor drive of the high pressure screw compressor (10B) is provided directly by the second motor (26 ') the ratio of - the speed (n _A ) 'of the first motor (26) and - the speed (пв) of the second motor (26') is greater than the ratio of the radius of the main rotor of the high pressure screw compressor (1OB) to the main rotor of the low pressure compressor (10A) low- BACKGROUND OF THE INVENTION A compressor (10A) is connected by a line (30) to an oil pump supply (20) for supplying lubricating oil at least in an amount sufficient to lubricate the moving-contact surfaces of the main and sub-rotors of the low pressure screw compressor (10A). Compressor set according to claim 1, characterized in that - the ratio of the rotational speed (n _A , Пв) of the first motor (26) and the second motor (26 ') is at least twice that of the radius ratio (R _a , - Rb) the main rotors of the high pressure screw compressor (10B) and the low pressure screw compressor (10A). Compressor set according to Claims 1 or 2, characterized in that the low-pressure screw compressor (10A) is connected via a line (34) to the coolant collector (14) for its feed into the grooves between the main and sub-rotors of the low-pressure screw compressor (10AJ).