SU721560A1 - Birotary compressor - Google Patents

Description

The invention relates to the field of compressor engineering and can be used in pumps and compressors with trochoid profiles of working surfaces. Known birotational compressors, comprising a housing, an end cap with suction and discharge windows, and located in a housing with the possibility of external and internal rotors with trochoid working surfaces, which have internal engagement, can be mounted. The disadvantage of this birotational compressor is that in it the suction and discharge cavities communicate through the Melsdu gap with external and internal rotors, which leads to significant gas overflows and requires abundant lubricant to seal the gaps and thereby the productivity of the combissor. The aim of the invention is to increase productivity by reducing the flow from the discharge cavity to the absorption cavity. The goal is achieved in that the external rotor in the birotational compress is made of three elements: an outer cup, an intermediate elastic material, and an inner thin-walled spring sleeve with an equidistant profile of the hypotrochoid. This reduces leakage and dead volume to a minimum by creating contact between the rolling surfaces of the rotating rotors, as it were, by introducing a spring-loaded elastic-elastic thin-walled bushing into the structure of the spring-loaded elastic-elastic material and thereby increasing productivity. FIG. 1 shows the proposed compressor, a longitudinal section; in fig. 2- the same cross section; in fig. 3- part of the rotors which are engaged. The compressor contains it case 1, end cover 2 with suction 3 and

the discharge 4 windows and the BHemHHjft 5 rotatably disposed in the housing 1 and the inner 6 rotors with trochoidal work surfaces having internal engagement. The outer rotor 5 is made of three elements: the outer cup 7, the intermediate elastic material 8 and the inner spring thin-walled sleeve 9. The profile of the thin-walled sleeve 9 is equal to the hypotrochoid equidistant calculated to overlap the maximum possible shape errors caused by technological and operational factors.

Birutativny compressor operates as follows.

When the outer rotor 5 rotates, its spring-thin-walled sleeve 9 uvELekaet the rotor 6. The working surfaces of the compressor, made on the hypotrochoid and its envelope or equidistor of the hypotrochoid and its envelope, do not require synchronizing gears. In the process of joint rotation of the rotors 5 and 6, the compressible gas moves from the suction port 3 to the injection port 4.

In the process of operation, the relative position of the rotors takes place when the cell volume becomes minimal. In this case, the cells are divided into two cavities A and B (Fig. 3). The cavity A is connected to the injection window 4, and the cavity B to the suction window 3. In order to reduce the flow of gas from the discharge to the intake, it is necessary that these cavities remain isolated during operation. However, in known designs, due to errors in the manufacture of the working bodies, their positional errors and deformations under operating conditions, these cavities are always communicated, since there are gaps between the rotors.

In part, these gaps can be sealed with oil injected into the working cavity of the compressor.

To reduce gas overflow from injection to suction and to reduce the amount of injected oil, a thin-walled spring sleeve 9 is inserted into the design of the outer rotor 5, fixed through an elastic-partial material.

8, for example polyurethane, in an outer cup 7 of the outer rotor 5.

Due to this implementation of the external rotor 5 thin-walled sleeve 9 under the action of the elastic-elastic material

8 is constantly in contact with the inner rotor 6, the minimum cell section is divided into two isolated cavities, due to which gas leakage from pumping to suction is reduced, the amount of oil injected and the working cavity are reduced, and the productivity of the birotational compressor is increased.

Claims (1)

1. US patent number ZO83894, Cl, 418-171, 1964, FIG.