SU1195048A1 - Method of cooling gas in piston compressor - Google Patents

Abstract

A COOLING METHOD FOR GAS IN A PISTON COMPRESSOR by supplying sprayed coolant to the suction or discharge pipe when the next volume of gas enters it, characterized in that, in order to increase the efficiency of the compressor by reducing the energy loss to the gas impact, the coolant is supplied in succession pipeline in front of the volume of gas and in the direction of its movement.

Description

The invention relates to a compressor industry and concerns methods for cooling gases in a piston compressor.

The purpose of the invention is to increase the efficiency of the compressor by reducing the energy loss to the gas shock.

The drawing shows a pipeline section with a device for cooling gas in a piston compressor, which implements the proposed method for cooling gas in a piston compressor, a longitudinal section.

The device for implementing the proposed gas cooling method in a piston compressor contains a glass 2 installed in the pipeline 1, having an expanding section 3 on the gas flow side with an elastic partition 4 fixed to its end surface, and a cylindrical section 5 of the glass 2 is made facing the movement of the gas nozzle 6 for spraying a liquid. The internal cavity 7 cups 2 channel 8 through the check valve 9 is connected with a source of fluid (not drawing not shown).

The method of cooling gas in a piston compressor is carried out as follows.

At the beginning of the injection process, the volume of gas begins to spread through the pipeline 1. The elastic wall 4 and the expanding section 3 are under pressure from this volume of gas, which through the elastic wall 4 is transferred to the gas-liquid mixture located in the inner cavity 7 of the cup 2. As a result, what

The rate of pressure propagation in the gas-liquid mixture is higher than in the gas; the increase in pressure in the gas-liquid mixture in the direction of the gas volume moves ahead of the pressure value in the latter.

The resulting pressure differential between the liquid and the gas causes the latter to be injected through the nozzles 6 into the pipeline 1 before the volume of gas in the direction of its movement along the pipeline 1, since the nozzles 6 are already filled with liquid. As the gas volume reaches the nozzles 6, the liquid injection stops as the pressure drop in this case becomes zero and the partition 4 begins to return to its original position under the action of elastic forces. At the same time, the pressure in the gas-liquid mixture decreases, the check valve 9 opens, and the gas-liquid mixture through channel 8 from the source of liquid begins to flow into the internal cavity 7 of the cup 2. At the same time, in the pipeline 1, after a volume of gas, a rarefaction wave begins to propagate and pressure gas in line 1 and the pressure of the gas-liquid mixture in cavity 7 is equalized. The supply of the gas-liquid mixture to the cavity 7 is stopped. In the following, the cycle repeats.

Thus, the proposed implementation of the method for cooling gas in a pneumatic compressor reduces the pressure loss of the working medium during the operation of the compressor and thereby increases the efficiency of the compressor.

Claims (1)

GAS COOLING METHOD In a PISTON COMPRESSOR by supplying finely dispersed coolant to the suction or discharge pipe when the next volume of gas enters into it, characterized in that, in order to increase the compressor efficiency by reducing energy losses on the pelvic shock, the coolant is supplied sequentially along the length of the pipeline in front of the gas volume and in the direction of his movement. REY Si yes oh about O = o, = O —O o o »SU <„> 1195048>