SU1109541A1 - Cryocondensation vacuum trap - Google Patents

Abstract

A CRYO CONDENSATION VACUUM TRAP, comprising a housing with a lid, inlet and outlet connections and a condensate collector located in the lower part of the housing, characterized in that, in order to improve serviceability, it further comprises a condensate extraction device, a purge gas supply system, a receiving pipe the purge gas supply tube, the receiving tube is installed along the axis of the housing, its lower end is placed in the condensate collector, the upper end is connected to the condensate extraction device, and one ends of the pipe supplying a purge gas are arranged concentrically in the cover receiving tube, while others are connected to a purge gas supply system. (L with cd 4 ;;

Description

The invention relates to vacuum technology.

Known cryogenic vacuum trap for vacuum steam-oil pumps, containing trapping elements and is intended mainly to prevent migration of the vapor of the working fluid from vacuum pumps [1].

However, this trap cannot be used to capture large quantities of easily condensable gas mixture.

Vapors from a pumping-off condensation vacuum trap are also known, comprising a housing with a cover, an inlet and an outlet, and a condensate collector located in the lower part of the housing [2].

However, in the known trap, there is no control over the completeness of condensate removal from the trap, while the removal of refrigerant from the trap is possible only due to its own evaporation, which does not provide for 20 quick removal of refrigerant before being supplied to the coolant reservoir.

The aim of the invention is to improve serviceability.

This goal is achieved by the fact that a cryocondensation vacuum trap ²⁵ containing a housing with a cover, inlet and outlet pipes and a condensate collector located in the lower part of the housing further comprises a condensate extraction device, a product supply system. _} θ of the waste gas, a receiving tube and purge gas supply tubes, the receiving tube being installed along the axis of the housing, its lower end is located in the condensate collector, the upper end is connected to the condensate extraction device, and one ends of the purging gas supply tubes ₃₅ are placed in the cap concentrically to the receiving tube and others are connected to the purge gas supply system.

The drawing shows a diagram of a trap and control equipment connected to it.

Cryocondensation vacuum trap contains a housing 1 with a cover 2, inlet and outlet pipes 3 and 4, and a condensate collector 5 located in the lower part of the housing 1.

The trap further comprises a condensate extraction device 6, a purge gas supply system, a receiving tube 7 and purge gas supply tubes 8, wherein the receiving tube 7 is mounted on the axis of the housing 1, its lower end is placed in the condensate collector 5, the upper one is connected to the condensate collection device 6 , some ends of the purge gas supply tubes 8 are located in the cap 2 concentrically to the receiving tube 7, and others are connected to the purge gas supply system.

The vacuum trap is also provided with a reservoir 9 for the refrigerant.

The housing 1 is placed in a tank 9 for a refrigerant filled with liquid nitrogen. The evacuated gases are in contact with the cooled surfaces of the trap, on which the easily condensable components of the evacuated gas mixture are frozen, as well as the return flow of the vapor of the working fluid of the vacuum pump (not shown).

In order to extract condensate from the trap and analyze it, the inlet and outlet pipes 3 and 4 are closed and removed from the tank 9 with the refrigerant, they are removed from the housing 1. Due to heat transfer from the external environment, the frozen one is removed from the housing 1. Due to heat transfer from the external Condensed water on frozen surfaces thaws and turns into a liquid. Then, using the device 6, suction liquid condensate. Dry heated air is supplied to the tube 8, which, entering the housing 1, blows all the internal surfaces of the trap, including those on which the vapor of the pumped mixture condenses and on which, after the removal of the main amount of condensate, the adsorbed layers of liquid remain. This liquid evaporates and the vapor-gas stream leaves the trap through the tube 7.

This ensures the most complete extraction of the condensate (up to 100%), practically eliminating its loss, which is especially important when determining the balance of substances, for example, absorbed by the adsorbent layer and desorbed during vacuum desorption. The trap is purged with air until the humidity of the gas stream becomes equal to the humidity of the air supplied to the trap.

Thus, the proposed trap allows you to increase the completeness of condensate extraction (up to 100%) from the trap, as well as improve serviceability due to the design of the trap is easily collapsible.

Claims (1)

Cryocondensation vacuum trap, comprising a housing with a cover, an inlet and an outlet, and a condensate collector located in the lower part of the housing, characterized in that, in order to improve serviceability, it further comprises a condensate extraction device, a purge gas supply system, a receiving tube and purge gas supply tubes, the receiving tube being installed along the axis of the housing, its lower end is located in the condensate collector, the upper one is connected to the condensate extraction device, and one ends of the supply tubes and purge gas are housed in a cap concentrically in the receiving tube, while others are connected to the purge gas supply system. (G SU. 1109541 From the purge gas system