RU1433133C - Scoop pump - Google Patents

Abstract

FIELD: vacuum technology. SUBSTANCE: scoop 2 with feed and bleed channels 3, 4 is located in rotating case 1. Shroud 5 embraces case 1 to form intermediate cavity 6 in which molecular stages 7 are located. Cavity 6 communicates with inner space 8 of the case and is sealed relative to the environment. Stages 7 prevent gas penetration into cavity 6. This provides substantial reduction of rotor heating and increases the speed of rotation of case 1 and the compression ratio. EFFECT: reduced power input and improved efficiency. 2 cl, 1 dwg

Description

 The invention relates to vacuum technology and can be used in scoop pumps for pumping gases.

 The aim of the invention is to reduce energy consumption when pumping gases.

 The drawing shows a scoop pump, a longitudinal section.

 In the rotating housing of the pump 1 there is a scoop 2 with a supply 3 and a discharge 4 channels. The casing 5 covers the housing 1 with the formation of the intermediate cavity 6. The pump has molecular stages 7 located in the intermediate cavity 6. The latter is communicated with the internal space 8 of the housing 1 and sealed relative to the environment.

 The housing 1 may have a neck 9 through which the intermediate cavity 6 communicates with the interior space 8 of the housing.

 In the scoop 2, an inlet 10 is made, in communication with the outlet channel 4, and the intermediate cavity 6 is sealed with seals 11.

 The pump operates as follows.

 Pre-pump is pumped to a deep vacuum, and then accelerates. Then the gas is supplied through the supply channel 3 to the inner space 8 of the housing 1 and is carried away by the rotating walls of the housing 1. Due to the action of centrifugal forces, the gas is compressed in the direction of increasing the radius of the housing 1. Near the inlet 10 of the scoop 2, the gas has the highest static pressure and the highest linear speed close to the peripheral linear speed of the housing 1. Inside the scoop 2, the gas velocity decreases, and the dynamic pressure is converted to additional static pressure, thereby increasing the degree of Atia.

 Molecular steps 7 do not allow gas to penetrate into the cavity 6 between the casing 5 and the housing 1, where a deep vacuum is maintained. Due to this, the energy losses due to friction on the outer surface of the housing 1 are significantly reduced in the pump and the efficiency is increased. This significantly reduces the heating of the rotor, which allows to increase the speed of the housing 1 and increase the compression ratio. (56) Copyright certificate of the USSR N 937777, cl. F 04 D 1/12, 1982.

Claims (2)

 1. CUP PUMP, comprising a rotating casing, a scoop located therein with inlet and outlet channels and a casing covering the casing with the formation of an intermediate cavity, characterized in that, in order to reduce energy consumption when pumping gases, the pump further comprises molecular stages located in the intermediate cavity, and the latter is communicated with the interior of the housing and sealed relative to the environment.  2. The pump according to claim 1, characterized in that the housing is provided with a neck, and the intermediate cavity communicates with the interior of the housing through it.