SU1262137A1 - Vortex ejector - Google Patents

Abstract

The invention relates to power plant engineering, in particular, to vortex ejectors for pumping various media. The purpose of the invention is to expand the range of operation by increasing the degree of twist of the gas. In the vortex chamber 1 with annular spacers 4, 6, and 7 with a tangential rectangular active nozzles 5, 8, and 9, each with a different height, respectively, hi, hz, hi, varying from spacer to spacer. The length of the spacers / 1-2, 1 is 1.5-2.0 of their height. Neighboring spacers are spaced apart from each other at a distance Ar |, Al2 not less than the height of the nozzles of the larger of the adjacent spacers, and nozzles 5. 8 and 9 of each of the spacers 4,6 and 7 have a total area, where is the area of the nozzles closest to the axis of the swirl space ; r, and TI are the inner radii of the vortex chamber, respectively, of rth and near to the axis of the chamber. The active gaseous medium, the passage through chamber 1, nozzles 5, 8, and 9, accelerates with increasing swirling flow. Gradual acceleration eliminates the flow of medium along the end surfaces of chamber 1. After flowing out of the nozzles 9, the active medium S creates in the axial region of chamber 1 a region of reduced pressure, which causes a passive medium to enter the ejector. 2 Il. % agzh1 Yu lBi-D. WITH

Description

The invention relates to inkjet technology, mainly to vortex ejectors for pumping various media.

The purpose of the invention is the expansion of the range of work.

In FIG. 1 shows a vortex ejector, ^{5 is a} longitudinal section; in FIG. 2 is a section AA in FIG. 1.

The vortex ejector comprises a swirl chamber 1 with a passive medium supply pipe 2 and a mixing chamber 3 and an annular spacer 4 located in the swirl chamber 1 with tangential rectangular active nozzles 5. The ejector is provided with additional annular spacers 6 concentrically located in the swirl chamber 1 6 and 7 with tangential rectangular active nozzles 8 and 9, the nozzles 5, 8 and 9 having different heights, respectively / g ,, / yy and / and, varying from a spacer to a spacer, and a length of ₂ θ /.·, / g and / |, component of 1.5-2.0 you Ota hi, h ₂ and hi, adjacent spacers are spaced apart at a distance of Ari and x2 is not less than the height of the nozzle the greater of adjacent spacers, and nozzles 5, 8 and 9, each spacer 4, 6 and 7 have a total area 25 defined by the relation :

where fs. - the area of the nozzles closest to the axis of the chamber swirl spacers; 30 g, - and G | - the internal radii of the i-th and spacers swirls closest to the axis of the chamber, respectively.

The active gaseous medium is tangentially fed into the turbulence chamber 1, acquires rotational motion in the last ³⁵ and, sequentially flowing through the active nozzles 5, 8 and 9 of the annular spacers 4, 6 and 7, gradually accelerates with a corresponding increase in the swirl of the active medium flow, and gradual acceleration of the active medium from the spacer to the spacer eliminates the overflow of the active medium along the end surfaces of the turbulence chamber 1. Expiring from the active nozzles 9 of the spacer 7 closest to the axis of the swirl chamber 1, the active medium creates a region of reduced pressure in the axial region of the swirl chamber 1, which causes the passive medium to enter the ejector through the inlet 2 of the passive medium supply. In the mixing chamber 3, the active and passive media are mixed and the mixture of media is supplied further to the destination.

Claims (1)

Claim A vortex ejector containing a swirl chamber with a passive medium supply pipe and a mixing chamber and an annular spacer located in the swirl chamber with tangential rectangular active nozzles, characterized in that, in order to expand the ejector’s working range, it is equipped with additional annular spacers concentrically located in the swirl chamber tangential rectangular active nozzles, and the nozzles have different heights, varying from spacers to spacers, and a length of 1.5-2.0 in heights, adjacent spacers are located one from another at a distance not less than the nozzle height of the largest of the adjacent spacers, and the nozzles of each spacer have a total area determined from the relation where F ^ is the nozzle area of the spacer closest to the axis of the swirl chamber; rt and r | —The internal radii of the ίth and spacers swirls closest to the axis of the chamber, respectively.