RU1806297C - Ejector - Google Patents

Abstract

Usage: in inkjet technology. SUMMARY OF THE INVENTION: active medium flow separators are mounted in series in a mixing chamber behind the outlet section of the active nozzle and are made in the form of concentrically mounted rings connected to each other and to the mixing chamber by radial bearings. The supports in the cross section and the separator rings in a longitudinal radial section are made with an inlet section with a sharp edge facing the outlet section of the active nozzle. The longitudinal radial sections of the rings of adjacent dividers and the supports of the latter are staggered. The inlet section of the ring closest to the active nozzle, formed by its sharp edges, is located in the plane of the outlet section of the active nozzle. 13 s.p. f-ly, 8 ill.

Description

The invention relates to inkjet technology and can be used for re-pumping various media. .

The purpose of the invention is to increase efficiency. . In FIG. 1 shows a longitudinal section of the proposed ejector; in FIG. 2-5 are sections in FIG. 1; in FIG. 6 is a longitudinal section through an ejector; FIGS. 7 and 8 are sections A-A in FIG. 1.

In an ejector (Fig. 1, 2) containing an active nozzle 1, a mixing chamber 2, a diffuser 3, and; active medium flow dividers 4 mounted in series in the mixing chamber 2 behind the outlet section of the active nozzle 1 and made in the form of concentrically mounted rings 5, connected with each other and with the mixing chamber by radial bearings 6, which in cross section and ring 5 of the spacer 4 in a longitudinal radial section are made with an inlet section with a sharp edge

7 facing the exit section of the active nozzle 1, wherein the longitudinal radial sections of the rings 5 of adjacent flow dividers 4 and the radial bearings 6 of the latter are staggered.

Moreover, the input section I-I of the separator 4 ring 5 closest to the active nozzle 1 of the ring 5 (Fig. 1, 2), formed by the sharp edges 7 of the latter, can be located in the plane of the output section of the active nozzle 1; the separator 4 closest to the active nozzle 1 (Fig. 1) can be installed with a gap relative to the output section of the active nozzle 1; the plane of the exit section of the separator 4 closest to the active nozzle 1 (Fig. 1) may be located in the plane of the input section 11-11 of the next separator 4; the dividers 4 can be installed with a gap between them (Fig. 1, 2); rings 5

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the dividers 4 in the longitudinal radial section can be made in the form of an isosceles triangle (Fig. 2), the height of which is parallel to the axis of the ejector, and the shape of the supports 6 in the cross section is identical to the shape of the rings 5 in their longitudinal radial section, and the cross section of the bearings is symmetrical about the axis e an ector; the rings 5 of the flow separator 4 in a longitudinal radial section can be made symmetrical about an axis passing through the section and parallel to the axis of the ejector (Fig. 3), while the specified section of the ring 5 of the separator 4 is formed by a straight input 8 and output 9 generators, interconnected by a curvilinear generatrix 10 facing outwardly convex, and forming 9 of the outlet portion of the rings 5. The separator 4 is parallel to each other, and the shape of the supports 6 in cross section is identical to the shape of the rings 5 in their longitudinal radial. In the cross section, the cross section of the supports 6 is located symmetrically with respect to the axis of the ejector; the rings 5 of the flow separator 4 in a longitudinal radial section can be made symmetrical with respect to the axis passing through the section of the ring 5 and parallel to the axis of the ejector (Fig. 4), while the input and output sections of this section of the ring 5 are formed respectively by convex curved 11 and rectilinear 12 generators, and the rectilinear generators 12 of the output section are parallel to each other; the inner surface 13 of the rings 5 of the separator 4 closest to the nozzle 1 and the outer surface 14 of the rings 5 of the next separator 4 can be cylindrical (Fig. 5), and the shape of the supports in their cross section can be identical to the shape of the rings in their longitudinal radial cross-section, and the wall of the support, identical to the generatrix of the cylindrical surface of the rings 5, is parallel to the axis of the ejector; radial bearings 6, by means of which the rings 5 of the separator 4 are fixed in the mixing chamber 2, can be installed at an acute angle to the axis of the ejector along the flow (Fig. 6); radial bearings 6, by means of which the rings 5 of the separator 4 are fixed in the mixing chamber 2, can be mounted perpendicular to the axis of the ejector (Fig. 1); on the inner 13 and outer 14 side surfaces of the rings 5 of the separator 4 (Fig. 7), grooves 15 and protrusions 16 can be made between the latter, while the grooves 15 and protrusions 16 are made along the flow of the active medium, the sharp edge 7 is rounded and the radius the input edge 17 of the groove 15 on the outer surface 14 of the rings 5 may be greater than or equal to the radius of the sharp

the edges 7 of the rings 5, and the radius of the input edge 18 of the grooves 15 on the inner surface may be less than or equal to the radius of the sharp edge 7 of the flow separator 4; the radii of the output edges 19 and 20 of the grooves 15 (Fig. 7)

0 of the inner and outer surfaces can be equal to the radii of the input edges 17 and 18 of their respective grooves 15; grooves 15 on the outer surface of the rings 5 (Fig. 8) can be made with the radius of the output

5 of the edge 20, exceeding the radius of their input edge 17, d grooves 15 on the inner surface of the rings 5 can be made with a radius of the output edge 19, smaller than the radius of their input edge 18.

0 The ejector works as follows (Fig. 1,2). An active medium (steam or water) enters the nozzle 1 from the receiving chamber, where the potential energy of the pressure of the latter is converted to the kinetic energy of the jet, which, after exiting the nozzle 1, passes through the mixture 2 installed in series in the chamber 2 behind the exit section of the active nozzle 1 flow dividers 4 facing

0 with a sharp edge 7 of the inlet portion toward the outlet section of the active nozzle 1, whereby instead of one solid jet, a series of tubular jets are formed instead of one solid jet, between which

5 there are cylindrical gaps. The passive medium enters into the indicated gaps along the rear faces facing the diffuser 3, radial bearings 6 having inlet cross section

0 plot with a sharp edge. Consistently, the staggered placement of the flow dividers 4 with a sharp edge 7 of the inlet portion in the mixing chamber 2 provides tubular jets of the active medium with less than 1

5 thicker, which leads to an increase in the interaction surface of the two media, a decrease in hydraulic resistance and, consequently, an increase in efficiency, and also in this case, the reliability of the ejector when pumping contaminated media is increased in comparison with an ejector having rings 5 of flow separators 4 installed only in one section, since the gap between

5. by adjacent flow dividers of one cross section, this increases.

The location of the input section 1-4 closest to the active nozzle 1 of the ring. 5 separator 4 (Fig. 1, 2), formed by the sharp edges 7 of the latter, can be in

the plane of the exit section of the active nozzle 1, as well as the separator 4 closest to the active nozzle 1 (Fig. 1) can be installed with a gap relative to the inlet section of the active nozzle 1, and the location of the exit section plane of the separator 4, closest to the active nozzle 1 (Fig. 1 ), may be in the plane of the inlet section II-II of the separator 4 following it, or the separators 4 can be installed with a gap between them (Figs. 1, 2). The choice of this or that location of the input H and output II-II sections of the separator 4 closest to the active nozzle 1 of the ring 5 is determined by the characteristics of the ejector and the achieved efficiency.

The embodiment of the longitudinal radial section of the rings 5 of the spacers 4 (Fig. 2-5) and the shape of the supports in the cross section are selected from the conditions for achieving the maximum efficiency due to the improved conditions of the two media and the effective access of the passive medium to the formed gaps between the tubular jets during operation Ejector. For better passage of the passive medium into the radial bearings 6 formed by the cylindrical gaps, by means of which the rings 5 of the separator 4 are fixed in the mixing chamber 2, can be installed at an acute angle p to the axis of the ejector along the flow (Fig. 6).

In addition, in order to further increase the efficiency of the ejector due to the development of the interaction surface of two media on the inner 13 and outer 14 lateral surfaces of the rings 5 of the separator 4 (Fig. 7, 8), grooves 15 and protrusions 16 between the latter can be made along the flow of the active medium . In this case, the interaction surface of the active medium with the passive medium sharply increases, the fragmentation, (decay) of the jet of the active medium improves, and the process of transferring the kinetic energy from the active to the passive medium is intensified.

The number of dividers and supports, their geometric dimensions are determined from the condition that the maximum efficiency of the ejector is achieved, taking into account the rigidity of the structure and the reliability of its operation.

The use of the claimed invention in condensing units of steam turbines, as well as in other branches of technology, makes it possible to reduce the energy consumption for the operation of the ejector due to a significant increase in its efficiency, as well as to reduce the weight and dimensions, and to increase the reliability of the ejector.

Formula 1. An ejector containing an active nozzle, a mixing chamber, a diffuser and active medium flow dividers installed in series in the mixing chamber behind the exit section of the active nozzle and made in the form concentrically mounted rings interconnected and with the mixing chamber radial

0 supports, characterized in that the radial bearings in the cross section and the spacer rings in the longitudinal radial section are made with the inlet section with a sharp edge facing

5 to the output section of the active nozzle, while the longitudinal radial sections of 1 rings of adjacent spacers and the radial bearings of the latter are located in a checkerboard pattern.

02. The ejector according to claim 1, characterized in that the input section of the separator closest to the active nozzle of the ring formed by the sharp edges of the latter is located in the plane of the output section of the active nozzle.

3. The ejector according to claim 1, characterized in that the separator closest to the active nozzle is installed with a gap relative to the exit section of the active nozzle.

0 4. Ejector pop. 1, characterized in that the plane of the output section of the separator closest to the active nozzle is located in the plane of the input section of the next separator,

5 5. Ejector pop. 1, characterized in that the separators are installed with a gap between them.

 6. The ejector according to claim 1, characterized in that the ring separators in the longitudinal

0 radial section made in the form of an isosceles triangle, the height of ko. which is parallel to the ejector axis, and the shape of the supports in cross section is identical to the shape of rings in an axially longitudinal radial section, and the cross section of the supports is symmetrical about the axis of the ejector.

7. Pop ejector, 1, characterized in that the flow separator rings in longitudinal radial section are made

0 symmetrical with respect to the axis passing through the section of the ring and parallel to the axis of the ejector, while the indicated section of the separator ring is formed by a linear input and output form 5. which are adjacent to each other, having a curved generatrix facing outward, and the generators of the output section of the separator rings are parallel to each other, the shape of the supports in cross section is identical to the shape of the rings in their longitudinal radial section, and the cross section of the supports is symmetrical with respect to the axis of the ejector. .

8. The ejector according to claim 1, characterized in that the rings of the flow separator in a longitudinal radial section are symmetrical about an axis passing through the section of the ring and parallel to the axis of the ejector, while the input and output sections of the indicated section of the ring are formed respectively by convex curvilinear and rectilinear generators, and the rectilinear generators of the output section are parallel to each other.

9. The ejector according to claim 1 ,. This is due to the fact that the inner surface of the rings of the separator closest to the nozzle and the outer surface of the rings of the next separator are cylindrical, and the shape of the supports in their cross section is identical to the shape of the rings in their longitudinal radial section, the wall of the support, identical to the generatrix of the cylindrical surface of the rings, is parallel to the axis of the ejector.

10. The ejector according to paragraphs. 1-9, about t and h and yushch and with. in that the radial bearings by which the spacer rings are fixed in the mixing chamber are mounted at an acute angle to the axis of the ejector along the flow.

11. The ejector for PGI. 1-9, characterized in that the radial bearings by which the spacer rings are fixed in the mixing chamber are mounted perpendicular to the axis of the ejector.

1.2. Ejector PP 1,6-9, characterized by the fact that grooves and protrusions between the latter are made on the inner and outer lateral surfaces of the separator rings, while the grooves and protrusions are made along the flow of the active medium, the sharp edge is rounded and the radius of the inlet edge the grooves on the outer surface of the rings are greater than or equal to

the radius of the sharp edge of the rings, and the radius of the inlet edge of the grooves on the inner surface is less than or equal to the radius of the sharp edge of the flow divider.

13. The ejector according to claim 12, characterized in that the radii of the input edges of the grooves of the inner and outer surfaces are equal to the radii of the input edges of the corresponding grooves.

14. The ejector according to claim 12, characterized in that the grooves on the outer surface of the rings are made with a radius of the outlet edge exceeding the radius of their inlet edge and the grooves on the inner

the surfaces of the rings are made with a radius of the output edge less than the radius of their input edge.

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FIG. 6