SU1293362A1 - Ejector for airing blind workings - Google Patents

Abstract

This invention relates to a mine ventilation technique. The goal is to increase the ventilation efficiency by increasing the amount of ejected air. The ejector consists of two diffusers 1 and 2 installed coaxially along its longitudinal axis 3 and symmetrically with respect to the transverse axis 4 of the receiving neck 5. It is connected to fittings 6 and 7 for supplying compressed air. Inside the neck 5 between the diffusers 1 and 2 there is a ring 8 with a diaphragm 11 on its outer surface (R). The ring 8 may interchange along the axis 3, forming the right and left outlet slots 12. The inner P 10 of the ring 8 consists of two truncated conical P 16 and 17, which are conjugated to each other without rounding in a smaller diameter. The junction between face 9 and internal П 10 is made with a radius determined from the expression: R 3, ЗН-6.6Н, where Н is the width of the outlet slit, m; R is the radius of rounding. When compressed air is fed into the throat 5, its pressure shifts the diaphragm 11 with the ring 8 to the left. Blowing out air from both the right slit 12 and the left slit takes the form of a slotted conical wall jet 15 or 19 with a curvilinear axis. Stream 15 or 19 sticks to the rounding radius R, twists its axis and flows along the inner P 10 of the 8l ring. With such a blowing of a jet of compressed air, the ejection of ambient air 16 and 19 into the jet increases. 2 Il. about (l go with so from 5 th

Description

The invention relates to ventilation technology, in particular to ventilation technology for mining, and can be used in devices for airing blind workings.

The purpose of the invention is to increase the ventilation efficiency by increasing the amount of ejected air.

Fig. 1 shows an ejector for ventilation of blind workings, a longitudinal section; on fig.2 - node I in figure 1.

The ejector (figure 1) consists of diffusers 1 and 2 installed along the longitudinal axis 3 of the ejector and symmetrically with respect to the transverse axis 4 of the receiving neck 5 (the left slot in figure 1 is closed) with fittings 6 and 7. Ring 8 having end 9 and the inner surface 10 and connected to the diaphragm 11, is installed with the possibility of reciprocating movement along the axis 3 of the ejector and with the formation of the outlet slit 12. The diaphragm 11 through the clamp 13 is rigidly fixed to the housing of the receiving neck 5.

Arrow 14 (FIG. 1) shows compressed air supply to the right annular slit 12 through the right fitting 7, arrow 15 (FIGS. 1 and 2) —a jet of compressed air from the right annular slit 12 at the extreme left position of the ring 8, and arrow 16 (Figures 1 and 2) —the direction of ejection of air flow into the jet from the surrounding ventilated space.

The arrows 17, 18 and 19 (Fig. 1) show the corresponding flows when the compressed air is supplied through the left fitting 7 to the left slot in the rightmost position of the ring 8.

The end surfaces 9 (Figures 1 and 2) of the ring 8 are made in a plane perpendicular to the axis 3 of the ejector, and are mated to the inner surface 10 of the ring 8 with curvings of radius R (Figure 2). The inner surface 10 of the ring 8 consists of two truncated conical surfaces 16 and 17, which are joined together without rounding along a smaller diameter in the middle section 18 of the ring 8 (Figures 1 and 2). 2, the letter H denotes the width of the annular gap.

The radius of rounding is determined from the mathematical expression

R 3, NN -6,6N.

The device works as follows. When compressed air is supplied through the first fitting 7 along arrow 14 to neck 5 (Fig. 1), the pressure of compressed air displaces diaphragm 11 to the left, which displaces ring 8 to the left, which opens the right slot 12 and compressed air is blown into the ejector in the form of a jet 15 (Figures 1 and 2), which sticks to the right rounding radius R, rotates on the rounding in the direction parallel to the longitudinal axis of the ejector, and flows along the conical surface of the ring 8 in the form of a slit conical wall jet with a curvilinear axis ve ited in the median section. The strut 15 through the diffuser 1 ejects the stream 16 from the ventilated space.

When compressed air is supplied through the left driver 7 in direction of arrow 17 to neck 5 (Fig. 1), the pressure of compressed air displaces diaphragm 11 to the right, which displaces ring 8 to the right, as a result of which the left slit opens and compressed air is blown into the ejector in the form of a jet 18, which sticks to the left rounding radius (Figures 1 and 2), turns on the rounding in a direction approximately parallel to the longitudinal axis of the ejector, and flows along the conical surface of the ring 8 in the form of a slotted conical jet with a curvilinear axis,

0 detached from the conical surface in the middle section. The jet 18 ejects through the diffuser 2 a stream 19 from the external space (figure 1).

Thus, blowing compressed air

both from the right 12 and from the left slots are made in the form of a slit conical wall jet 15 or 19 with a curvilinear axis, which adheres to rounding radius R, bends its axis and flows along the inner surface 10 of the ring 8.

0 With this injection of a jet of compressed air ejection surrounding, its air 16 and 19 into the jet increases.

To ensure stable adhesion of the jet 15 and 18 to the rounding radius R and, therefore, to ensure the maximum ejection coefficient, it is recommended to choose a rounding radius within

R s, ZN - 6,6N

in accordance with the data obtained by the authors through special experimental studies.

Claims (1)

Invention Formula j Injector for airing a dead end openings, including two diffusers, installed coaxially with the longitudinal axis of the ejector and symmetrically with respect to the throat, connected to two fittings for supplying compressed air, inside which is placed a ring with a diaphragm fixed on its outer surface, mounted inside the throat between the diffusers with the possibility of reciprocating motion with the formation of the exhaust slit, characterized in that, in order to increase 5 of the efficiency of airing the workings by increasing the amount of ejected air, the inner surface of the ring is made in the form of two mating surfaces, and the interface between the end and inner surfaces of the ring is made with a radius determined from the following mathematical expression: j 3,3 // -f- 6,6I, where N is the width of the exhaust slit, m; R is the radius of rounding, m FIG. 2