SU848694A1 - Jet nozzle - Google Patents

Description

(54) SPRAYER

The invention relates to the mining industry and can be used to combat dust in the operation of mining machines using water-air ejectors. Nozzles for flat ejectors of the type EP and FC, containing a conical or umbrella torch, the shape of which is determined by the design of the nozzle input, are known. Such nozzles operate at a pressure of 6-15 kgf / cm. In a flat ejector, the opening of the cone or umbrella torch of the nozzle does not cause an even flow of liquid and air, as the flat walls of the ejector do not evenly become wetted with a circular section of the nozzle torch. these nozzles l. The disadvantage of such nozzles is the low productivity of the flat ejector and the effectiveness of dust suppression. The closest technical solution to the present invention is a flat-jet nozzle, including a housing with a housing located therein with an internal channel and an external channel located perpendicular to it. The nozzle has a milled groove, on which the direction of spraying of a flat torch of the nozzle depends. The flat torch of these nozzles does not reach the walls of the flat ejector and does not fill the entire volume of the flat ejector; therefore, there is no intensive interaction of the air jet with water droplets. On nonwettable walls, a stream of drawn air passes through the ejector izj. The disadvantage of such a nozzle is the low efficiency of the air suppression and the productivity of water-to-air flat ejectors.

The purpose of the invention is to increase the effectiveness of dust suppression.

This goal is achieved in that the nozzle, which includes the housing and the insert with the central channel, is inserted with additional channels that are offset from the axis of the housing and provided with a shaped guide that is installed so as to extend the inner walls of the additional channels.

FIG. 1 shows the nozzle, in a perspective view; in fig. 2 - nozzle, general view in section along the axis; in fig. 3 - the same general view with digging through the internal channel.

The nozzle includes a housing 1, which has an insert 2 located therein with additional channels 3 and a central channel 4, which are perpendicular to each other, and the additional channels 3 are displaced relative to the axis a-a forcing. The nozzle is also provided with a profiled guide 5, the walls of which are a continuation of the inner walls 7 of the additional channels 3. The liquid is supplied through the channel 8 in the nozzle body. .

With the help of channels 3 and the central channel 4 of the insert 2, flat jets are formed {not one, but in the existing nozzles), and to improve the formation of the plume and its best direction on the insert 2 is fixed to the profiled guide 5, with the improvement directing fluid flow to the walls of a flat ejector (not shown).

Thus, the liquid entering the channel 8 of the nozzle body 1 is directed to the central channel 4, through which the additional channels 3 located perpendicular to it, where the formation of flat fluid plumes going out of the nozzle occurs. The walls in the profiled guide 5, as it were, continue the length of the run of the fluid through the additional channels 3 and contribute to the directional formation of the nozzle plume, in contact with which the flat torch of the fluid is thrown onto the walls of the ejector.

The use of the proposed nozzle in ejectors allows for increased reliability and efficiency of dust suppression while reducing water consumption by half compared with existing typical irrigation devices, which leads to significant economic efficiency of the dust suppression system using ejectors.

Claims (2)

1. Equipment and instruments for com-. depleted coal mines and concentrators. M., 1975, p. 124. 2. USSR author's certificate No. 281363., class E 23 011/14, 1968 (prototype). FiggZ