RU1802267C - Gas sprinkling injector - Google Patents

Description

The invention relates to means for spraying liquids, namely, nozzles for irrigation of gas and can be used for wet gas purification.

The purpose of the invention is to increase the efficiency of gas irrigation, the movement of which coincides with the direction of spraying the liquid at a variable gas flow rate,

In FIG. 1 shows a diagram of the proposed nozzle, General view; in FIG. 2 - section 1-1 in FIG. 1; in FIG. 3 is a section 2-2 in FIG. 1.

The nozzle contains a vortex chamber 1 with an inlet pipe 2, a swirl 3 and an adjusting needle 4, and an axial outlet nozzle 5. The needle 4 is mounted on a conical wall 6 with windows 7 and placed along the axis of the nozzle opening 8. The nozzle 5 is provided with a cylindrical wall 9 coaxially placed with the outer part of the chamber 1. The nozzle 5 is mounted axially movable and rotatable and is provided with a coil spring 10 located in the gap between the chamber 1 and the wall 9. One end of the spring 10 is mounted on the nozzle wall 9 and the second - on the vortex chamber 1. The nozzle 5 is equipped with aerodynamic resistance fixed to its outer part in the form of blades 11.

The nozzle works as follows.

The fluid is supplied through the nozzle 2 to the vortex chamber 1, where it acquires a rotational motion by the swirl 3, passes through the windows 7 and the nozzle 5 orifice 8, where it is sprayed into a stream of gas moving in the direction of atomization of the liquid, causing it to wet.

The gas in collision with the blades 11 is twisted and intensively moves with the spray torch.

As the gas flow rate increases, its pressure on the blades 11 increases, which leads to a displacement of the nozzle 5 along the gas and compression of the spring 10. This leads to the removal of the hole 8 from the needle 4, which increases the flow area of the hole 8 and increases the flow rate of liquid for irrigation.

As the gas flow rate decreases, spring 10 compresses due to its elasticity and

moves the nozzle 5 in the opposite direction. The needle 4 enters the hole 8 and reduces the live section of this hole, which leads to a decrease in fluid flow to

gas irrigation. When gas interacts with the blades 11, the latter rotate and twist the spring 10 due to the fact that its one end is fixed to the nozzle strut 9 and the other to the vortex chamber 1. When

achieving balance between the twisting

moment formed by the interaction

gas with blades and spring elasticity 10,

the blades 11 become oscillatory

The movement during its rotation in opposite directions by a small angle due to the action of a turbulent gas flow with pressure pulsation on the blades, which leads to an additional intensity of gas mixing with the liquid and its irrigation efficiency.

The technical and economic efficiency of the proposed nozzle compared with the prototype is to increase the quality of gas purification up to 10-12% by increasing the efficiency of its irrigation at variable rates due to automatic adjustment of the liquid flow for irrigation depending on the gas flow by moving the needle relative to the nozzle opening with the energy of the irrigated gas acting on the blades attached to the spring-loaded nozzle. In this case, the flow rate of fluid for irrigation is substantially reduced.

Claims (1)

Gain Formula A gas irrigation nozzle comprising a vortex chamber with an inlet, a swirl and an adjustment needle, and an axial outlet nozzle the fact that in order to increase the efficiency of gas irrigation, the movement of which coincides with the direction of spraying the liquid at a variable gas flow rate, the nozzle is installed with the possibility of axial movement and rotation and is provided with a 1/1 th cylindrical spring, one end of which is fixed to the nozzle, and the other to the vortex chamber, and the nozzle is provided with aerodynamic drag in the form of blades fixed from its outer part. FIG. 2 about 2-2