SU1130383A1 - Gas cleaner - Google Patents

Abstract

1. A GAS CLEANER containing a cylindrical acoustic coagulation chamber, at one end of the second is a sound generator connected to an inlet nozzle, and on the other - a reflector and an outlet nozzle, so that In order to reduce the size of the gas scrubber and improve its efficiency, it is equipped with a tube installed in the center of the acoustic coagulation chamber along the entire length, one end of which is tightly attached to the end of the chamber, and the other side is made with openings on the side surface and installed with a gap with respect to the reflector, there is a window on the side surface of the acoustic coagulation chamber, above which there is a sound generator on the outside, made in the form of two rectangular chambers located one opposite the other, one of which is connected to the inlet nozzle; top wall, fitted with plates installed between them and the window, and on the side surface. Acoustic coagulation chambers between the windows and the reflector are made around the perimeter of the annular slots sucking suspended particles. 2. The gas scrubber of claim 1, characterized by the fact that the rectangular chambers of the evisogenerator are located at an acute angle from the end face to the longitudinal axis of the acoustic coagulation chamber. fff tS

Description

1 The invention relates to a device for cleaning gas from solid, liquid particles, which is realized in various industrial apparatuses, for example, in screw oil-filled compressors. A gas cleaning device is known that introduces a sound chamber comprising a housing, an acoustic generator, located opposite the gas inlet in the center of the end cover of the chamber and a reflector at the opposite end of the chamber, from which the gas to be purified is self-sounding in the field of standing acoustic waves, solid or liquid the particles coagulate. Inertial deposition of coagulated particles occurs between the reflector and the outlet of the C13 device. A disadvantage of the known gas scrubber is its large size due to the size of the coagulation chamber, due to the need to reduce the speed of the gas to be purified and to increase the intensity of sound vibrations. The purpose of the invention is to reduce the size of the gas scrubber and increase its efficiency in operation. The goal is achieved by the fact that a gas scrubber containing a cylindrical acoustic coagulation chamber, at one end of which a sound generator is located, is connected to the inlet pipe, and at the other end is a reflector and an outlet pipe — installed in the center of the acoustic coagulation chamber P1 of the entire length , one end of which is tightly attached to the end of the chamber, and the other is made with openings on the side surface and is installed with a gap in relation to the reflector, on the side surface of the chamber acoustic coagulation and, there is a window above which the sound generator is located on the outside, made in the form of two rectangular chambers located one opposite the other, one of which is connected to the inlet nozzle, while the rectangles of the chamber are made with a common upper wall, fitted between them, and the window a, on the lateral surface of the acoustic coagulation chamber between the window and the reflector, are provided around the entire perimeter of the suspended particles of the suspended particles. The rectangular chambers of the sound detector are located at an acute angle from the end to the longitudinal axis of the chamber of the acoustic coagule 1. Fig. I shows the proposed device, a general view; Fig.2section aa in Fig.5; in fig. 3 is a section BB in FIG. FIG. 4 is a view B of FIG. 1. FIG. The gas cleaner contains a cylindrical acoustic coagulation chamber I, closed at one end with an end cap 2, an inlet 3, a sound generator 4 consisting of two rectangular chambers 5 located opposite one another, one of which is connected to the inlet nozzle; top wall 6; Opposite to the sound generator on the side surface of the acoustic coagulation chamber there is a window 7 for tangentially entering the gas to be cleaned and sound waves into the chamber. The space between the chambers 5 and the window 7 is limited from the environment on the sides of the plates 8. At the end of the scrubber along the gas there is a reflector 9 for the formation of a standing sound wave. Between the window 7 and the reflector 9 on the lateral surface of the acoustic coagulation chamber along the entire perimeter there are slots -10 suction of suspended particles and cameras 11 and 1 and 2 that are insulated from one another. In order to increase the intensity of the sound field in the gas purifier, a right pipe 15 passes through the entire length in the center, hermetically adjacent one end to the end cap 2, its other end freely passing through the reflex Ktor, on this crest, is made holes 16 for the passage of purified gas to the outlet nozzle P. The gas scrubber operates on the next oraz. The gas to be cleaned is supplied to the inlet 3, enters the chamber 5 adjacent to it. In the space between the chambers 5 sound waves are generated, the power of which depends on the flow rate of the gas being purified, the pressure drop in the sound generator, and

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the geometric dimensions of the chambers 5 and their relative position depend on the latter factors. and oscillation frequency.

Sound waves and gas from the evukogenerator through window 7 enter tangentially into the cylindrical, acoustic coagulation chamber. The gas jet forms in the annular space a spiral flow rotating around the longitudinal axis, the suspended particles in which are thrown off by the action of centrifugal forces to the outer surface.

When multiple waves are reflected from the inner surfaces of the taco-phone and the reflector, spiral-shaped sound waves are formed over its entire length, under the action of which the gas self-resonates, suspended liquid and solid particles are enlarged and caught by slits 10, and then discharged from chambers 1I through nozzles 12 and 13. The detached gas passes from the annular space of the chamber through the holes in the central tube 16 to the outlet nozzle 17.

To ensure the effective distribution of helical sound waves along the entire length of the apparatus of the sound generator chamber 5, they are located at an acute angle with respect to the longitudinal axis of the acoustic coagulation chamber on the side of the end cap (Fig. 4). At the same time, a high intensity of sound pressure is generated at the periphery of the gas scrubber in the periphery.

Thus, in the proposed construction, the pressure on the gas to be cleaned is simultaneously subjected to acoustic pressure for coarsening particles and centrifugal forces to capture them along the entire length of the gas scrubber. In addition, to increase the time to sound the suspended particles and the intensity of the sound pressure, i.e. to improve cleaning efficiency, reduce size

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apparatus, organized B1shtoobrazny gas movement in the field of action of the spiral-shaped, which is a sound field for the entire length of the apparatus . The centrally located pipe 16 reduces the flow area dl. sound waves, thereby increasing the intensity of the sound floor with constant expenditure of pneumatic power and sound generator efficiency.

Sound generator chambers 5 are rectangular for reasons of simulating rod-type gas-jet emitters.

The proposed structure of a single-jet compressed air generator is close in its acoustic characteristics to core radiators with a large jet radius.

Improving the economical operation of the scrubber is achieved by the high absolute value of the kinetic energy of the gas flow of the gas after

25 generating sound waves in the region of sound generator chambers 5, which is not spent irretrievably on hydraulic losses, as is the case in the known device, but is used to form a vortex motor

aerosol and creating a floor of centrifugal forces. by tangential south of entering the gas flow after the sound generator into the chamber of the acoustic coagulant n. Under the influence

5 centrifugal sludge gas-suspended solid or liquid particles are thrown against the wall and removed. The organization of the vortex motion of the aerosol in the field of a helical sound field

0 also makes it possible to increase the sounding time of particles suspended in gas (an important parameter for coagulation) due to the preferential movement of particles in the peripheral, near-wall region, where the speed is lower, and the trajectory of movement of a part of the gas flow is longer compared to the average values for the entire gas flow. .

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Claims (2)

I. A gas purifier, containing a cylindrical acoustic coagulation chamber, at one end of which there is a sound generator connected to the inlet pipe, and at the other end there is a reflector and outlet pipe, which, in order to reduce the dimensions of the gas scrubber and increase its efficiency in operation, it equipped with a pipe installed in the center of the acoustic coagulation chamber along the entire length, one end of which is hermetically adjacent to the chamber end, and the other is made with holes on the side surface and is installed with a gap with respect to To the reflector, on the lateral surface of the acoustic coagulation chamber there is a window above which there is a sound generator on the outside, made in the form of two rectangular chambers located opposite one another, one of which is connected to the inlet pipe, while the rectangular chambers are made with a common upper wall are equipped with plates installed between them and the window, and on the side surface. The acoustic coagulation chamber between the window and the reflector is provided with annular slots of suction of suspended particles around the entire perimeter. 2. Gas scrubber according to π. 1, due to the fact that the rectangular chambers of the pac-Q sound generator are placed at an acute angle from the side of the tord to the longitudinal axis of the acoustic coagulation chamber. FIG. / 1·