SU912231A1 - Apparatus for coagulating aerosol particles - Google Patents

Description

The invention relates to the purification of gases from dust - and can be used in non-ferrous metallurgy, in the building materials industry.

A device is known for the coagulation of solid or liquid particles contained in process gases, including a sound generator connected to the gas inlet and located in the upper lid of the chamber, and a reflector designed to reflect oscillations and create a standing wave in the sound chamber. The specified reflector is fixedly mounted in the bottom cover of the camera 1 3.

The main disadvantage of the known device is the impossibility of adjusting it to the standing wave mode and keeping it in operation.

A device for coagulating aerosols is known, which contains sound generators in the upper part, and a resonator plate in the lower part, designed to reflect sound vibrations and create a standing wave mode 2.

In the known coagulation chamber, the position of the resonator plate relative to the oscillators to create the standing wave mode is determined by calculation, and for given parameters of the acoustic field this distance is taken as a multiple of the integer, the number of half-waves. However, to maintain the specified pressure of compressed air, the parameters of the acoustic the floor

10 is extremely difficult due to the variable load on the network of compressors (input or output of units which are compressed air consumers). Pressure change

15 compressed air supplied to the generator leads to a change in the frequency of the acoustic field, resulting in a stationary resonator. plate is a violation of the regime

20 standing waves, which significantly reduces the efficiency of coagulation of aerosols. Reducing the efficiency of coagulation leads to a decrease in the size of aggregates of aerosol particles, 25 and, consequently, the efficiency of subsequent dust collection.

The aim of the invention is to increase the efficiency of aero30 coagulation. sols by continuously maintaining the standing wave mode.

To achieve this goal, a device for coagulating aerosol particles, containing a coagulation chamber with sound generators and a resonator plate, is provided with an oscillation receiver and an actuator, and the resonator plate is axially displaced and connected via an actuator to an oscillation receiver installed along the coagulum axis camera.

The drawing shows a device for coagulating aerosol particles, a general view.

The device contains a coag-storage chamber 1 and a bunker 2. In the upper part of the coagulation chamber there is a sound generator 3, and in the lower part there is a resonator plate 4 connected by a rod 5 with an actuating mechanism 6. Dust gas is supplied through a tangential nozzle 7, and the output is through the pipe 8. The actuator is connected to the receiver 9 oscillations located along the axis of the chamber.

A device for coagulating aerosol particles works as follows.

Before starting work in the absence of a gas load, the coagulation chamber is tuned to rest

waves, performed

by moving the resonator plate 4, actuated by the actuator 6. The signal at the end of tuning is the value of the electrical impulse from the sound oscillator 9, which in the standing wave mode has the maximum value. This value is hereinafter a determining parameter when setting up a coagulation chamber. The dusty gas is supplied to the chamber through the tangential nozzle 7. Here, due to centrifugal separation, the largest fractions of dust are separated, which is deposited in the bunker 2. Subjected to intense acoustic oscillations created by the generator 3, the dust particles coagulate, forming large aggregates. The gas containing the aggregated aerosol through the pipe 8 enters the dust-collecting apparatus. When the pressure of the compressed air, which is applied to the sound generator, changes, the frequency of the sound field in the chamber changes.

which leads to violation of the standing wave regime. The consequence of this violation is a change in the magnitude of the electrical pulse from the receiver 9, which causes the actuator b to move the resonator plate 4 until the value of the electrical pulse equals the maximum value corresponding to the standing mode.

waves in the coagulation chamber.

Before the start of the experiment, the camera is set to

one hundred

waves by adjusting the position of the generator located at the top of the chamber. However, the period of operation due to fluctuations in the pressure of the compressed air, the acoustic field parameters in the oscillating chamber change, which leads to disruption of the standing wave mode. Since the parameters of the dust and gas flow in a series of experiments have approximately the same values,

(up to 60%) is explained precisely by the violation of the standing wave mode in the coagulation chamber.

Testing devices show that dust collection efficiency

fluctuates between 60-75%, while there are also observed fluctuations in the magnitude of the pressure of compressed air supplied from a sound generator, from 3 to 5.4 atm.

Claims (2)

1. USSR author's certificate No. 380336, cl. On 01 D 51/08, 1973, 2. The patent of Great Britain W1419823, cl. On 01 D 5/08, 1975.