RU1814925C - Electrostatic sprayer - Google Patents

Abstract

The invention relates to the field of high voltage engineering, in particular, electron-ion technology. The goal is to obtain a multicomponent charged aerosol. The electrostatic atomizer contains a housing with an induction and a grounded electrode installed in it, made with an axial through hole connected at the outlet to the gas supply source, an annular spray nozzle communicating with the surfaces of the inducing and grounded electrodes communicating with the liquid supply channels and covering the latter gas supply channel. The electrostatic sprayer is equipped with an additional fluid supply pipe fixed in the housing, the output end of which is connected to the cavity of the through hole of the grounded electrode. 1 ill. 1 Z

Description

 The invention relates to the field of high voltage engineering, in particular, electron-ion technology, and can be used in industry to reduce dust levels in workrooms, in agriculture for combating plant diseases and pests, for vaccinating animals .

The aim of the invention is to obtain a multicomponent charged aerosol

The drawing shows the proposed electrostatic atomizer in a longitudinal / ib-section.

The electrostatic atomizer comprises a dielectric housing 1. An annular atomizing nozzle is formed by the facing surfaces of the inducing 2 and grounded 3 electrodes. Spray gas flow

is carried out through the channel 4, the liquid is supplied through the longitudinal holes 5 made in the holder 6 of the grounded electrode 3. Only well-conducting liquid is supplied through these holes. The axial through hole in the grounded electrode 3 is connected to the gas supply pipe. A pipe 8 for additional fluid supply passes through the housing 1 and is fixed in this housing. The holder 6 is also fastened in the housing 1. The pipe 8, with its outlet end, opens into the gas supply pipe 7, i.e. the output end of the nozzle 8 is in communication with the cavity of the through hole of the grounded electrode 3. High voltage to the induction electrode 2 is supplied from the high voltage power supply 9.

. The electrostatic atomizer operates as follows. Sprayed

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liquid (well-conducting components) is supplied through the longitudinal holes 5 and flows to the surface of the grounded electrode 3 in the form of a film. Interacting with the high-speed gas stream supplied through channel 4, it is crushed by the pelvis into droplets. Since crushing occurs in the interelectrode gap of the annular nozzle in an electric field, which is created by applying a high voltage from source 9 to induction electrode 2, the resulting droplets are obtained electrically charged. The dielectric fluid components are supplied through the nozzle 8 and exit to the inside of the nozzle 7. Caught up and crushed by the gas stream inside the nozzle 7, they enter small droplets into the outer zone of the atomizer. Interacting with highly charged drops of well-conducting components of the sprayed liquid, drops of dielectric components are captured by them, as a result of which a multicomponent charged aerosol is formed.

Practice has shown that dielectric components make up a significantly smaller proportion of the atomized liquid. The main part is composed of well-conducting components. Therefore, when the droplets merge, the contribution of the dielectric components to the total mass of the sprayed liquid is insignificant, as a result of which the transferred specific charge of the multicomponent aerosol flow is quite high.

If the flow rate of the dielectric components increases and the air supplied through the pipe 7 is insufficient to crush them, then the electrostatic atomizer operates as follows. The additional gas supply to the pipe 7 is stopped. Inside the pipe 7, only the dielectric fluid enters through the pipe 8. It is known that when sawing a liquid behind the end of a grounded electrode, a stagnation zone is formed (as shown by experiments, a zone of reduced pressure). The liquid entering the nozzle 7 therefore flows through a through hole in the grounded electrode 3 to its end outer surface. Rasteka smiling

along it, the liquid reaches the edge of the grounded electrode 3 and is sprayed from it by the main gas-dynamic flow together with the charged well-conducting components, forming a multicomponent charged aerosol. It should be noted that in the presence of a stagnant zone, the total discharged electric charge is slightly less than in the absence of it (when there is a gas supply through pipe 7).

However, even in this case, the specific charge transferred is higher than in the case of charging the entire dispersible mixture directly in the annular nozzle of the atomizer. .: ..,:. Thus, from the foregoing

it follows that the proposed electrostatic atomizer in comparison with the prototype allows to obtain a multi-component well-charged aerosol, which is very important for the practical needs of industry and agriculture.

The formula is also invented for an electrostatic atomizer, comprising a housing with an induction electrode and a grounded electrode installed in it, made with an axial through hole communicated at the inlet with a gas supply source, and an annular spray nozzle communicating with one another by the surfaces of the induction and grounded electrodes communicating with fluid supply channels and the last supply channel surrounding

gas, characterized in that, in order to obtain a multicomponent charged aerosol, the atomizer is equipped with an additional liquid supply nozzle secured in the .. casing, the outlet end of which is connected to the cavity of the through hole of the grounded electrode ... , -. -,