阅读说明：本技术 一种介质微孔道放电处理工业废盐中的有机物的处理装置 (Device for treating organic matters in industrial waste salt through dielectric micro-channel discharge ) 是由 王小平 龚云姜 于 2020-05-21 设计创作，主要内容包括：本发明公开了一种介质微孔道放电处理工业废盐中有机物的装置,其特征在于：放电组件和微孔道。本装置主要由：高压电极(11)、进气口(14)、腔体(13)、介质(9)、工业废盐层(8)、腔体(7)、固定支(6)、介质(5)、腔体(4)、地极(3)、出气口(2)组成的低温等离子体反应器,高压电极(11)通过导线(12)与高压电源连接,地极(3)通过导线(1)与地线相连接。本装置可有效降解和去除工业废盐中的有机物,可在不同种类气体、不同的气压下等条件下进行,具有效率高、工艺流程简单、操作方便等优点。(The invention discloses a device for treating organic matters in industrial waste salt by medium micro-channel discharge, which is characterized in that: a discharge assembly and a microchannel. The device mainly comprises: the low-temperature plasma reactor comprises a high-voltage electrode (11), an air inlet (14), a cavity (13), a medium (9), an industrial waste salt layer (8), a cavity (7), a fixed support (6), a medium (5), a cavity (4), a ground electrode (3) and an air outlet (2), wherein the high-voltage electrode (11) is connected with a high-voltage power supply through a lead (12), and the ground electrode (3) is connected with a ground wire through a lead (1). The device can effectively degrade and remove organic matters in the industrial waste salt, can be carried out under the conditions of different gases, different air pressures and the like, and has the advantages of high efficiency, simple process flow, convenient operation and the like.)

1. The device for treating organic matters in industrial waste salt through medium micro-channel discharge is characterized by comprising a low-temperature plasma reactor consisting of a lead (1), an air outlet (2), a ground electrode (3), a cavity (4), a medium (5), a fixing support (6), a cavity (7), an industrial waste salt layer (8), a medium (9), a micro-channel (10), a high-voltage electrode (11), a lead (12), a cavity (13) and an air inlet (14), wherein the high-voltage electrode (11) is connected with a high-voltage power supply through the lead (12), and the ground electrode (3) is connected with a ground wire through the lead (1).

2. The apparatus for treating a dielectric microchannel discharge as set forth in claim 1, wherein: the medium (9) is made of an insulating material and comprises a plurality of micro channels.

3. The apparatus for treating a dielectric microchannel discharge as set forth in claim 1, wherein: the diameter of the microchannel (10) is less than 100 um.

4. The apparatus for treating a dielectric microchannel discharge as set forth in claim 1, wherein: the medium (9) and the medium (5) can adopt quartz, ceramics and polytetrafluoroethylene.

5. The apparatus for treating a dielectric microchannel discharge as set forth in claim 1, wherein: the earth electrode (3) can adopt a sheet, a net or a ring-shaped conductive material.

6. The apparatus for treating a dielectric microchannel discharge as set forth in claim 1, wherein: the medium (9) is disc-shaped.

7. The apparatus for treating a dielectric microchannel discharge as set forth in claim 1, wherein: the high-voltage electrode (11) is a metal plate with uniform holes, and the shapes of the holes can be circular, rhombic, square and rectangular.

8. The apparatus for treating a dielectric microchannel discharge as set forth in claim 1, wherein: the medium (5) has a smaller diameter than the medium (9).

Technical Field

The invention belongs to the technical field of solid waste treatment, and particularly relates to a device for treating organic matters in industrial waste salt through dielectric micro-channel discharge treatment.

Background

The industrial waste salt is inevitably generated in chemical production, the yield of the industrial waste salt is hundreds of millions of tons every year in China nowadays, the industrial waste salt is listed as dangerous waste in 2016, and the problem of treatment of the industrial waste salt is the bottleneck problem of development of many enterprises. At present, the research on the treatment technology of industrial waste salt is less at home and abroad, and the types and the amounts of impurities contained in the industrial waste salt are different, so that the wide application of a certain technology is limited to a certain extent. At present, most of industrial waste salt is subjected to landfill treatment, and on one hand, certain environmental risks exist in the landfill treatment, and pollutants always exist; on the other hand, the method is not in accordance with the concept of sustainable development, cannot realize recycling, and industrial salt is a strategic material of the country, so that the recovery and resource utilization of industrial waste salt are urgent matters. The treatment technology of industrial waste salt at present mainly comprises a high-temperature treatment method, an alkali preparation method, a salt washing method, an oxidation method and treatment by dissolving in water. The high-temperature treatment method of industrial waste salt can be divided into pyrolysis and combustion according to the gas atmosphere, and also comprises a grading carbonization method, and the waste salt is easy to harden after high-temperature treatment, so the method is combined with a fluidized bed technology, namely the fluidized bed high-temperature treatment technology; the alkali making method realizes industrial recycling to a certain extent, but the purity after treatment is not high; the salt washing method has limited capacity for treating waste salt, and the washed solution needs further treatment, so the method is generally suitable for pretreatment; the oxidation method is to rapidly oxidize and decompose organic matters in industrial waste salt by using an oxidant, but has a risk of introducing new impurities into a solution; dissolving industrial waste salt into water to treat the salt-containing wastewater, wherein the salt-containing wastewater is treated by a membrane treatment method, an activated sludge method and other technologies. Therefore, more methods and techniques for treating organic matters in industrial waste salt need to be found.

The low-temperature plasma technology is a novel advanced oxidation technology, integrates multiple actions of free radical oxidation, ozone oxidation, ultraviolet photolysis, high-energy electron bombardment, supercritical effect, local thermal effect and the like, and the traditional low-temperature plasma treatment technology comprises dielectric barrier discharge, corona discharge, sliding arc discharge and the like. Low-temperature plasma is gradually applied to environmental treatment in recent years, and low-temperature plasma treatment technology is gradually reported for wastewater, soil, gas and solid waste. The principle of plasma treatment of organic matter under gas phase conditions is now widely accepted as: under the action of an electric field, electron avalanche is generated, then active ions with strong oxidizing property such as hydroxyl radicals, ozone, hydrogen peroxide and the like are generated, the active ions and organic matters are subjected to oxidation reaction to degrade and remove the organic matters, and simultaneously, the decomposition and removal of the organic matters are promoted under the actions of heat radiation, ultraviolet radiation and the like. The medium discharge has the characteristics of high generation efficiency of active substances, low energy consumption, simple operation, high reaction rate, stable work and the like, thereby having wide application prospect and application value. The production rate of plasma active substances generated by the traditional dielectric barrier discharge is limited by the temperature of a discharge environment, and if the temperature of the discharge environment is too high, the decomposition rate of the active substances generated by the discharge in a discharge space is too high, so that the problems of reduction of the degradation rate and the removal rate of organic matters in industrial waste salt and the like can be caused.

Disclosure of Invention

At present, the treatment technology of industrial waste salt is relatively few, the treatment technology and the treatment device are still needed to be researched and developed, and the invention provides the industrial waste salt treatment device for medium micro-channel discharge.

The invention provides an industrial waste salt treatment device for medium micro-channel discharge, which is characterized in that: the low-temperature plasma reactor comprises a high-voltage electrode (11), an air inlet (14), a cavity (13), a medium (9), an industrial waste salt layer (8), a cavity (7), a fixed support (6), a medium (5), a cavity (4), a ground electrode (3) and an air outlet (2), wherein the high-voltage electrode (11) is connected with a high-voltage power supply through a lead (12), the ground electrode (3) is connected with a ground wire through a lead (1), and a plurality of uniform microchannels are formed in the medium (9).

By adopting the scheme, when the high-voltage electrode works, the high-voltage electrode (11) is connected with a high-voltage power supply through a lead (12), the high-voltage electrode (11) is insulated and blocked by an insulating medium (9), and gas discharge is carried out on a medium micro-channel under the action of an electric field, and the working characteristics of the high-voltage electrode are analyzed as follows:

firstly, when organic matters in the industrial waste salt layer (8) are treated, the high-voltage electrode (11) realizes micro-channel discharge on the insulating medium (9).

Secondly, gas enters the cavity (13) through the gas inlet (14), when the gas passes through the micro-channel (10), gas-phase discharge is realized in the micro-channel, the yield of active substances can be improved, the gas can uniformly enter an industrial waste salt layer, and the removal rate of organic matters in the industrial waste salt is improved.

And thirdly, during discharging, dielectric pore channel discharging is realized in the high-voltage electric field by the insulating medium (9), and the discharging process after dielectric blocking of the insulating medium (5) has the advantages of short pulse delay, wide applicable voltage frequency range, strong adaptability and the like.

Fourthly, when the gas enters the micro-channel (10) from the cavity (13) and then enters the industrial waste salt layer (8), the air cooling of the medium (9) and the micro-channel (10) can be realized, the yield of active substances is improved, and the treatment efficiency of organic matters in the industrial waste salt is improved.

Furthermore, the medium (9) is made of an insulating material, and the electric field penetrates through the micropores due to the fact that the medium (9) is insulating, so that the effect of collecting the electric field is achieved, the initial voltage of discharging is reduced, the utilization rate of energy is improved, and the operation cost is reduced.

Further, the method is carried out. The diameter of the microchannel (10) is less than 100 um.

Further, the medium (9) and the medium (5) can adopt any one of quartz, ceramics and polytetrafluoroethylene.

Further, the high-voltage electrode (11) and the ground electrode (3) can adopt a sheet-shaped, net-shaped or annular conductive material.

Further, the insulating medium (9) is disc-shaped.

The invention has the beneficial effects that:

firstly, when organic matters in industrial waste salt in the device are treated, the insulating medium (9) discharges gas in the micro-channels (10) in the medium (9) in a high-voltage electric field.

Secondly, when the gas enters the cavity (13) from the gas inlet (14) and passes through the micro-channel (10), the gas is discharged in the micro-channel (10), so that the yield of the active substance can be improved, and the removal of organic matters in industrial waste salt is facilitated. The micro-channels are uniformly distributed on the medium (10), and the gas can more uniformly enter the industrial waste salt layer (8) so as to solve the problem of non-uniform mass transfer of the plasma gas.

Thirdly, when the invention discharges, the insulating medium (9) carries out micro-channel gas-phase discharge in a high-voltage electric field, and after being blocked by the insulating medium (5), the discharge process has the advantages of short pulse delay, wide applicable voltage frequency range, strong adaptability and the like.

Fourthly, when the gas enters the micro-channel (10) from the cavity (13) and then enters the industrial waste salt layer (8), the discharging area of the medium (9) and the micro-channel (10) can be cooled by wind, the yield of active substances is improved, and the treatment efficiency of organic matters in the industrial waste salt is improved.

Fifthly, the medium (9) is insulated, so that the electric field can only penetrate through the micropores, the effect of collecting the electric field is achieved, the discharge voltage is reduced, the energy utilization rate is improved, and the operation cost is reduced.

Drawings

FIG. 1 is a schematic view of the structure of the present invention

FIG. 2 is a schematic representation of a media containing microchannels according to the present invention

FIG. 3 is a schematic diagram of a high voltage electrode of the present invention

In the figure: 1. the device comprises a lead 2, an air outlet 3, a ground electrode 4, a cavity 5, a medium 6, a fixing support 7, a cavity 8, an industrial waste salt layer 9, a medium 10, a micro-channel 11, a high-voltage electrode 12, a lead 13, a cavity 14 and an air inlet.

Detailed Description

As shown in fig. 1, the apparatus is composed of: the low-temperature plasma generator comprises a high-voltage electrode (11), an air inlet (14), a cavity (13), a medium (9), a cavity (7), an industrial waste salt layer (8), a medium (5), a fixed support (6), a low-voltage electrode (3), a cavity (4), an air outlet (2) and a lead (1); the high-voltage power supply connected with the lead (12) adopts an alternating-current high-voltage power supply, the high-voltage electrode (11) adopts a metal net, the industrial waste salt (8) is placed on the medium (9), and the metal high-voltage electrode net is tightly attached to the lower surface of the medium (9). The earth electrode (3) is connected with the earth wire through a lead (1), an alternating current high-voltage power supply supplies power to the high-voltage electrode (11) through a lead (12), carrier gas enters a cavity (13) from an air inlet (14), then a micro-channel (10) enters an industrial waste salt layer (8), and the carrier gas enters the micro-channel (10)Generating active particles (OH, H, O) by gas discharge₃Etc.) enters the industrial waste salt layer to contact with organic matters in the industrial waste salt layer to generate oxidation reaction, so that the organic matters are degraded and removed, and finally the organic matters are discharged through the air outlet (2) along with the carrier gas through the cavity (4).

When the device works, the working characteristics are as follows:

firstly, when organic matters in the industrial waste salt are treated in the device, the carrier gas enters the industrial waste salt layer (8) after passing through the micro-channels (10) and has a certain stirring effect on the industrial waste salt, so that the gas can be better contacted with the industrial waste salt, and therefore active particles generated in the micro-channels (10) can be better contacted and reacted with the organic matters in the industrial waste salt, and the decomposition efficiency is improved.

Secondly, when the device is in discharge operation, gas discharge is carried out in the micro-channel of the insulating medium (9) through the insulating medium (9), and the process after the discharge is blocked by the insulating medium (5) has the advantages of short pulse delay, wide applicable voltage frequency range and the like.

Thirdly, the carrier gas passes through the microchannel (10) from the cavity (13) and the discharge region is in the microchannel, so that cooling of the medium (9) and the discharge region can be achieved, and the production efficiency and survival time of the active material can be improved.

Fourthly, because the medium (9) is insulated, the electric field can only penetrate through the micro-channel, so that the effect of collecting the electric field is achieved, the initial voltage of discharge is reduced, the utilization rate of energy is improved, and the operation cost is reduced.

The embodiments of the present invention have been described above in detail. It should be understood that numerous modifications and variations could be devised by those skilled in the art in light of the present teachings without departing from the inventive concepts. Therefore, the technical solutions available to those skilled in the art through logic analysis, reasoning and limited experiments in the prior art according to the concept of the present invention should be within the scope of protection defined by the claims.