CN115353174A - Plasma active water generating device and active water generating method - Google Patents

Abstract

A plasma active water generating device and an active water generating method belong to the technical field of plasma active water production equipment. The water inlet of each plasma generation assembly is communicated with a water inlet device, and the water outlet of each plasma generation assembly is communicated with an active water collecting device; the water seepage component and the outer electrode (10) are arranged at intervals, the water seepage part of the water seepage component is higher than the outer electrode (10), one electrode of the power supply (8) is connected with the outer electrode (10), and the other electrode is communicated with water seeped from the water seepage part. The plasma active water generating device discharges between water and the outer electrode directly, ensures good ionization effect on water, ensures more stable and uniform ionization on water, has high content of active ingredients in ionized water, and has good sterilizing effect on active water produced by the active water generating device; the water of the active water generation method is used as an ionization electrode, the ionization effect between the active water and the outer electrode is good, and the ionization efficiency is high.

Description

Plasma active water generating device and active water generating method

Technical Field

A plasma active water generating device and an active water generating method belong to the technical field of plasma active water production equipment.

Background

The plasma active water can kill microorganisms in various water sources, has a certain optimization effect on water quality, can promote reaction while improving the cleaning efficiency, and achieves the purpose of saving water. Plasma activated water is usually produced by ionization, i.e. water flows between two electrodes, and active water is produced by electric discharge between the two electrodes, but the existing plasma activated water production equipment has the following problems: because water is ionized between the two electrodes, only part of water is ionized, the ionization of the water is not uniform, and the content of active ingredients in the water is low, so that the sterilization efficiency of the active water is low.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the defects of the prior art are overcome, and the plasma active water generating device and the plasma active water generating method which are stable in water ionization and high in active ingredient content in ionized active water are provided.

The technical scheme adopted by the invention for solving the technical problems is as follows: the plasma active water generating device is characterized in that: the plasma generating device comprises a water inlet device, an active water collecting device and a plurality of plasma generating assemblies, wherein the water inlet of each plasma generating assembly is communicated with the water inlet device, and the water outlet of each plasma generating assembly is communicated with the active water collecting device;

the plasma generating assembly comprises a power supply, an outer electrode and a water seepage assembly, the water seepage assembly and the outer electrode are arranged at intervals, the water seepage portion of the water seepage assembly is higher than that of the outer electrode, one electrode of the power supply is connected with the outer electrode, and the other electrode is communicated with water seeped out of the water seepage portion.

Preferably, water installations and active water collection device from top to bottom set gradually, plasma generation subassembly sets up between water installations and active water collection device.

Preferably, the water inlet device is a water inlet tank, and the water inlet tank is higher than the plasma generation assembly; the active water collecting device is an active water tank which is lower than the plasma generating assembly.

Preferably, the plasma generator further comprises a bearing cylinder, the diameter of the upper part of the bearing cylinder is larger than that of the lower part of the bearing cylinder, the bearing cylinder is arranged on the lower side of each plasma generating assembly, and the bottom of each bearing cylinder is communicated with the active water collecting device.

Preferably, the plasma generation assembly further comprises an insulating cylinder, the insulating cylinder is sleeved outside the water seepage assembly at intervals, and the outer electrode is arranged around the insulating cylinder.

Preferably, the plasma generating assembly further comprises an exhaust gas treatment device, and the exhaust gas treatment device is communicated with the insulating cylinder.

Preferably, the device also comprises a gas collecting pipe, and the gas inlet of the gas collecting pipe is communicated with each waste gas treatment device.

Preferably, the infiltration subassembly include ceramic membrane and isolation plywood, the ceramic membrane is cylindric, and the isolation plywood sets up in the ceramic membrane, keeps apart plywood and ceramic membrane inner wall sealing connection to form at the upside of keeping apart the plywood infiltration portion, the outer electrode encircles the ceramic membrane setting.

Preferably, the plasma generator further comprises a cooling device, and the cooling device is arranged outside each plasma generating assembly.

An active water generation method of the plasma active water generation device is characterized in that: the method comprises the following steps:

water in the water inlet device enters each plasma generating assembly;

after the water in the plasma generating assembly extends out of the water seepage part, the water flows downwards along the inner wall of the water seepage assembly;

two electrodes of the power supply are respectively communicated with the seeped water and the outer electrode, and when water on the outer wall of the water seepage component flows through the outer electrode, the water is directly ionized with the outer electrode to generate active water;

the produced active water enters an active water collecting device.

Compared with the prior art, the invention has the beneficial effects that:

an electrode of this plasma active water generating device's power communicates with the water that the infiltration subassembly oozes, the other end communicates with the outer electrode, the water that the portion of seeping seeps flows down along the infiltration subassembly, because the speed of infiltration portion infiltration is slow, can make the water that oozes flow down through the outer wall of infiltration subassembly, water is little at the thickness of the subassembly outer wall that seeps, and water itself is electrified, water is as an electrode of ionization, discharge between water directness and the outer electrode, guarantee that the ionization effect to water is good, and it is more stable, even to the ionization of water, the aquatic active ingredient's after the ionization content is high, the bactericidal effect of the active water of producing through this active water generating device is good.

The active water generating method can generate ionization between the water and the outer electrode only when the water flows to the outer electrode positive pair along the outer wall of the water seepage component, the water is used as an ionized electrode, the ionization effect between the water and the outer electrode is good, the ionization efficiency is high, and the ionization stops immediately when no water exists between the water seepage component and the outer electrode, so that the ionization efficiency can be improved, and the energy utilization rate can be improved.

Drawings

Fig. 1 is a front sectional view of a plasma activated water generating apparatus.

Fig. 2 is a front cross-sectional schematic view of a plasma generation assembly.

Fig. 3 is a partially enlarged view of a portion a in fig. 2.

Fig. 4 is a schematic top view of a plasma generating assembly.

In the figure: 1. the gas-liquid separation device comprises a fixing cap 101, a water inlet 102, an outward flanging 103, a mounting groove 2, an inner electrode connecting wire 3, an inner electrode water cavity 4, an insulating cylinder 5, an outer cover 6, a ceramic membrane 601, a mounting part 7, an isolation layer plate 8, a power supply 9, a threading pipe 10, an outer electrode 11, a discharge region 12, an air inlet pipe 13, an air outlet pipe 1301, an air outlet hole 14, a water inlet tank 15, an active water tank 16, a communicating pipe 17, an air collecting pipe 18, a receiving cylinder 19 and a purging pipe.

Detailed Description

The present invention will be further described with reference to specific embodiments, however, it should be understood by those skilled in the art that the detailed description given herein with respect to the drawings is for better explanation and that the present invention is necessarily limited to those embodiments, and that equivalents and common means not specifically described herein are nevertheless deemed to be within the scope of the present application.

FIG. 1~4 is a preferred embodiment of the present invention, which is further described below in conjunction with 1~4.

A plasma active water generating device comprises a water inlet device, an active water collecting device and a plurality of plasma generating assemblies, wherein the water inlet of each plasma generating assembly is communicated with the water inlet device, and the water outlet of each plasma generating assembly is communicated with the active water collecting device; the plasma generation assembly comprises a power supply 8, an outer electrode 10 and a water seepage assembly, the water seepage assembly and the outer electrode 10 are arranged at intervals, a water seepage part of the water seepage assembly is higher than that of the outer electrode 10, one electrode of the power supply 8 is connected with the outer electrode 10, and the other electrode is communicated with water seeped from the water seepage part. This plasma active water generating device's a power 8's an electrode and the water that seeps of infiltration subassembly switch on, the other end switches on with outer electrode 10, the water that seeps of infiltration portion flows downwards along the infiltration subassembly, because the speed of infiltration portion infiltration of infiltration is slow, can make the water that seeps flow downwards through the outer wall of infiltration subassembly, water is little at the thickness of infiltration subassembly outer wall, and water itself is electrified, water is as an electrode of ionization, discharge between water directness and the outer electrode 10, guarantee that the ionization effect to water is good, and it is more stable, even to the ionization of water, the aquatic active ingredient's content after the ionization is high, the bactericidal effect of the active water of producing through this active water generating device is good.

Specifically, the method comprises the following steps: as shown in fig. 1: the water inlet device is arranged on the upper side of the active water collecting device, the plasma generating assemblies are arranged between the water inlet device and the active water collecting device, and in the embodiment, the plasma generating assemblies are connected in parallel to form two plasma generating assemblies.

In this embodiment, the water inlet device is a water inlet tank 14, the active water collecting device is an active water tank 15, the top of each plasma generating assembly is communicated with the water inlet tank 14, and the bottom is communicated with the active water tank 15.

The plasma active water generating device further comprises a bearing cylinder 18 and a purging pipe 19, the bearing cylinder 18 is arranged on the lower side of each plasma generating assembly, the diameter of the upper portion of each bearing cylinder 18 is larger than that of the lower portion of each bearing cylinder, the bearing cylinders 18 are arranged right below the corresponding plasma generating assemblies and bear active water produced by the plasma generating assemblies, the bottoms of the bearing cylinders 18 are communicated with the active water tank 15, and the borne active water is sent into the active water tank 15 to be stored. All be connected with on each socket 18 and sweep pipe 19, can sweep the ozone that produces in the subassembly through sweeping pipe 19 to the plasma takes place to concentrated processing avoids causing the pollution to the environment.

As shown in figure 2~4: the plasma generating component further comprises an insulating cylinder 4, the insulating cylinder 4 is a cylinder with the upper end and the lower end both open, and the insulating cylinder 4 is made of inorganic materials. The water seepage component comprises a ceramic membrane 6 and an isolation layer plate 7, the ceramic membrane 6 is cylindrical, the top of the ceramic membrane 6 is open, the bottom of the ceramic membrane 6 is closed, and the bottom of the ceramic membrane 6 is hemispherical with the middle part protruding downwards so that ionized active water can flow down from the bottom of the ceramic membrane 6 conveniently. The diameter of the ceramic membrane 6 is smaller than that of the insulating cylinder 4, the ceramic membrane 6 is coaxially arranged in the insulating cylinder 4, a flow channel for water to flow is formed between the ceramic membrane 6 and the insulating cylinder 4, the isolation layer plate 7 is disc-shaped, the isolation layer plate 7 is arranged in the ceramic membrane 6, the isolation layer plate 7 is arranged in the middle of the ceramic membrane 6, the side part of the isolation layer plate 7 is in sealing connection with the inner wall of the ceramic membrane 6, the inner electrode water cavity 3 is formed in the inner cavity of the upper part of the ceramic membrane 6, and a water seepage part is formed in the upper part of the ceramic membrane 6. The outer electrode 10 is arranged around the lower part of the insulation cylinder 4, the outer electrode 10 is spiral and arranged along the insulation cylinder 4, the outer electrode 10 is arranged on the lower side of the isolation layer plate 7, and the area of the flow channel corresponding to the outer electrode 10 is a discharge area 11. It is also possible to provide only the ceramic membrane 6 without the insulating cylinder 4.

The water penetration member may also be a plate-shaped ceramic membrane 6, and the external electrodes 10 are provided at one side of the plate-shaped ceramic membrane 6, and water penetrates to the other side through the ceramic membrane 6.

The plasma generating assembly further comprises a fixing cap 1, the fixing cap 1 is a cylinder with a closed top, an installation part 601 is arranged at the top of the ceramic membrane 6, the installation part 601 extends into the fixing cap 1 and is connected with the fixing cap 1 in a sealing mode, a water inlet 101 is formed in the top of the fixing cap 1, and the water inlet 101 is communicated with the inner electrode water cavity 3.

An outward flange 102 is arranged around the bottom of the fixing cap 1, and the top of the insulating cylinder 4 extends into the flange 102 and is connected with the flange 102 in a sealing manner.

The plasma generation assembly further comprises cooling means arranged around the insulating cylinder 4. The cooling device comprises an outer cover 5, the outer cover 5 is sleeved outside the insulating cylinder 4, the outer cover 5 and the insulating cylinder 4 are arranged at intervals, a cooling cavity is formed between the insulating cylinder 4 and the outer cover 5, the bottom of the outer cover 5 is connected with the bottom of the insulating cylinder 4 in a sealing mode, and the top of the outer cover 5 extends into the flanging 102 and is connected with the flanging 102 in a sealing mode. The bottom of the outer cover 5 is provided with an air inlet pipe 12, and the air inlet pipe 12 is communicated with the cooling cavity.

The bottom of the flanging 102 of the fixing cap 1 is provided with two concave mounting grooves 103, the top of the insulating cylinder 4 and the top of the outer cover 5 extend into the mounting grooves 103 and are connected with the fixing cap 1 in a sealing mode.

Plasma takes place still includes exhaust treatment device at the subassembly, and exhaust treatment device includes outlet duct 13, and outlet duct 13 sets up at the top of insulating cylinder 4, and the one end and the 4 inner chambers of insulating cylinder of outlet duct 13 communicate, and the other end passes dustcoat 5 and outwards stretches out, and sealed the setting between dustcoat 5 and the outlet duct 13 is provided with the venthole 1301 with cooling chamber intercommunication on the outlet duct 13, makes outlet duct 13 communicate with insulating cylinder 4 and dustcoat 5 simultaneously.

The middle part of the outer cover 5 is provided with a threading pipe 9, one electrode of the power supply 8 is connected with an outer electrode 10 through a lead which passes through the threading pipe 9, the other electrode of the power supply 8 is connected with an inner electrode connecting wire 2, and the inner electrode connecting wire 2 extends into the inner electrode water cavity 3 and is communicated with water in the inner electrode water cavity 3.

As shown in fig. 1 and 2: the plasma active water generating device further comprises a gas collecting pipe 17, in the embodiment, the gas collecting pipe 17 is a three-way pipe, two gas inlets of the gas collecting pipe 17 are connected with corresponding gas outlet pipes 13 through communicating pipes 16, and a gas outlet of the gas collecting cylinder 17 is connected with gas treatment equipment.

An active water generating method of the plasma active water generating device comprises the following steps:

the water in the water inlet device enters each plasma generation assembly.

Specifically, the water to be ionized is contained in the water inlet tank 14, and the water in the water inlet tank 14 freely flows into the inner electrode water cavity 3 of each plasma generation assembly. The method is characterized in that common water is adopted, and the common water has certain conductivity.

The water in the plasma generating assembly flows downwards along the inner wall of the water seepage assembly after extending out of the water seepage part.

Specifically, water in the inner electrode water cavity 3 flows downwards along the outer wall of the ceramic membrane 6 after seeping out of the outer wall of the ceramic membrane 6 on the upper side of the isolation layer plate 7, and the thickness of the water on the outer wall of the ceramic membrane 6 is small due to the fact that the water seepage speed of the outer wall of the ceramic membrane 6 is low.

Two electrodes of the power supply 8 are respectively communicated with the seeped water and the outer electrode 10, and when the water on the outer wall of the water seepage component flows through the outer electrode 10, the water is directly ionized with the outer electrode 10 to generate active water.

Specifically, one motor of the power supply 8 is communicated with water in the inner electrode water cavity 3, the other electrode is communicated with the outer electrode 10, the seeped water flows downwards along the inner wall of the ceramic membrane 6, and when the seeped water flows to the discharge area 11 corresponding to the outer electrode 10, the water is used as the inner electrode and is ionized with the outer electrode 10, so that the ionization of the water is more stable and uniform, and the content of active ingredients in the ionized water is high.

In the ionization process, part of ozone is generated, and negative pressure is pumped through the air outlet pipe 13, so that part of ozone gas generated in the insulating cylinder 4 can be pumped away and concentrated, and the environment pollution is avoided. Cooling air is introduced into the outer cover 5 through the air inlet pipe 12, enters the air outlet pipe 13 through the air outlet hole 1301, and is discharged through the air outlet pipe 13, so that the insulating cylinder 4 is cooled. The housing 5 is preferably a transparent housing.

The produced active water enters an active water collecting device.

The ionized active water continuously flows downwards along the outer wall of the ceramic membrane 6, drops into the receiving cylinder 18 through the bottom of the ceramic membrane 6 and enters the active water tank 15 through the receiving cylinder 18.

The foregoing is directed to preferred embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow. However, any simple modification, equivalent change and modification of the above embodiments according to the technical essence of the present invention are within the protection scope of the technical solution of the present invention.

Claims (10)

1. A plasma active water generating device is characterized in that: the plasma water purifier comprises a water inlet device, an active water collecting device and a plurality of plasma generating assemblies, wherein the water inlet of each plasma generating assembly is communicated with the water inlet device, and the water outlet of each plasma generating assembly is communicated with the active water collecting device;

the plasma generating assembly comprises a power supply (8), an outer electrode (10) and a water seepage assembly, the water seepage assembly and the outer electrode (10) are arranged at intervals, the water seepage portion of the water seepage assembly is higher than the outer electrode (10), one electrode of the power supply (8) is connected with the outer electrode (10), and the other electrode is communicated with water seeped out from the water seepage portion.

2. A plasma activated water generating device as defined in claim 1, wherein: the water inlet device and the active water collecting device are sequentially arranged from top to bottom, and the plasma generating assembly is arranged between the water inlet device and the active water collecting device.

3. A plasma activated water generating apparatus according to claim 1 or 2, characterized in that: the water inlet device is a water inlet tank (14), and the water inlet tank (14) is arranged higher than the plasma generating assembly; the active water collecting device is an active water tank (15), and the active water tank (15) is lower than the plasma generating assembly.

4. A plasma activated water generating apparatus according to claim 1 or 2, characterized in that: the plasma generator further comprises a bearing cylinder (18), the diameter of the upper portion of the bearing cylinder (18) is larger than that of the lower portion of the bearing cylinder, the bearing cylinder (18) is arranged on the lower side of each plasma generating assembly, and the bottom of each bearing cylinder (18) is communicated with an active water collecting device.

5. The plasma activated water generating apparatus according to claim 1, wherein: plasma generate assembly still include insulating cylinder (4), insulating cylinder (4) interval cover is established outside the infiltration subassembly, outer electrode (10) encircle insulating cylinder (4) and set up.

6. Plasma active water generating device according to claim 5, characterized in that: the plasma generating assembly further comprises an exhaust gas treatment device, and the exhaust gas treatment device is communicated with the insulating cylinder (4).

7. Plasma active water generating device according to claim 6, characterized in that: the waste gas treatment device also comprises a gas collecting pipe (17), and the gas inlet of the gas collecting pipe (17) is communicated with each waste gas treatment device.

8. A plasma activated water generating device as defined in claim 1, wherein: the infiltration subassembly include ceramic membrane (6) and keep apart plywood (7), ceramic membrane (6) are cylindric, keep apart plywood (7) and set up in ceramic membrane (6), keep apart plywood (7) and ceramic membrane (6) inner wall sealing connection to form at the upside of keeping apart plywood (7) infiltration portion, outer electrode (10) encircle ceramic membrane (6) and set up.

9. A plasma activated water generating device as defined in claim 1, wherein: the plasma generator further comprises cooling devices, and the cooling devices are arranged outside the plasma generating assemblies.

10. A method for generating active water for a plasma active water generating apparatus according to any one of claims 1~9, comprising: the method comprises the following steps:

water in the water inlet device enters each plasma generating assembly;

after the water in the plasma generating assembly extends out of the water seepage part, the water flows downwards along the inner wall of the water seepage assembly;

two electrodes of the power supply (8) are respectively communicated with the seeped water and the outer electrode (10), and when water on the outer wall of the water seepage component flows through the outer electrode (10), ionization is directly generated between the water seepage component and the outer electrode (10) to generate active water;

the produced active water enters an active water collecting device.

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