KR102160490B1 - Plasma water treatment system with modular plate discharge tube protection filter - Google Patents

Abstract

A plasma water treatment system equipped with a modular plate discharge tube protection filter is disclosed. The plasma water treatment system includes: an oxygen generator; a modular plate discharge tube; a power supply unit; a modular plate discharge tube protection filter; an injector; and an ozone dissolving tank. A sterilization effect of the water to be treated can be increased.

Description

Plasma water treatment system equipped with a modular plate discharge tube protection filter {PLASMA WATER TREATMENT SYSTEM WITH MODULAR PLATE DISCHARGE TUBE PROTECTION FILTER}

The present invention relates to a plasma water treatment system, and more particularly, to a plasma water treatment system provided with a modular plate discharge tube protection filter provided with a filter filter for filtering foreign substances in water to be treated.

In recent years, air and water pollution has emerged as a serious environmental problem due to rapid industrial development, population expansion, and urban concentration. In particular, domestic and foreign industrial wastewater severely pollutes surface water and the like by various organic substances, causing enormous harm to the health of the people. In addition, pollution of domestic rivers and lakes is accelerating due to inflow water from factory wastewater, livestock complexes, golf courses, etc., and although a small amount, eutrophication of the reservoir due to organic compounds in the raw water, algae and odors, etc. As a result, it is difficult to treat water supply.

In order to solve this problem, water treatment devices using ozone have been developed to sterilize contaminated water using ozone.

Conventional water treatment apparatuses have a filtration filter for filtering foreign substances in the water to be treated in the process of supplying the water to be treated, but the filtration filter is provided in a tank in which the water to be treated is stored, Even if provided, it lacks a structure capable of automatically discharging foreign substances accumulated in the filtration filter.

Registered Patent No. 10-0359989

Accordingly, an object to be solved by the present invention is to provide a plasma water treatment system provided with a modular plate discharge tube protection filter capable of automatically discharging foreign substances accumulated in a filtration filter that filters foreign substances in water to be treated.

A plasma water treatment system according to an embodiment of the present invention includes an oxygen generator; A modular plate discharge tube for introducing oxygen from the oxygen generator and generating ozone using the introduced oxygen; A power supply unit for supplying power to the modular plate discharge tube; A modular plate discharge tube configured to discharge the water to be treated from one side to the side opposite to the supply side of the water to be treated while the foreign substances in the water to be treated are removed by allowing the water to be treated to proceed through an internal filter Protection filter; Part or all of the water to be treated from which foreign substances have been removed is introduced through the modular plate discharge tube protection filter, and ozone is introduced from the modular plate discharge tube, and ozone water is generated by mixing the ozone with the treated water. And an injector for discharging the ozone water in a direction different from the inlet side of the treated water and the ozone; And the ozone water discharged from the injector is introduced, promotes the dissolution of ozone in the ozone water, and comprises an ozone dissolution tank for discharging the sterilized water to be treated in one direction through ozone, wherein the modular plate discharge tube protection filter, A water filter tank having a certain length; A filtration filter provided to have a diameter smaller than the diameter of the water filtration tank to be treated; A treatment water inlet port connected to an end of the water supply pipe to which the treatment water is supplied and provided at an upper side of the treatment water filtration tank; A treatment water discharge port provided on the other side of the upper portion of the treatment water filtration tank and discharges the treatment water from which foreign matters are removed through the filter filter; A foreign matter discharge port provided at the lower end of the water filtering tank to be treated; An opening/closing valve rotating in a first direction and a second direction to open or close the foreign material discharge port; A motor rotating the on-off valve in the first direction and the second direction; A first pressure sensing sensor provided on the side of the treated water inlet and measuring pressure at the side of the treated water inlet; A second pressure sensing sensor provided on the side of the discharge port to be treated to measure the pressure at the discharge port of the treated water; The pressure difference between the first pressure value input from the first pressure sensor and the second pressure value input from the second pressure sensor and electrically connected to the first pressure sensor and the second pressure sensor And a control unit for controlling the motor so that the opening/closing valve rotates in a direction in which the foreign material discharge port is opened when the pressure difference is determined and is within a preset motor operation range, and the motor operation range includes the first pressure value 2 It is characterized in that it is set to 1.2 to 2.2 times the pressure value.

In one embodiment, further comprising a backflow preventer installed on the ozone supply line connected between the modular plate discharge tube and the injector to block the flow of water to be treated backflowing from the injector into the modular plate discharge tube And, the backflow preventer, a flat portion, a side portion perpendicular to the flat portion, a first taper portion tapering downward from a lower end of the side portion, a second taper tapering to a diameter smaller than the diameter of the end of the first tapered portion A counterflow water tank including an ozone inlet through the flat portion, an ozone outlet through the side portion, and a counterflow water outlet through an end of the second tapered portion; The upper body, the lower body provided in the lower part of the upper body and tapered to a diameter that can be in close contact with the inner surface of the second tapered part, provided in the countercurrent water tank, wherein the lower body is in close contact with the inner surface of the second tapered part Thus, it may include a buoy having a floatable weight and provided to close the backflow water outlet.

In one embodiment, the buoy is provided with a guide shaft insertion groove having a predetermined depth on one side of the plane of the upper body, and the backflow preventer extends from one side of the inner surface of the flat portion of the counterflow water tank so that the lower portion is the guide shaft It is inserted into the insertion groove, it may further include a buoy guide shaft for guiding the rise and fall of the buoy.

The plasma water treatment system according to the present invention is electronically controlled so that the modular plate discharge tube protection filter that removes foreign substances in the water to be treated detects the pressure difference between the inlet side and the discharge side of the water to be treated, and opens the foreign matter discharge port for discharging foreign substances. Therefore, there is an advantage in that the supply of the water to be treated can always be smoothly performed without clogging or blocking the supply of the water to be treated due to the accumulation of foreign substances in the filter, and furthermore, smooth operation of the plasma water treatment system is possible.

In addition, since the ozone dissolving tank has a structure in which ozone is dissolved while passing through the multi-layered dissolution space in a vortex form, the action of dissolving ozone in the water to be treated can be increased. There is an advantage to be able to.

1 is a view showing the configuration of a plasma water treatment apparatus according to an embodiment of the present invention.
2A is a perspective view showing the appearance of the modular plate discharge tube shown in FIG. 1.
2B is an exploded perspective view illustrating the configuration of the plate discharge tube shown in FIG. 2.
3 is a view for explaining the configuration of the modular plate discharge tube protection filter shown in FIG.
4 is a cross-sectional view for explaining the configuration of the ozone melting tank shown in FIG.
5 is a view for explaining the configuration of the backflow preventer shown in FIG.

Hereinafter, a plasma water treatment system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present invention, various modifications may be made and various forms may be applied, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form disclosed, it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention. In describing each drawing, similar reference numerals have been used for similar elements. In the accompanying drawings, the dimensions of the structures are shown to be enlarged than the actual size for clarity of the present invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are used only for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element.

The terms used in the present application are used only to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility of being added.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this application. Does not.

1 is a diagram showing the configuration of a plasma water treatment system according to an embodiment of the present invention.

Referring to FIG. 1, the plasma water treatment system according to an embodiment of the present invention includes an oxygen generator 110, a modular plate discharge tube 120, a power supply unit 130, a modular plate discharge tube protection filter 140, and an injector. 150), may include an ozone dissolving tank 160.

The oxygen generator 110 generates oxygen from external air.

The modular plate discharge tube 120 receives oxygen from the oxygen generator 110 and generates ozone using the introduced oxygen. For example, the modular plate discharge tube 120 may be configured to form a modular type by stacking a plurality of plate discharge tubes 120 as shown in FIG. 2A. Referring to FIG. 2B, the plurality of plate discharge tubes 120 have a cooling water circulation passage 121a formed therein, and a discharge panel 121 having a panel electrode receiving portion 121b formed concave in a square shape on one surface thereof. A panel electrode 122 accommodated in the panel electrode receiving portion 121b and an insulating packing 123 stacked on an edge of the discharge panel 121 may be included. When a plurality of such plate discharge tubes 120 are stacked, the insulating packings 123 provided in each plate discharge tube are stacked in contact with each other. Accordingly, the panel electrodes 122 provided in each plate discharge tube 120 are A predetermined interval, that is, a discharge interval is formed from each other, so that discharge may be performed between the panel electrodes 122.

The power supply unit 130 supplies power to the modular plate discharge tube 120. For example, the power supply unit 130 may include an inverter 131 and a transformer 132.

The modular plate discharge tube protection filter 140 allows the to-be-treated water supplied from one side to pass through an internal filter so that foreign matters in the water to be treated are removed and the treated water from which the foreign matters are removed It is configured to discharge to the opposite side.

For example, the modular plate discharge tube protection filter 140 includes a water filter tank 141 to be treated, a filter (not shown), a water inlet to be treated 142, a water discharge to be treated 143, a foreign matter discharge port 144, An on/off valve 145, a motor 146, a first pressure sensor 147, a second pressure sensor 148, and a control unit 149 may be included.

The water filtering tank 141 to be treated is provided to have a predetermined length. For example, the water filtering tank 141 to be treated may have a cylindrical shape.

The filtration filter has a diameter smaller and shorter in length than the diameter of the water filtration tank 141 to be treated, and may be disposed parallel to the length direction of the water filtration tank 141 to be treated, and has a cylindrical shape. It can be provided.

The water inlet 142 to be treated is connected to an end of the water supply pipe 10 to which the water to be treated is supplied, and may be provided on one side of the upper portion of the water filtration tank 141 to be treated.

The water to be treated discharge port 143 is provided on the other side of the upper portion of the water filtering tank 141 to be treated, and passes through the filter to discharge the water to be treated from which foreign matters are removed.

The foreign matter discharge port 144 is provided at the lower end of the water filtering tank 141 to be treated, and may be opened when a foreign matter in the water filtering tank 141 is intended to be discharged.

The opening/closing valve 145 may open or close the foreign material discharge port 144 by rotating in the first direction and the second direction.

The first pressure sensor 147 is provided on the side of the water inlet 142 to be treated to measure the pressure on the inlet 142 of the water to be treated.

The second pressure sensing sensor 148 is provided on the side of the treatment water discharge port 143 to measure the pressure at the side of the treatment water discharge port 143.

The control unit 149 is electrically connected to the first pressure sensor 147 and the second pressure sensor 148, the first pressure value and the second pressure input from the first pressure sensor 147 When the pressure difference between the second pressure values input from the pressure detection sensor 148 is determined and the pressure difference is within a preset motor operation range, the on/off valve 145 rotates in the direction in which the foreign matter outlet 144 is opened. The motor 146 can be controlled.

Here, the motor operation range may be set to a case in which the first pressure value is 1.2 to 2.2 times the second pressure value.

For example, the modular plate discharge tube protection filter 140 has a filter structure based on other components other than the configuration of the first pressure sensing sensor 147, the second pressure sensing sensor 148, and the control unit 149, "Lakos Filter". It can be the same as the structure. The "Lakos Filter" is known as a filter in which automatic backwashing and foreign matter are removed by rotating the upper twist valve.

The injector 150 passes through the modular plate discharge tube protection filter 140 and partially or all of the water to be treated from which foreign substances are removed is introduced, and ozone is introduced from the modular plate discharge tube 120 to be treated. Ozone water may be generated by mixing the ozone, and the ozone water may be discharged in a direction different from the inlet side of the treated water and the ozone. For example, the injector 150 includes a first opening (not shown) through which water to be treated is introduced, a second opening through which ozone is introduced (not shown), and a third opening (not shown) through which ozone-mixed ozone water is discharged. In addition, the first opening and the third opening may be in a vacuum state, and the ozone generated in the discharge tube may be sucked and mixed with the water to be treated to generate ozone water.

The ozone dissolving tank 160 flows in the ozone water discharged from the injector 150 through the ozone supply line 40 connected to the third opening of the injector 150, thereby promoting the dissolution of ozone in the ozone water and reducing ozone. Through this, the sterilized water to be treated can be discharged in one direction.

For example, the ozone dissolving tank 160 is connected to the ozone supply line 40 connected between the first dissolution tank 161, the modular plate discharge tube 120 and the injector 150 at the inlet side, and the inside of the first dissolution tank 161 Ozone water is introduced into the furnace, and the first ozone water input pipe 162 is provided so that the outlet side is located close to the inner bottom surface of the first dissolution tank 161, and is arranged at regular intervals in the height direction of the first dissolution tank 161 The first dissolving disk 163 to form a plurality of dissolving spaces in the first dissolution tank 161, the first dissolving disc 163 is penetrated to communicate with the lower dissolution space and the upper dissolving A plurality of first ozone water circulation pipes 164, second dissolution tanks 165, which are provided to communicate with the space, extending from the top of the first dissolution tank 161 toward the inner bottom surface of the second dissolution tank 165 2 The ozone water input pipe 166, a second dissolution disk 167 disposed at regular intervals in the height direction of the second dissolution tank 165 to form a plurality of dissolution spaces inside the second dissolution tank 165, the A plurality of second ozone water circulation pipes 168 penetrated through the second dissolving disks 167 to communicate with the lower dissolution space and the upper dissolution space communicated with the upper dissolution space, and the second dissolution tank 165 It is provided and may include an ozone water discharge pipe 169 for discharging the ozone water moved to the upper portion of the second melting tank 165 through the melting spaces in the second melting tank 165.

On the other hand, the plasma water treatment system according to an embodiment of the present invention is installed on the ozone water transfer pipe 20 connected between the modular plate discharge tube 120 and the injector 150, and flows back from the injector 150. It may further include a backflow preventer 170 for blocking the flow of water to be treated into the modular plate discharge tube 120.

The backflow preventer 170 may include a counterflow target water tank 171, a buoy 172, and a buoy guide shaft 173.

The countercurrent treatment water tank 171 includes a flat portion 1711, a side portion 1712 perpendicular to the flat portion 1711, a first tapered portion 1713 tapering downward from the lower end of the side portion 1712, A second tapered portion 1714 tapering to a diameter smaller than the diameter of the end of the first tapered portion 1713, an ozone inlet 1715 penetrating through the flat portion 1711, and ozone penetrating through the side portion 1712 It may include a discharge port 1716 and a countercurrent water discharge port 1917 penetrating through the end of the second tapered portion 1714.

The buoy 172 is provided on an upper body 1721 provided with a guide shaft insertion groove 1721a having a predetermined depth on one side of the plane, and is provided under the upper body 1721, and is in close contact with the inner surface of the second tapered part 1714 A lower body (1722) tapered to a diameter capable of being provided in the countercurrent water tank 171, and the lower body (1722) is in close contact with the inner surface of the second tapered portion (1714), and the counterflow water outlet ( 1717) is provided to close, and may have a floatable weight. Such a buoy 172 is maintained in a state in which the pressure is applied to the plane by ozone flowing through the ozone inlet 1715 in a normal state to block the countercurrent water outlet 1717, and the countercurrent treated water tank 171 When the water to be treated backflowing inside is filled, it is floated and the counterflow water outlet 1717 can be opened.

The buoy guide shaft 173 extends from one side of the inner surface of the flat portion 1711 of the countercurrent water tank 171 so that the lower portion is inserted into the guide shaft insertion groove 1721a, and the buoy 172 rises and Can guide descent.

Meanwhile, in the plasma water treatment system according to an embodiment of the present invention, each of the modular plate discharge tubes 120 through branch tubes 30 branched from the ozone water transfer tube 20 and connected to the modular plate discharge tube 120 Ozone water may be introduced into the cooling water circulation passage 121a of the discharge panel 121 and may be configured to cool the discharge panel 121 while circulating ozone water along the cooling water circulation passage 121a.

Hereinafter, a process of sterilizing target water in the plasma water treatment system according to an embodiment of the present invention will be described.

When oxygen is supplied from the oxygen generator 110 to the modular plate discharge tube 120 and power is applied to the modular plate discharge tube 120 from the power supply unit 130, a discharge is generated in the modular plate discharge tube 120 to generate ozone Is created.

The generated ozone moves in the direction of the injector 150, first passes through the backflow preventer 170, and then is supplied to the injector 150.

Along with this, water to be treated is supplied and introduced into the interior of the modular plate room conversion protection filter 140, and the water to be treated is removed while passing through the internal filter to remove foreign substances. Is discharged to the opposite side of the supply side.

The water to be treated from which foreign substances have been removed flows into the injector 150 and is mixed with ozone in the injector 150, and the injector 150 directs ozone water generated by mixing ozone into the water to be treated toward the ozone dissolution tank 160. Discharge.

Subsequently, some of the ozone water discharged from the injector 150 flows into the ozone melting tank 160 and the rest flows into the modular plate discharge tube 120.

At this time, the ozonated water introduced into the ozone dissolving tank 160 passes through the multi-layered dissolution space in a vortex in the first dissolution tank 161 of the ozone dissolution tank 160, and then passes through the multi-layered dissolution space in the second dissolution tank 165. The dissolution of ozone is promoted by passing through while forming a vortex, and the water to be treated sterilized by ozone is discharged from the second dissolution tank 165.

In addition, some of the ozone water introduced into the modular plate discharge tube 120 is discharged after cooling the discharge panel 121 while passing through the cooling water circulation passage 121a of each of the discharge panels 121 of the modular plate discharge tube 120. It is discharged from the panel 121.

In the process of treating the water to be treated, foreign matters removed from the water to be treated as they pass through the modular plate discharge tube protection filter 140 are accumulated in the filtration filter 140. At this time, the water inlet 142 side The pressure of and the pressure at the side of the treated water outlet 143 are different, and each pressure is measured through the first pressure sensor 147 and the second pressure sensor 148.

That is, the first pressure value measured by the first pressure sensor 147 is higher than the second pressure value measured by the second pressure sensor 148, and each of the first pressure value and the second pressure value is the controller (149), and the control unit 149 determines the pressure difference between the input first pressure value and the second pressure value input from the second pressure sensor 148 so that the pressure difference is within a preset motor operation range. On the back, the motor 146 is controlled so that the opening/closing valve 145 rotates in the direction in which the foreign material discharge port 144 is opened. For example, when the first pressure value is 1.2 times greater than the second pressure value, it corresponds to a pressure difference in the motor operating range, so that the control unit 149 is in a direction in which the opening/closing valve 145 is opened. Controls the motor 146 to rotate. Accordingly, the foreign matter discharge port 144 is opened so that the foreign matter accumulated in the filtration filter 140 together with the treated water flowing into the treated water filtration tank 141 can be discharged and removed.

Meanwhile, when the water to be treated is supplied to the injector 150 during the treatment of the water to be treated, the water to be treated may flow backward in the direction of the modular plate discharge tube 120. For example, if the flow rate is slowed, it can be reverse flowed. The water to be treated flowing back from the injector 150 toward the modular plate discharge tube 120 flows into the counter flow water tank 171 of the back flow preventer 170, and when the amount of flow gradually increases, the buoy 172 As is floating, the counterflow water outlet 1717 at the end of the second taper portion 1714 of the counterflow water tank 171 is opened, and accordingly, the reverse water to be treated flows along the counterflow water outlet 1717 Is discharged. At this time, since the floating buoy 172 floats along the buoy guide shaft 173, a stable rise can be achieved.

In the plasma water treatment system according to an embodiment of the present invention, the modular plate discharge tube protection filter 140 for removing foreign substances in the water to be treated detects a pressure difference between the inlet side and the discharge side of the water to be treated to discharge foreign substances. Since it is electronically controlled to open the foreign matter outlet 144, the supply of water to be treated can always be smoothly made without clogging or blocking the supply of water to be treated due to the accumulation of foreign substances in the filter, and furthermore, the smooth supply of the plasma water treatment system. There are advantages to being able to operate.

In addition, since the ozone dissolving tank 160 has a structure in which ozone is dissolved while passing through the multi-layered dissolution space in a vortex form, the action of dissolving ozone in the water to be treated can be increased, and thus, the sterilization effect of the water to be treated. There is an advantage that can be increased.

On the other hand, the first pressure sensing sensor 147, the second pressure sensing sensor 148, and the backflow preventer 170 of the plasma water treatment system according to an embodiment of the present invention are effectively prevented and removed from adhesion of contaminants. To achieve this, an antifouling coating layer made of a composition for antifouling coating may be applied.

The anti-fouling coating composition contains mercaptobenzothiazole and amidoalkyl betaine in a molar ratio of 1:0.01 to 1:2, and the total content of mercaptobenzothiazole and amidoalkyl betaine is 1 with respect to the total aqueous solution. ~10% by weight.

The molar ratio of the mercaptobenzothiazole and amidoalkyl betaine is preferably 1:0.01 to 1:2.If the molar ratio is out of the above range, the coating property of the substrate decreases or the surface moisture adsorption increases after application. There is a problem that the film is removed.

The mercaptobenzothiazole and amidoalkyl betaine are preferably 1 to 10% by weight in the total aqueous solution of the composition, and if it is less than 1% by weight, there is a problem that the coating property of the substrate is deteriorated, and if it exceeds 10% by weight, the coating film thickness Crystal precipitation is likely to occur due to an increase in

On the other hand, as a method of applying the present antifouling coating composition onto a substrate, it is preferable to apply it by a spray method. Further, the thickness of the final coating film on the substrate is preferably 550 to 2000Å, more preferably 1100 to 1900Å. If the thickness of the coating film is less than 550 Å, there is a problem of deterioration in the case of high temperature heat treatment, and if it exceeds 2000 Å, crystal precipitation on the coated surface is liable to occur.

In addition, the present antifouling coating composition may be prepared by adding 0.1 mol of mercaptobenzothiazole and 0.05 mol of amidoalkyl betaine to 1000 ml of distilled water, followed by stirring.

Meanwhile, as a fragrance material having a sterilization function is coated on the inner surface of the foreign material discharge port 144 of the plasma water treatment system according to an embodiment of the present invention, it can effectively sterilize the discharged water and foreign matter.

On the other hand, functional oils may be mixed in the perfume material, and the mixing ratio is 95 to 97% by weight of the perfume and 3 to 5% by weight of the functional oil are mixed, and the functional oil is 50% by weight of Costus oil, Kashii It consists of 50% by weight of Cassie oil.

Here, it is preferable that 3 to 5% by weight of the functional oil is mixed with respect to the fragrance. When the mixing ratio of the functional oil is less than 3% by weight, the effect is insignificant, and when the mixing ratio of the functional oil exceeds 3 to 5% by weight, the effect is not greatly improved, while the manufacturing cost is greatly increased.

Costus oil is good for neuralgia, muscle pain, antidepressant, and stress relief.

Cassie oil has excellent effects on detoxification, treatment of skin diseases, sterilization, relief of itching, clearing the head, and relieving tension.

As such functional oil is coated on the inner surface of the foreign material discharge port 144, it exhibits an excellent effect of sterilizing water to be treated and foreign matter. The reason for the numerical limitation of the constituents and ratios is that the present inventors have repeatedly failed several times and analyzed through the test results, showing the optimum effect in the constituents and ratios.

In addition, a metal mesh foam may be attached to the outer surface of the motor 146. This metal mesh foam is in the form of a metal mesh foam having pores.

Such a metal mesh foam may be configured in a form in which a temperature change layer is applied to penetrate the surface of the metal mesh foam.

In the thermochromic layer, two or more thermochromic materials that change color when the temperature is higher than a predetermined temperature are applied to the surface of the metal mesh foam and are separated into two or more sections according to the temperature change, so that a stepwise temperature change can be determined. A protective layer may be applied on the thermochromic layer to prevent damage to the thermochromic layer.

Here, the thermochromic layer may be formed by applying a thermochromic material having a discoloration temperature of 40°C or more and 60°C or more, respectively. The temperature change layer is for detecting a temperature change of the motor 146 by changing color according to the temperature of the motor 146 that is indirectly heated as the internal temperature rises by the heater unit. The temperature of the motor 146 is transmitted to the metal mesh foam, and the temperature change layer reacts according to the temperature change of the metal mesh foam, and as a result, the temperature change of the motor 146 can be sensed.

The thermochromic layer may be formed by applying a thermochromic material that changes color when it reaches a predetermined temperature or higher on the surface of the metal mesh foam. In addition, the thermochromic layer is generally composed of a microcapsule structure of 1 to 10 µm, and can be colored and transparent due to the bonding and separation phenomena of the electron donor and the electron acceptor according to the temperature in the microcapsule.

In addition, the color change layer has a fast color change, and may have various color change temperatures such as 40°C, 60°C, 70°C, 80°C, and the like, and the color change temperature can be easily adjusted in various ways. The thermochromic layer may use various types of thermochromic materials based on the principle of molecular rearrangement of organic compounds and spatial rearrangement of atomic groups.

To this end, it is preferable that the thermochromic layer is formed to be separated into two or more sections according to temperature changes by applying two or more thermochromic materials having different discoloration temperatures. It is preferable to use a thermochromic material having a relatively low discoloration temperature and a thermochromic material having a relatively high discoloration temperature, and more preferably, a discoloration temperature of 40℃ or more and 60℃ or more. A thermochromic layer can be formed by using a thermochromic material.

Through this, it is possible to check the temperature change of the motor 146 so that the temperature change of the motor 146 can be detected, and accordingly, it is easy to visually check whether the current motor 146 is in a normal driving state or an overheated state. There is an advantage to be able to.

In addition, the protective film layer is applied on the thermochromic layer to prevent damage to the thermochromic layer due to external impact, and at the same time, it is easy to check whether the thermochromic layer is discolored, and at the same time consider that the thermochromic material is weak to heat, it has an insulation effect It is preferable to use a transparent coating material.

In addition, a packing (not shown) is provided inside the opening/closing valve 145 to maintain watertightness. This packing may be made of a rubber material, and the raw material content ratio of such packing is mixed with 60% by weight of rubber, 33 to 36% by weight of carbon black, 2 to 5% by weight of antioxidant, and 1 to 3% by weight of sulfur as an accelerator. .

Carbon black is to increase abrasion resistance, so it is added, but if the content is less than 33% by weight, elasticity and abrasion resistance decrease, and if it exceeds 36% by weight, the content of rubber, which is the main component, is relatively small, so the elasticity may decrease. , 33 to 36% by weight are mixed.

Antioxidant is 3C (N-PHENYL-N'-ISOPROPYL- P-PHENYLENEDIAMINE) or RD (POLYMERIZED 2,2,4-TRIMETHYL-1,2-DIHYDROQUINOLINE) to add 2 to 5% by weight, 2 If it is less than% by weight, the product is liable to be oxidized, and if too much is added and exceeds 5% by weight, the content of rubber, which is the main component, is relatively small, and there is a fear that the elasticity may decrease, and the price of the antioxidant is expensive. ~5% by weight is appropriate.

Sulfur as an accelerator is mixed with 1 to 3% by weight. If less than 1% by weight, the vulcanization effect in the heating process during molding is insignificant, so 1% by weight or more is added. If it exceeds 3% by weight, since the content of the rubber as the main component is relatively small, the elasticity may be lowered, so 1 to 3% by weight is appropriate.

Accordingly, since the present invention is reinforced with synthetic rubber having elasticity in various directions, the elasticity, toughness and rigidity of the packing are increased, so that durability is improved, and thus the life of the packing is increased.

110: oxygen generator 120: modular plate discharge tube
130: power supply 140: modular plate discharge tube protection filter
150: injector 160: ozone melting tank
170: backflow preventer

Claims (4)

Oxygen generator 110;
A modular plate discharge tube 120 through which oxygen is introduced from the oxygen generator 110 and generates ozone using the introduced oxygen;
A power supply unit 130 for supplying power to the modular plate discharge tube 120;
A modular plate discharge tube configured to discharge the water to be treated from one side to the side opposite to the supply side of the water to be treated while the foreign substances in the water to be treated are removed by allowing the water to be treated to proceed through an internal filter Protection filter 140;
Part or all of the water to be treated from which foreign substances have been removed is introduced through the modular plate discharge tube protection filter 140, and ozone is introduced from the modular plate discharge tube 120, thereby adding the ozone to the treated water. An injector 150 for generating ozone water by mixing and discharging the ozone water in a direction different from the inlet side of the treated water and the ozone; And
The ozone water discharged from the injector 150 flows in, promotes the dissolution of ozone in the ozone water, and includes an ozone dissolution tank 160 for discharging the sterilized water to be treated through ozone in one direction,
The modular plate discharge tube protection filter 140,
A water filter tank 141 having a predetermined length;
A filtration filter (not shown) provided to have a diameter smaller than the diameter of the filtration target 141 in the filtration target 141;
A target water inlet 142 connected to an end of the water supply pipe 10 to which the target water is supplied and provided at an upper side of the target water filtration tank 141;
A treatment water outlet 143 provided at the other side of the upper portion of the treatment water filtration tank 141 and for discharging the treatment water from which foreign substances are removed by passing through the filtration filter;
A foreign matter discharge port 144 provided at the lower end of the water filtering tank 141 to be treated;
An opening/closing valve 145 rotating in a first direction and a second direction to open or close the foreign material discharge port 144;
A motor 146 rotating the on-off valve 145 in the first direction and the second direction;
A first pressure sensor 147 provided on the side of the treated water inlet 142 to measure the pressure at the side of the treated water inlet 142;
A second pressure sensing sensor 148 provided on the side of the treated water outlet 143 and measuring the pressure at the side of the treated water outlet 143;
The first pressure value and the second pressure sensor 148 are electrically connected to the first pressure sensor 147 and the second pressure sensor 148 and input from the first pressure sensor 147 ) To determine the pressure difference between the second pressure values inputted from ), and if the pressure difference is within a preset motor operating range, the on/off valve 145 rotates the motor 146 in a direction in which the foreign matter outlet 144 is opened. It includes a control unit 149 to control,
The motor operation range is set in a case where the first pressure value is 1.2 to 2.2 times the second pressure value;
It is installed on the ozone water transfer pipe 20 connected between the modular plate discharge tube 120 and the injector 150, and the treated water flowing back from the injector 150 flows into the modular plate discharge tube 120. Further comprising a backflow preventer 170 for blocking the,
The backflow preventer 170,
The flat portion 1711, the side portion 1712 perpendicular to the flat portion 1711, the first tapered portion 1713 tapering downward from the lower end of the side portion 1712, the first tapered portion 1713 A second tapered portion 1714 tapered to a diameter smaller than the diameter of the end, an ozone inlet 1715 penetrating through the flat portion 1711, an ozone outlet 1716 penetrating through the side portion 1712, and the second taper A counterflow target water tank 171 including a counterflow water outlet 1717 penetrating the end of the part 1714;
An upper body 1721 having a guide shaft insertion groove 1721a having a predetermined depth on one side of the plane, and having a diameter that is provided under the upper body 1721 and is in close contact with the inner surface of the second tapered part 1714 The taper is provided in the lower body 1722 and the counterflow water tank 171, so that the lower body 1722 is in close contact with the inner surface of the second tapered portion 1714 to close the counterflow water outlet 1717. Buoy 172 provided and having a floatable weight; And
A buoy guide extending from one side of the inner surface of the flat portion 1711 of the countercurrent treatment water tank 171 and having a lower portion inserted into the guide shaft insertion groove 1721a, and guiding the ascent and descending of the buoy 172 Characterized in that it comprises a shaft (173),
Plasma water treatment system equipped with a modular plate discharge tube protection filter.
delete The method of claim 1,
The buoy 172 is provided with a guide shaft insertion groove (1721a) having a predetermined depth on one side of the plane of the upper body (1721),
The backflow preventer is extended from one side of the inner surface of the flat portion 1711 of the counterflow water tank 171 and has a lower portion inserted into the guide shaft insertion groove 1721a, and the buoy 172 rises and falls. It characterized in that it further comprises a buoy guide shaft for guiding,
Plasma water treatment system equipped with a modular plate discharge tube protection filter.
The method of claim 1,
The ozone dissolving tank 160,
A first melting tank 161;
The inlet side is connected to the ozone supply line 40 connected between the modular plate discharge tube 120 and the injector 150 to inject ozone water into the first dissolution tank 161, and the outlet side of the first dissolution tank 161 A first ozone water input pipe 162 provided to be positioned close to the inner bottom surface;
A first melting disk 163 arranged at regular intervals in the height direction of the first melting tank 161 so as to form a plurality of melting spaces inside the first melting tank 161;
A plurality of first ozone water circulation pipes 164 which penetrate through the first dissolution disks 163 so that the lower end communicates with the lower dissolution space and the upper end communicates with the upper dissolution space;
A second melting tank 165;
A second ozone water input pipe 166 extending from the top of the first dissolution tank 161 toward the inner bottom surface of the second dissolution tank 165;
A second melting disk (167) disposed at regular intervals in the height direction of the second melting tank (165) to form a plurality of melting spaces inside the second melting tank (165);
A plurality of second ozone water circulation pipes 168 which penetrate through the second dissolution disks 167 so that the lower end communicates with the lower dissolution space and the upper end communicates with the upper dissolution space;
It characterized in that it comprises an ozone water discharge pipe 169 provided above the second dissolution tank 165 and discharges ozone water that has passed through the dissolution spaces in the second dissolution tank 165 and moved to the upper part of the second dissolution tank 165. ,
Plasma water treatment system equipped with a modular plate discharge tube protection filter.

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