CN204356417U - Electrolytic ozone generator - Google Patents
Electrolytic ozone generator Download PDFInfo
- Publication number
- CN204356417U CN204356417U CN201420757276.XU CN201420757276U CN204356417U CN 204356417 U CN204356417 U CN 204356417U CN 201420757276 U CN201420757276 U CN 201420757276U CN 204356417 U CN204356417 U CN 204356417U
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- China
- Prior art keywords
- anode
- negative electrode
- clamping plate
- cathode
- conservancy diversion
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Abstract
Electrolytic ozone generator, belongs to Ozone generation device technique field, comprises ion-exchange membrane and the anode component and the cathode assembly that are divided into ion-exchange membrane both sides; Anode component comprises axial anode water tank, anode water conservancy diversion clamping plate, anode metal micro pore sheet and anodic reaction meson diaphragm from outside to inside; Described cathode diversion clamping plate comprise the negative electrode concave surface being positioned at edge and the negative electrode convex surface being positioned at center.This electrolytic ozone generator, ensure that the snap-in force of producer, avoids because of long-play anodic reaction meson diaphragm and cathodic reaction meson diaphragm is thinning and loosely organized and device that is that cause leaks, and reaches the effect of stable ozone output and concentration.
Description
Technical field
The utility model belongs to Ozone generation device technique field, is particularly related to electrolytic ozone generator.
Background technology
Ozone is a kind of oxygenant of environment-friendly type, has stronger oxidisability, and reacted product is the oxygen useful to human body.Based on above advantage, ozone product has been widely used in the fields such as drinking water treatment, sewage disposal and health care.
Low tension solution, relative to traditional corona method generation technology of ozone, can be promoted to 10% ~ 25% by ozone concn, and not containing NO in product
xclass gas, without any secondary pollution, therefore, low tension solution has wider application.The principle of low tension solution output ozone is the positive and negative polarities electrolysis deionized water adopting low dc voltage conducting solid film electrode, water is separated into hydrogen-oxygen molecule with the form of proton exchange on special anodic dissolution interface, hydrogen is directly discharged from cathode solution interface, oxygen molecule obtains energy because of the electron excitation of high-density current generation in anodic interface, and aggregates into ozone.
The reaction meson diaphragm of the anode in existing electrolytic ozone generator and negative electrode, mostly forms through the sticky pressure of reaction meson particle, baking.Electrolytic ozone generator is while operation, and the reaction meson film of anode and negative electrode will be subject to the electric shock of low-voltage DC continuously, and after long-play, the reaction meson diaphragm of anode and negative electrode will be thinning gradually.And common plane clamping plate just occur without bounce pressure comparatively fruit, cause electrolytic ozone generator insufficient pressure, thus make the loosely organized of whole electrolytic ozone generator, cause electrolytic ozone generator to leak, electrolytic ozone generator ozone output is declined and maybe cannot produce ozone.
Therefore, be necessary to research and develop a kind of electrolytic ozone generator, make its long-play still can keep stable snap-in force, thus ensure stable ozone output and concentration.
Utility model content
The purpose of this utility model is to overcome the above-mentioned defect mentioned and deficiency, and provides electrolytic ozone generator.
The technical scheme that the utility model realizes the employing of its object is as follows.
Electrolytic ozone generator, comprises ion-exchange membrane and the anode component and the cathode assembly that are divided into ion-exchange membrane both sides;
Anode component comprises axial anode water tank, anode water conservancy diversion clamping plate, anode metal micro pore sheet and anodic reaction meson diaphragm from outside to inside; Described anode water conservancy diversion clamping plate comprise the anode concave surface being positioned at edge and the anode convex surface being positioned at center;
Cathode assembly comprises axial negative electrode water tank, cathode diversion clamping plate, cathodic metal micro pore sheet and cathodic reaction meson diaphragm from outside to inside; Described cathode diversion clamping plate comprise the negative electrode concave surface being positioned at edge and the negative electrode convex surface being positioned at center;
Described anode water conservancy diversion clamping plate and cathode diversion clamping plate are equipped with screw rod; Described screw rod is through the anode concave surface of anode water conservancy diversion clamping plate and the negative electrode concave surface of cathode diversion clamping plate; Anode concave surface and negative electrode concave surface are enclosed to form a ring groove.
The axial arranged outside of described anode component has anode water tank; Described anode water tank radial direction is provided with anode inlet channel and anode outlet conduit; The axis inner side of anode water tank is provided with anode water conservancy diversion clamping plate; Sandwiched anode gasket between described anode water tank and anode water conservancy diversion clamping plate; The middle part of anode convex surface is provided with anode discharge orifice and the protruding water conservancy diversion contact of anode; Anode water conservancy diversion clamping plate axially inner side are disposed with anode metal micro pore sheet and anodic reaction meson diaphragm; Sandwiched anode gel packing ring between described ion-exchange membrane and anode water conservancy diversion clamping plate; Described anode gel packing ring axially outside fits in the edge of anode convex surface, and anode metal micro pore sheet and anodic reaction meson diaphragm are placed in the internal space of anode gel packing ring.
The protruding water conservancy diversion contact of described anode has 15 ~ 20.
The axial arranged outside of described cathode assembly has negative electrode water tank; Described negative electrode water tank radial direction is provided with negative electrode inlet channel and negative electrode outlet conduit; The axis inner side of negative electrode water tank is provided with cathode diversion clamping plate; Sandwiched cathode gasket between described negative electrode water tank and cathode diversion clamping plate; The middle part of negative electrode convex surface is provided with cathode system water hole and cathode bulging water conservancy diversion contact; Described cathode diversion clamping plate axially inner side are disposed with cathodic metal micro pore sheet and cathodic reaction meson diaphragm; Sandwiched negative electrode silicone gasket between described ion-exchange membrane and cathode diversion clamping plate; Described negative electrode silicone gasket axially outside fits in the edge of negative electrode convex surface, and cathodic metal micro pore sheet and cathodic reaction meson diaphragm are placed in the internal space of negative electrode silicone gasket.
Described cathode bulging water conservancy diversion contact has 15 ~ 20.
This electrolytic ozone generator, ensure that the snap-in force of producer, avoids because of long-play anodic reaction meson diaphragm and cathodic reaction meson diaphragm is thinning and loosely organized and device that is that cause leaks, and reaches the effect of stable ozone output and concentration.
Accompanying drawing explanation
Fig. 1 is diagrammatic cross-section of the present utility model;
Fig. 2 is explosive view of the present utility model;
Fig. 3 is the front view of anode of the present utility model concavo-convex row water conservancy diversion clamping plate;
Fig. 4 is the rear view of negative electrode of the present utility model concavo-convex row water conservancy diversion clamping plate;
In figure: 1-anode water tank, 2-anode gasket, 3-anode water conservancy diversion clamping plate, 3a-anode discharge orifice, the protruding water conservancy diversion contact of 3b-anode, 3c-anode convex surface, 3d-anode concave surface, 4-anode metal micro pore sheet, 5-anodic reaction meson diaphragm, 6-anode gel packing ring, 7-ion-exchange membrane, 8-negative electrode silicone gasket, 9-cathodic reaction meson diaphragm, 10-cathodic metal micro pore sheet, 11-cathode diversion clamping plate, 11a-cathode system water hole, 11b-cathode bulging water conservancy diversion contact, 12-cathode gasket, 13-negative electrode water tank, 14-screw rod, 15-nut, 16-groove.
Embodiment
Below in conjunction with accompanying drawing, the utility model is described in further detail.
Electrolytic ozone generator, comprises ion-exchange membrane 7 and the anode component and the cathode assembly that are divided into ion-exchange membrane 7 both sides.
The axial arranged outside of anode component has anode water tank 1; Described anode water tank 1 radial direction is provided with anode inlet channel and anode outlet conduit.
The axis inner side of anode water tank 1 is provided with anode water conservancy diversion clamping plate 3; Sandwiched anode gasket 2 between described anode water tank 1 and anode water conservancy diversion clamping plate 3.Described anode water conservancy diversion clamping plate 3 comprise the anode concave surface 3d being positioned at edge and the anode convex surface 3c being positioned at center; The middle part of anode convex surface 3c is provided with anode discharge orifice 3a and the protruding water conservancy diversion contact 3b of anode.Anode water conservancy diversion clamping plate 3 axially inner side are disposed with anode metal micro pore sheet 4 and anodic reaction meson diaphragm 5.Sandwiched anode gel packing ring 6 between described ion-exchange membrane 7 and anode water conservancy diversion clamping plate 3.Described anode gel packing ring 6 axially outside fits in the edge of anode convex surface 3c, and anode metal micro pore sheet 4 and anodic reaction meson diaphragm 5 are placed in the internal space of anode gel packing ring 6.
Containing the plumbous oxide compound with tantalum in described anodic reaction meson diaphragm 5.
Described anode water conservancy diversion clamping plate 3 are formed by the metallic titanium plate die stamping of 1.0-1.5 mm thick.
The protruding water conservancy diversion contact 3b of described anode has 15 ~ 20.
The axial arranged outside of described cathode assembly has negative electrode water tank 13; Described negative electrode water tank 13 radial direction is provided with negative electrode inlet channel and negative electrode outlet conduit.
The axis inner side of negative electrode water tank 13 is provided with cathode diversion clamping plate 11; Sandwiched cathode gasket 12 between described negative electrode water tank 13 and cathode diversion clamping plate 11.Described cathode diversion clamping plate 11 comprise the negative electrode concave surface being positioned at edge and the negative electrode convex surface being positioned at center; The middle part of negative electrode convex surface is provided with cathode system water hole 11a and cathode bulging water conservancy diversion contact 11b.Described cathode diversion clamping plate 11 axially inner side are disposed with cathodic metal micro pore sheet 10 and cathodic reaction meson diaphragm 9.Sandwiched negative electrode silicone gasket 8 between described ion-exchange membrane 7 and cathode diversion clamping plate 11.Described negative electrode silicone gasket 8 axially outside fits in the edge of negative electrode convex surface, and cathodic metal micro pore sheet 10 and cathodic reaction meson diaphragm 9 are placed in the internal space of negative electrode silicone gasket 8.
Containing platinum carbon oxides in described cathodic reaction meson diaphragm 5.
Described cathode bulging water conservancy diversion contact 11b has 15 ~ 20.
Described cathode diversion clamping plate 11 are identical with structure with anode water conservancy diversion clamping plate 3 shape, and material is different.Described cathode diversion clamping plate 11 are formed by 304 stainless steel plate die stampings of 1.0-1.5 mm thick.
Anode metal micro pore sheet 4 and cathodic metal micro pore sheet 10 titanium particle sintering compression form, and thickness is 0.8-1.2 millimeters.
Described anode water conservancy diversion clamping plate 3 and cathode diversion clamping plate 11 are equipped with screw rod 14; Described screw rod 14 is also fixed with nut 15 through the anode concave surface 3d of anode water conservancy diversion clamping plate 3 and the negative electrode concave surface of cathode diversion clamping plate 11; Anode concave surface 3d and negative electrode concave surface are enclosed to form a ring groove 16.
When screw rod 14 and nut 15 are tightened, anode concave surface 3d and negative electrode concave surface close to each other, groove 16 narrows.Anode water conservancy diversion clamping plate 3 and cathode diversion clamping plate 11 have certain rebound effect, regulate the reactive force of anode convex surface 3c antianode silicone gasket 6 and the reactive force of negative electrode convex surface anticathode silicone gasket 8, thus ensure that the snap-in force of producer.
At positive terminal, pure water flows into anode electrolysis room from the anode inlet channel of anode water tank 1, then flows into anode metal micro pore sheet 4 and anodic reaction meson diaphragm 5 through anode water conservancy diversion clamping plate 3, and through electrolysis, portion of water solution changes into oxygen and ozone.Oxygen and ozone are together with the anode outlet conduit outflow anode electrolysis room of undecomposed water finally by anode water tank 1.
At cathode terminal, pure water flows into catholyte chamber from the negative electrode inlet channel of negative electrode water tank 13, then is worth through cathodic metal micro pore sheet 10 and cathodic reaction meson diaphragm 9.Through electrolysis, portion of water solution changes into hydrogen.Hydrogen is together with the negative electrode outlet conduit outflow catholyte chamber of undecomposed water finally by negative electrode water tank 13.
After electrolytic ozone generator long-play, anodic reaction meson diaphragm 5 and cathodic reaction meson diaphragm 9 can be thinning gradually, without bounce pressure comparatively fruit, causing electrolytic ozone generator insufficient pressure, and causing the loosely organized of whole electrolytic ozone generator just appears in common plane clamping plate.The setting of anode water conservancy diversion clamping plate 3 and cathode diversion clamping plate 11, avoids the device caused because of loosely organized and leaks, and reaches the effect of stable ozone output and concentration.
The utility model is illustrated according to embodiment, and under the prerequisite not departing from present principles, this device can also make some distortion and improvement.It should be pointed out that and all drop on the technical scheme that all employings are equal to replacement or the mode such as equivalent transformation and obtain in protection domain of the present utility model.
Claims (5)
1. electrolytic ozone generator, is characterized in that, comprises ion-exchange membrane (7) and is divided into anode component and the cathode assembly of ion-exchange membrane (7) both sides;
Anode component comprises axial anode water tank (1), anode water conservancy diversion clamping plate (3), anode metal micro pore sheet (4) and anodic reaction meson diaphragm (5) from outside to inside; Described anode water conservancy diversion clamping plate (3) comprise the anode concave surface (3d) being positioned at edge and the anode convex surface (3c) being positioned at center;
Cathode assembly comprises axial negative electrode water tank (13), cathode diversion clamping plate (11), cathodic metal micro pore sheet (10) and cathodic reaction meson diaphragm (9) from outside to inside; Described cathode diversion clamping plate (11) comprise the negative electrode concave surface being positioned at edge and the negative electrode convex surface being positioned at center;
Described anode water conservancy diversion clamping plate (3) and cathode diversion clamping plate (11) are equipped with screw rod (14); The anode concave surface (3d) of described screw rod (14) through anode water conservancy diversion clamping plate (3) and the negative electrode concave surface of cathode diversion clamping plate (11); Anode concave surface (3d) and negative electrode concave surface are enclosed to form a ring groove (16).
2. electrolytic ozone generator as claimed in claim 1, is characterized in that, the axial arranged outside of described anode component has anode water tank (1); Described anode water tank (1) radial direction is provided with anode inlet channel and anode outlet conduit; The axis inner side of anode water tank (1) is provided with anode water conservancy diversion clamping plate (3); Sandwiched anode gasket (2) between described anode water tank (1) and anode water conservancy diversion clamping plate (3); The middle part of anode convex surface (3c) is provided with anode discharge orifice (3a) and the protruding water conservancy diversion contact (3b) of anode; Anode water conservancy diversion clamping plate (3) axially inner side are disposed with anode metal micro pore sheet (4) and anodic reaction meson diaphragm (5); Sandwiched anode gel packing ring (6) between described ion-exchange membrane (7) and anode water conservancy diversion clamping plate (3); Described anode gel packing ring (6) axially outside fits in the edge of anode convex surface (3c), and anode metal micro pore sheet (4) and anodic reaction meson diaphragm (5) are placed in the internal space of anode gel packing ring (6).
3. electrolytic ozone generator as claimed in claim 2, is characterized in that, the protruding water conservancy diversion contact (3b) of described anode has 15 ~ 20.
4. electrolytic ozone generator as claimed in claim 1, is characterized in that, the axial arranged outside of described cathode assembly has negative electrode water tank (13); Described negative electrode water tank (13) radial direction is provided with negative electrode inlet channel and negative electrode outlet conduit; The axis inner side of negative electrode water tank (13) is provided with cathode diversion clamping plate (11); Sandwiched cathode gasket (12) between described negative electrode water tank (13) and cathode diversion clamping plate (11); The middle part of negative electrode convex surface is provided with cathode system water hole (11a) and cathode bulging water conservancy diversion contact (11b); Described cathode diversion clamping plate (11) axially inner side are disposed with cathodic metal micro pore sheet (10) and cathodic reaction meson diaphragm (9); Sandwiched negative electrode silicone gasket (8) between described ion-exchange membrane (7) and cathode diversion clamping plate (11); Described negative electrode silicone gasket (8) axially outside fits in the edge of negative electrode convex surface, and cathodic metal micro pore sheet (10) and cathodic reaction meson diaphragm (9) are placed in the internal space of negative electrode silicone gasket (8).
5. electrolytic ozone generator as claimed in claim 4, it is characterized in that, described cathode bulging water conservancy diversion contact (11b) has 15 ~ 20.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201420757276.XU CN204356417U (en) | 2014-12-07 | 2014-12-07 | Electrolytic ozone generator |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201420757276.XU CN204356417U (en) | 2014-12-07 | 2014-12-07 | Electrolytic ozone generator |
Publications (1)
Publication Number | Publication Date |
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CN204356417U true CN204356417U (en) | 2015-05-27 |
Family
ID=53257897
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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CN201420757276.XU Expired - Fee Related CN204356417U (en) | 2014-12-07 | 2014-12-07 | Electrolytic ozone generator |
Country Status (1)
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CN (1) | CN204356417U (en) |
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2014
- 2014-12-07 CN CN201420757276.XU patent/CN204356417U/en not_active Expired - Fee Related
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Date | Code | Title | Description |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20150527 Termination date: 20191207 |
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CF01 | Termination of patent right due to non-payment of annual fee |