CN205061557U - Forced air cooling integral type ozone generator discharge device - Google Patents
Forced air cooling integral type ozone generator discharge device Download PDFInfo
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- CN205061557U CN205061557U CN201520779064.6U CN201520779064U CN205061557U CN 205061557 U CN205061557 U CN 205061557U CN 201520779064 U CN201520779064 U CN 201520779064U CN 205061557 U CN205061557 U CN 205061557U
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Abstract
The utility model discloses a forced air cooling integral type ozone generator discharge device, base electrode including two symmetry settings, the base electrode is provided with the draw -in groove, the draw -in groove is used for the mounting medium high voltage electrode body, the bottom surface of draw -in groove is provided with the strip arch of a plurality of just equidistant settings that are parallel to each other, the strip arch and the medium high voltage electrode body are contradicted in order to form inlet channel between the strip arch adjacent, still be provided with two gas tanks that the shape is the same on the base electrode, each inlet channel's both ends equally divide do not with two gas tanks intercommunications, still set up on the one of which base electrode respectively with the inlet port and the venthole of two gas tanks intercommunications, inlet port and venthole along the central point symmetry on the medium high voltage electrode body terminal surface set up so that the inlet port via each inlet channel to the venthole to admit air return circuit path length the same. It is provided with the fin to go back an organic whole on the base electrode, the fin set up the direction with inlet channel sets up the direction parallel.
Description
Technical field
The utility model relates to a kind of ozonizer, and more particularly, it relates to air-cooled integrated ozone producer electric discharge device.
Background technology
Ozonizer is the device for producing ozone gas (O3).Ozone is easy to decomposition and cannot stores, and needs formed in-situ onsite application (can carry out the storage of short period of time when special), and the place using ozone so every all needs to use ozonizer.Ozonizer at tap water, sewage, industrial oxidation, food-processing and fresh-keeping, medicine synthesis, the field widespread uses such as space sterilizing.
Existing ozonizer electric discharge device, generally comprise two pieces and be symmetrical arranged base electrode, its opposite face is provided with at least one medium High-voltage electrode body, the end face of medium High-voltage electrode body and base electrode leaves some gaps, by applying high voltage electric in medium High-voltage electrode body, make the breakdown formation ozone of the air in gap, so, due to when air is punctured by high voltage electric, a large amount of heats can be produced, so certainly will need to arrange heat-removal system at base electrode, general heat-removal system is divided into air cooling system and water-cooling system two kinds, water-cooling system because of pipeline complicated and easily produce the phenomenon of water clock, several scenes can not be applicable to, and in air cooling system, certainly will be different with air inlet that is gap UNICOM and the loop of giving vent to anger corresponding to arranging, the position in loop is arranged, working efficiency and reliability of structure certainly will be had influence on, the Chinese patent being CN01238563.8 as publication number discloses a kind of ozone generating-device, the setting of its electric discharge device is arranged on the inlet pipe of both sides and escape pipe formed air circuit, and be communicated with gap by the cavity arranged at inlet pipe and escape pipe, it is when designing, do not consider the design requirement in gap, although the thickness due to gap meets the demand of discharge effect, but the width in gap, here certainly will comparatively greatly (because the cavity of gap with inlet pipe and escape pipe will be communicated with), certainly, such mentality of designing easily gains enlightenment and realizes, but, if devise the induction trunk that several gaps are formed, so different owing to being bound to via the path length of each passage from inlet pipe to escape pipe in Realism Design, so just just can not have difference in the ozone conversion rate of each intake ducting, the transformation efficiency of whole equipment is caused to decline.
Utility model content
For the deficiency that prior art exists, the purpose of this utility model is the air-cooled integrated ozone producer electric discharge device providing a kind of high conversion.
For achieving the above object, the utility model provides following technical scheme: air-cooled integrated ozone producer electric discharge device, comprise two pieces of symmetrically arranged base electrodes, described base electrode is provided with draw-in groove, described draw-in groove is used for mounting medium High-voltage electrode body, it is characterized in that, the bottom surface of described draw-in groove is provided with some being parallel to each other and the strip projected parts of spaced set, described strip projected parts and medium High-voltage electrode body conflict to form induction trunk between adjacent strip projected parts, described base electrode is also provided with the identical air drain of two shapes, the two ends of each induction trunk are communicated with two air drains respectively, one base electrode also offers the air inlet port and production well that are communicated with two air drains respectively, described air inlet port is arranged to make air inlet port identical to the air inlet circuit path length of production well via each induction trunk along the central point on medium High-voltage electrode body end face with production well.
First, by some parallel and strip projected parts of spaced set, make original interstitial structure, change the induction trunk that width is smaller into, make each induction trunk (gap) when medium High-voltage electrode body is discharged, cross-sectional area reduces, ensure that enough air pressure and the turnover ratio of ozone, and by integrally offering air drain when gas enters or leave induction trunk on base electrode, capital is cushioned through air drain in advance, the stress that gas expansion brings can be reduced, play certain buffering effect, then airflow diversion is to each induction trunk, conflux again after breakdown formation ozone to the air drain of the other end, give vent to anger to production well, under ensure that the prerequisite of the exchange efficiency of gas, provide the circulation that multiple branch road carries out air-flow, ensure that security, this feature symmetrically arranged by the central point on air inlet port and production well and air inlet medium High-voltage electrode body end face simultaneously, ensure that air-flow flow through each branch road the path length of process equal, furtherly, the air-flow passed through in each induction trunk unit time is also identical, airshed would not be had like this to pass through inequality and cause total gas conversions lower.
The utility model can be set to further: be also provided with elastic sealing element between two pieces of described base electrodes, and described elastic sealing element is provided with the resigning hole identical with position with air drain shape.By the setting of elastic sealing element and resigning hole, ensure that stopping property, although in the prior art, too can elastic sealing element be set, but, because the air drain in the design and base electrode are integrated setting, so elastic sealing element is only with arranging the resigning hole matched with air drain, the coincident of the same and base electrode in its edge, the opposing end surface of two pieces of base electrodes can extrude elastic sealing element, the resistance to air loss of assurance device, such setting, compare the sealed structure of other existing scheme, only adopt one piece of elastic sealing element just can play a preferably sealing effectiveness, and need in other existing scheme to seal respectively air drain and gap, and the stopping property be wholely set that effect compares this programme is lower.
The utility model can be set to further: the length of described induction trunk is more than or equal to the length of medium High-voltage electrode body end face.By the length of induction trunk being greater than or equal to the length of medium High-voltage electrode body, ensure that air drain and medium High-voltage electrode body stagger setting, so all ozone generation process are all produce at induction trunk, and the waste of energy consumption can not be caused.
The utility model can be set to further: described base electrode has also been wholely set fin, and the setting direction of described fin is parallel with the setting direction of described induction trunk.Dispelled the heat by fin, to ensure the safety performance of this device, and gordian technique is that the direction that fin is arranged must be parallel with induction trunk, plays the effect improving structural strength.
The utility model can be set to further: described air inlet port and production well are provided with internal thread.By the design of internal thread, the stopping property of air inlet port and production well can be improved.
The utility model can be set to further: air drain described in each includes the rectangle dashpot for being communicated with each induction trunk and is symmetricly set on the circular slot to make way at rectangle dashpot two ends, by cambered surface transition between described rectangle dashpot and circular slot to make way.Arranged by rectangle dashpot and the slot to make way of circle, the shape of slot to make way is in order to adapt to pipe shape design, rectangle dashpot is then to adapt to each induction trunk and design requirement, and the resiliency of air-flow between slot to make way and dashpot, can be increased further by this feature of cambered surface transition, to a certain degree overdraught forms small-sized backflow in this transition cambered surface, ensure that transient state air pressure can not be excessive, and the air current flow of each induction trunk is consistent.
The utility model can be set to further: described base electrode also includes fixed part, and described fixed part and fin be arranged in parallel and be provided with retaining thread hole.On the basis of this programme, the design of fixed part is parallel with fin, can provide reserving space like this for the setting of blower fan, can be fixed on arbitrary sidewall simultaneously.
By adopting technique scheme, first, by some parallel and strip projected parts of spaced set, make original interstitial structure, change the induction trunk that width is smaller into, make each induction trunk (gap) when medium High-voltage electrode body is discharged, cross-sectional area reduces, ensure that enough air pressure and the turnover ratio of ozone, and by integrally offering air drain when gas enters or leave induction trunk on base electrode, capital is cushioned through air drain in advance, the stress that gas expansion brings can be reduced, play certain buffering equalized pressure effect, then airflow diversion is to each induction trunk, conflux again after breakdown formation ozone to the air drain of the other end, give vent to anger to production well, under ensure that the prerequisite of the exchange efficiency of gas, provide the circulation that multiple branch road carries out air-flow, ensure that security, this feature symmetrically arranged by the central point on air inlet port and production well and air inlet medium High-voltage electrode body end face simultaneously, ensure that air-flow flow through each branch road the path length of process equal, furtherly, the air-flow passed through in each induction trunk unit time is also identical, airshed would not be had like this to pass through inequality and cause total gas conversions lower.
Accompanying drawing explanation
Fig. 1 is this apparatus structure schematic diagram;
Fig. 2 is this device front view;
Fig. 3 is this device explosion figure;
Fig. 4 is this device side-view;
Fig. 5 is A-A direction sectional view in Fig. 4.
Reference numeral: 11, base electrode; 111, fin; 112, fixed part; 113, draw-in groove; 114, air drain; 1141, rectangle dashpot; 1142, circular slot to make way; 115, strip projected parts; 116, induction trunk; 1171, air inlet port; 1172, production well; 2, medium High-voltage electrode body; 3, elastic sealing element; 31, resigning hole; 41, inlet pipe; 42, escape pipe.
Embodiment
Referring to figs. 1 through Fig. 5, the utility model embodiment is described further.
As depicted in figs. 1 and 2, air-cooled integrated ozone producer electric discharge device, comprise two pieces of symmetrically arranged base electrodes 11, base electrode 11 is provided with draw-in groove 113, draw-in groove 113 is for mounting medium High-voltage electrode body 2, the bottom surface of draw-in groove 113 is provided with some being parallel to each other and the strip projected parts 115 of spaced set, with reference to shown in Fig. 3 and Fig. 4, strip projected parts 115 and medium High-voltage electrode body 2 conflict to form induction trunk 116 between adjacent strip projected parts 115, base electrode 11 is also provided with the air drain 114 that two shapes are identical, the two ends of each induction trunk 116 are communicated with two air drains 114 respectively, one base electrode 11 also offers the air inlet port 1171 and production well 1172 that are communicated with two air drains 114 respectively, air inlet port 1171 is arranged to make air inlet port 1171 identical via the air inlet circuit path length of each induction trunk 116 to production well 1172 along the central point on medium High-voltage electrode body 2 end face with production well 1172.Also be provided with elastic sealing element 3 between two pieces of base electrodes 11, elastic sealing element 3 is provided with the resigning hole 31 identical with position with air drain 114 shape.The length of induction trunk 116 is more than or equal to the length of medium High-voltage electrode body 2.Base electrode 11 is also provided with fin 111, and the setting direction of fin 111 is parallel with the setting direction of induction trunk 116.Air inlet port 1171 and production well 1172 are provided with internal thread.The circular slot to make way 1142 that each air drain 114 includes the rectangle dashpot 1141 for being communicated with each induction trunk 116 and is symmetricly set on rectangle dashpot 1141 two ends, by cambered surface transition between rectangle dashpot 1141 and circular slot to make way 1142.Base electrode 11 also includes fixed part 112, and fixed part 112 and fin 111 be arranged in parallel and be provided with retaining thread hole.
As Fig. 3, shown in, each base electrode 11 is all provided with draw-in groove 113, be respectively arranged with medium High-voltage electrode body 2 in draw-in groove 113, between medium High-voltage electrode body 2 and draw-in groove 113, form induction trunk 116, then carried out the collection with ozone that enters of air by inlet pipe 41 as shown in Figure 2 and escape pipe 42, can to show in figure and suggestion, the length of the ventilation path between air inlet port 1171 and production well 1172 is all identical, and meanwhile, the length of medium High-voltage electrode body 2 is greater than the length of induction trunk 116.Gap discharge trace is between 0.26-0.65, and the width of induction trunk 116 is between 1.0-40.2 millimeter, and the thickness of its medium High-voltage electrode body 2 is good between 0.4-1.5 millimeter.
The above is only preferred implementation of the present utility model, protection domain of the present utility model be not only confined to above-described embodiment, and all technical schemes belonged under the utility model thinking all belong to protection domain of the present utility model.It should be pointed out that for those skilled in the art, do not departing from the some improvements and modifications under the utility model principle prerequisite, these improvements and modifications also should be considered as protection domain of the present utility model.
Claims (7)
1. air-cooled integrated ozone producer electric discharge device, comprise two pieces of symmetrically arranged base electrodes, described base electrode is provided with draw-in groove, described draw-in groove is used for mounting medium High-voltage electrode body, it is characterized in that, the bottom surface of described draw-in groove is provided with some being parallel to each other and the strip projected parts of spaced set, described strip projected parts and medium High-voltage electrode body conflict to form induction trunk between adjacent strip projected parts, described base electrode is also provided with the identical air drain of two shapes, the two ends of each induction trunk are communicated with two air drains respectively, one base electrode also offers the air inlet port and production well that are communicated with two air drains respectively, described air inlet port is arranged to make air inlet port identical to the air inlet circuit path length of production well via each induction trunk along the central point on medium High-voltage electrode body end face with production well.
2. air-cooled integrated ozone producer electric discharge device as claimed in claim 1, it is characterized in that: be also provided with elastic sealing element between two pieces of described base electrodes, described elastic sealing element is provided with the resigning hole identical with position with air drain shape.
3. air-cooled integrated ozone producer electric discharge device as claimed in claim 1, is characterized in that: the length of described induction trunk is more than or equal to the length of medium High-voltage electrode body end face.
4. air-cooled integrated ozone producer electric discharge device as claimed in claim 1, it is characterized in that: described base electrode has also been wholely set fin, the setting direction of described fin is parallel with the setting direction of described induction trunk.
5. air-cooled integrated ozone producer electric discharge device as claimed in claim 1, is characterized in that: described air inlet port and production well are provided with internal thread.
6. air-cooled integrated ozone producer electric discharge device as claimed in claim 5, it is characterized in that: air drain described in each includes the rectangle dashpot for being communicated with each induction trunk and is symmetricly set on the circular slot to make way at rectangle dashpot two ends, by cambered surface transition between described rectangle dashpot and circular slot to make way.
7. the air-cooled integrated ozone producer electric discharge device as described in claim 1 or 2 or 3 or 4 or 5 or 6, it is characterized in that: described base electrode also includes fixed part, described fixed part and fin be arranged in parallel and are provided with retaining thread hole.
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CN201520779064.6U CN205061557U (en) | 2015-10-09 | 2015-10-09 | Forced air cooling integral type ozone generator discharge device |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN105217577A (en) * | 2015-10-09 | 2016-01-06 | 崔清瑞 | Air-cooled integrated ozone producer electric discharge device |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN105217577A (en) * | 2015-10-09 | 2016-01-06 | 崔清瑞 | Air-cooled integrated ozone producer electric discharge device |
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Effective date of registration: 20181112 Address after: 100000 meters southeast of Caoyuan Village Committee, Liyuan Town, Tongzhou District, Beijing Patentee after: Beijing Zhongrui Zhongtian Technology Co., Ltd. Address before: No. 5, 3, Building 7, Xili Nursery, Fengtai District, Beijing, 100000 Patentee before: Cui Qingrui |