CN114751383A - Integrated ozone generation module - Google Patents

Abstract

The embodiment of the invention provides an integrated ozone generation module, which comprises a first end cover positioned at a first end, a second end cover positioned at a second end, a first ground electrode and a second ground electrode which are arranged between the first end cover and the second end cover, and a high-voltage discharge device arranged between the first ground electrode and the second ground electrode; wherein the first ground electrode and the second ground electrode each have a micro air passage in the opposite face and an air distribution passage in the opposite face and a through hole communicating the micro air passage and the air distribution passage.

Description

Integrated ozone generation module

Technical Field

The invention relates to the field of ozone generators, in particular to an integrated ozone generation module. The invention also relates to a related ozone generator.

Background

Ozone is a strong oxidant, and can be effectively sterilized, so that it is widely used in the fields requiring sterilization or disinfection, such as environmental protection, medical treatment, water treatment, pharmacy, food preparation, cosmetic preparation, and the like.

To this end, various ozone generators and related apparatus are currently proposed, which are typically implemented using an electrical discharge to produce a low temperature plasma gas.

Common types of ozone generators include tubular, tank, or cabinet type ozone generators. However, these ozone generators are often customized to specific needs, and the ozone generators themselves are poorly scalable. Moreover, these ozone generators are usually large or attached to large facilities and cannot flexibly meet various needs of users.

The present inventors are also aware of certain expandable plate-type structure ozone generators, but they still suffer from a large footprint.

In view of the above, there is a need to provide a plate-type ozone generating structure that is compact so as to be suitable for a small ozone generator that is convenient to carry.

The above description is merely provided as background for understanding the relevant art in the field and is not an admission that it is prior art.

Disclosure of Invention

Therefore, the embodiment of the invention provides an integrated ozone generation module, which has a compact structure, is suitable for a portable small ozone generator, and has relatively high gas production efficiency.

According to a first aspect, an integrated ozone generation module is provided, which comprises a first end cap at a first end, a second end cap at a second end, a first ground electrode and a second ground electrode arranged between the first end cap and the second end cap, and a high voltage discharge device arranged between the first ground electrode and the second ground electrode. The manner in which the pair of ground electrodes are clamped by means of the end caps allows a compact ozone generating module structure to be achieved, in particular so that the ground electrodes or other module components are easy to manufacture while ensuring that a relatively small area of the ground electrodes is present.

In one embodiment, the first ground electrode includes a contact surface formed in an opposite surface facing the second ground electrode to be proximate to the high voltage discharge device and at least one micro air channel formed recessed from the contact surface. In one embodiment, the first ground electrode includes a first air distribution passage and a second air distribution passage formed in a back-facing surface facing away from the second ground electrode. In one embodiment, the first ground electrode further includes a first through hole connecting the first air distribution passage with a first end of the micro air passage and a second through hole connecting the second air distribution passage with a second end of the micro air passage. Not only can greatly improve the convenience of manufacturing and installation through setting up reaction structures such as little gas channels and gas distribution structure separately at the opposite surface of ground electrode, but also importantly can allow the gas access structure still can conveniently install under the limited circumstances of volume space, has still guaranteed simultaneously even under very compact module structure, still can obtain efficient gas reaction efficiency.

In one embodiment, the second ground electrode includes a contact surface formed in an opposite surface facing the first ground electrode to be closely attached to the high-voltage discharge device and at least one micro air channel formed recessed from the contact surface. In one embodiment, the second ground electrode includes a first air distribution passage and a second air distribution passage formed in a back-facing surface facing away from the first ground electrode. In one embodiment, the second ground electrode further includes a plurality of first through holes communicating the first air distribution passage with a first end of the micro air passage and a plurality of second through holes communicating the second air distribution passage with a second end of the micro air passage.

In one embodiment, the first ground electrode includes a recessed region formed in an opposing face, the contact face and micro-airways being located within the recessed region. In one embodiment, the second ground electrode includes a recessed region formed in an opposing face, the contact face and the micro gas channel being located within the recessed region. The recessed region may be for receiving a high voltage discharge device.

In one embodiment, the recessed region of the second ground electrode is deeper than the recessed region of the first ground electrode.

In one embodiment, the first end cap includes a through vent hole communicating with the first air distribution passage of the first ground electrode. In one embodiment, the second end cap includes a vent hole therethrough in communication with the first air distribution passage of the second ground electrode.

In one embodiment, the first ground electrode includes a through vent hole connected to the second air distribution channel of the first ground electrode. In some embodiments, the second ground electrode includes a through vent hole connected to the second gas distribution passage of the second ground electrode.

In some embodiments, the vent holes of the end cap may be disposed adjacent to an end of the first cloth air duct. In some embodiments, the air vent holes of the first and second ground electrodes may be disposed adjacent to an end portion of the second air distribution duct.

In some embodiments, the vent of the first ground electrode is aligned with the vent of the second ground electrode.

Therefore, gas circulation can be formed through the vent hole of the first end cover, the first air distribution channel of the first ground electrode, the micro air channel (from the first end to the second end) of the first ground electrode, the second air distribution channel of the first ground electrode, the vent holes of the first ground electrode and the second ground electrode, the second air distribution channel of the second ground electrode, the micro air channel (from the second end to the first end) of the second ground electrode, the first air distribution channel of the second ground electrode and the vent hole of the second end cover (the flow in the positive direction and the negative direction is feasible). Such a structure allows the ozone generating module of the embodiment of the present invention to realize a considerably long effective gas reaction channel in an extremely compact structure, thereby effectively improving the gas production rate. This can sufficiently separate the inflow/outflow ports and allow them to be used interchangeably, thereby utilizing a relatively compact space.

In a further embodiment, the vent holes of the end cap and/or the vent holes of the first and second ground electrodes are located outside the envelope of the recessed region, thereby not only further extending the channel to improve the gas production rate relative to the compact structure of the ozone generating module, but also effectively ensuring that gas flow across the electrode plates does not affect the effective gas reaction under the compact structure.

In some embodiments, the vent of the end cap and/or the vent of the first and second ground electrodes are located at a corner of the end cap and/or the first and second ground electrodes. This enables full use of the space of the compact ozone generating module without affecting its effective function.

In some embodiments, the first ground electrode includes a distribution channel formed in a back-facing surface facing away from the second ground electrode for distributing a cooling fluid. In some embodiments, the second ground electrode includes a distribution channel formed in a back-facing surface facing away from the first ground electrode for distributing a cooling fluid. Not only can the ease of manufacture and installation be greatly improved by locating the flow structures of the cooling fluid on opposite surfaces of the ground electrode, but it is also important to be able to allow the fluid access structure to be conveniently installed with limited volumetric space while still ensuring efficient cooling efficiency even with a very compact modular structure.

In some embodiments, the first end cap includes a through-flow hole communicating with the routing channel of the first ground electrode. In some embodiments, the second end cap includes a through flow hole communicating with the cloth flow passage of the second ground electrode.

In some embodiments, the first ground electrode includes a through-flow hole connected to the routing channel of the first ground electrode. In some embodiments, the second ground electrode includes a through-flow hole connected to the flow distribution channel of the second ground electrode.

In some embodiments, the flow aperture of the end cap may be disposed adjacent an end (e.g., a first end) of the routing channel. In some embodiments, the through-holes of the first and second ground electrodes may be disposed adjacent to an end (e.g., the second end) of the routing channel.

In some embodiments, the through-hole of the first ground electrode is aligned with the through-hole of the second ground electrode.

Therefore, circulation of the through hole of the first end cover, the one end (such as the first end) of the distribution channel of the first ground electrode, the other end (such as the second end) of the distribution channel of the first ground electrode, the through hole of the second ground electrode, the one end (such as the second end) of the distribution channel of the second ground electrode, the other end (such as the first end) of the distribution channel of the second ground electrode and the through hole of the second end cover can be formed (the flow in the positive direction and the negative direction is feasible), so that a module cooling fluid distribution structure with extremely high compactness can be obtained, the flow path of the cooling fluid can be fully prolonged, the heat exchange effect of the cooling fluid is fully utilized, and the maximized cooling effect is obtained under the extremely compact structure. This can sufficiently separate the inflow/outflow ports and allow them to be used interchangeably, thereby utilizing a relatively compact space.

In some embodiments, the flow apertures of the end cap and/or the flow apertures of the first and/or second ground electrodes are located outside the envelope of the recessed region, which not only further extends the cooling path, but also effectively ensures cooling fluid flow across the electrode plates in a compact configuration without affecting effective gas reaction.

In some embodiments, the through-flow aperture of the end cap and/or the through-flow apertures of the first and second ground electrodes are located at a corner of the end cap and/or the first and second ground electrodes. This enables full use of the space of the compact ozone generating module without affecting its effective function.

In some embodiments, the vent hole of the end cap and/or the vent holes of the first and second ground electrodes are located at upper corners of the end cap and/or the first and second ground electrodes; the through-flow holes of the end cap and/or the through-flow holes of the first and second ground electrodes are located at lower corners of the end cap and/or the first and second ground electrodes.

In some embodiments, the first end cap further comprises a first sealing gasket arranged between the first end cap and the first ground electrode, and the second end cap further comprises a second sealing gasket arranged between the second end cap and the second ground electrode.

In some embodiments, the first gasket includes a flow channel hole aligned with the distribution channel of the first ground electrode, a first gas channel hole aligned with the first gas distribution channel of the first ground electrode, and a second gas channel hole aligned with the second gas distribution channel of the first ground electrode.

In some embodiments, the second gasket includes a flow passage hole aligned with the flow distribution passage of the second ground electrode, a first air passage hole aligned with the first air distribution passage of the second ground electrode, and a second air passage hole aligned with the second air distribution passage of the second ground electrode.

In some embodiments, the first gasket includes a sealing rib surrounding the flow passage aperture, a sealing rib surrounding the first air passage aperture, and a sealing rib surrounding the second air passage aperture.

In some embodiments, the second gasket includes a sealing rib surrounding the flow passage aperture, a sealing rib surrounding the first air passage aperture, and a sealing rib surrounding the second air passage aperture.

Preferably, the sealing rib is provided on a surface facing the end cap; the sealing rib is not provided at the surface facing the ground electrode, i.e., the surface facing the ground electrode is flat. This enables the tightening effect of the end caps to be fully exploited to achieve a good sealing effect at the same time without affecting the effective flow of gas/cooling fluid.

In some embodiments, the high voltage discharge device includes a first dielectric plate abutting the first ground electrode, a second dielectric plate abutting the second ground electrode, and a sealing gasket surrounding the first and second dielectric plates. Optionally, the high voltage discharge device comprises first and second heat conducting plates disposed between the first dielectric plate and the second dielectric plate. In some embodiments, the seal gasket includes a joint portion for electrically connecting the high voltage fuse and at least one resilient conductive tab extending from the joint portion, the resilient conductive tab abutting the first and second dielectric plates.

According to a second aspect, there is provided an ozone generator comprising an integrated ozone generating module according to any of the embodiments of the present invention.

According to a third aspect, a ground electrode for an ozone generator is provided, the ground electrode having a first surface and an opposing second surface. The ground electrode includes a contact surface formed on one of the first and second surfaces for abutting the high voltage discharge device and at least one micro-air channel formed recessed from the contact surface. The ground electrode includes a first air distribution passage and a second air distribution passage formed in the other of the first and second surfaces. The ground electrode further comprises a first through hole connecting the first air distribution channel with the first end of the micro air channel and a second through hole connecting the second air distribution channel with the second end of the micro air channel.

The ground electrode according to embodiments of the invention may be a single piece as such, without the need for a blocking element, and without the need for further accessories, such as a flow channel blocking element.

In some embodiments, the ground electrode includes a routing channel formed in the other of the first and second surfaces for distributing a cooling fluid.

In some embodiments, the ground electrode includes a through vent hole connected to the second gas distribution channel of the ground electrode.

In some embodiments, the first ground electrode includes a through-flow hole connected to the routing channel of the first ground electrode.

In some embodiments, the ground electrode includes a recessed region formed in one of the first and second surfaces, the contact surface and at least one micro air via being located in the recessed region.

In some embodiments, the vent hole is located at an end of the second cloth air duct and outside an envelope of the recessed area.

In some embodiments, the through-flow aperture is located at an end of the second gas distribution channel outside an envelope of the recessed region.

Additional features and advantages of embodiments of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following.

Drawings

Embodiments of the invention will hereinafter be described in detail with reference to the accompanying drawings, illustrated elements not limited to the scale shown in the drawings, wherein like or similar reference numerals denote like or similar elements, and wherein:

figures 1A-1F illustrate various views of an integrated ozone generation module according to an embodiment of the present invention;

fig. 2A to 2E illustrate various views of a first ground electrode according to an embodiment of the present invention;

FIGS. 3A to 3G show a plurality of views of a second ground electrode according to an embodiment of the present invention;

4A-4C illustrate various views of an end cap according to an embodiment of the invention;

fig. 5A to 5D show various views of a high voltage fuse according to an embodiment of the present invention.

List of reference numerals

20. A plate-type ozone generating module; 200. an opposite face; 202. back to face;

21. a first ground electrode; 210. a contact surface; 2100. a recessed region; 211. distributing a flow channel; 212. a micro-airway; 2121. a recess; 2122. a recess; 213. a first air distribution groove; 214. a second air distribution groove; 215. A first through hole; 216. a second through hole; 217. a through-flow aperture; 218. a vent hole;

22. a second ground electrode; 220. a contact surface; 2200. a recessed region; 221. distributing a flow channel; 222. a micro-airway; 2221. a recess; 2222. a recess; 223. a first air distribution groove; 224. a second air distribution groove; 225. A first through hole; 226. a second through hole; 227. a through-flow aperture; 228. a vent hole; 229. accommodating grooves;

23. a first end cap; 237. a through-flow aperture; 238. a vent hole;

24. a second end cap; 237. a through-flow aperture; 238. a vent hole;

25. a first gasket; 251. a flow passage hole; 2511. sealing the convex edge; 253. a first gas passage hole; 2531. Sealing the convex edge; 254. a second airway hole; 2541. sealing the convex edge;

26. A second gasket; 261. a flow passage hole; 2611. sealing the convex edge; 263. a first gas passage hole; 2531. sealing the convex edge; 264. a second airway hole; 2641. sealing the convex edge;

32. a high voltage safety device; 321. a first conductive wire 322, a second conductive wire 323, a first elastic insulating sheath; 324. a second elastic insulating sheath; 325. a fuse tube; 326. a thermally conductive insulating plate; 3260. 3262, 3264, slot; 3261. 3263, 3265, positioning acute angle; 3266. 3267, spacer portions; 3268. 3269, an electrical connection; 327. an insulating and heat insulating film; 328. fusing the wires; 329. extinguishing the particles;

40. a high voltage discharge device; 41. a heat conducting plate; 411. a notch; 42. a heat conducting plate; 421. a notch; 43. A dielectric plate; 44. a dielectric plate; 45. a sealing gasket; 450. a seal washer body; 451. an elastic conductive sheet; 452. an elastic conductive sheet; 453. a joint part.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the following detailed description and accompanying drawings. The exemplary embodiments and descriptions of the present invention are provided to explain the present invention, but not to limit the present invention.

In the description herein of the "ground electrode" and the "high-voltage discharge device" and the plate-like member thereof, the "surface" refers to the side of the extended surface of the plate, and may also be referred to as the "plate surface", without being limited to a plane and may have different heights (e.g., depressions or protrusions) on the same "surface"; "side" refers to the narrow sides of the board other than the top and bottom.

In this document, "first" and "second" do not denote relative importance or order, but rather are used to distinguish one element or feature from another.

In embodiments of the present invention, an ozone generator, in particular an ozone generator of an integrated ozone generation module based on a plate-like structure, and related ozone generator components are provided. The integrated ozone generating module may include a pair of end caps, a pair of ground electrodes between the end caps, and a high voltage discharge device between the pair of ground electrodes. The pair of end caps may, for example, act to tighten the stacked components.

In some embodiments of the invention, the integrated ozone generation module can be applied in portable ozone generator or small/micro ozone generator (e.g. 30g output) applications, the ozone generation module (ground electrode) for example being non-scalable.

In an embodiment of the present invention, the ozone generator, for example, a miniature or micro-miniature ozone generator, may further comprise a high voltage safety device integrated in the ozone generating module or independent thereof, which is electrically connected to the high voltage discharge device, for example, by a plug (not shown). A high voltage fuse device according to one embodiment of the present invention is shown, for example, in fig. 5A to 5D.

In an embodiment of the present invention, the ozone generator, for example, a miniature or micro-miniature ozone generator, may further comprise a plurality of electrical elements, for example, which supply power to the ozone generating module and/or provide control, monitoring, and display functions. In embodiments of the invention, the ozone generator, e.g. a miniature or micro-miniature ozone generator, may further comprise optional cooling fluid and/or gas lines and/or connections.

Exemplary illustrative embodiments of the invention are described below with reference to the accompanying drawings.

As shown in fig. 1 to 1F, the integrated ozone generating module 20 according to the embodiment of the present invention may include a first end cap 23 at a first end, a second end cap 24 at a second end, a first ground electrode 21 (adjacent to the first end cap 23) and a second ground electrode 22 (adjacent to the second end cap 24) disposed between the first end cap and the second end cap, and a high voltage discharging device 40 disposed between the first ground electrode and the second ground electrode. In the illustrated embodiment, the integrated ozone generating module 20 may include a first gasket 25 disposed between the first end cap 23 and the first ground electrode 21 and a second gasket 26 disposed between the second end cap 24 and the second ground electrode 22. The clamping of the ground electrode pair by means of the end caps allows a compact ozone generating module construction to be achieved, in particular in such a way that the ground electrodes or other module components are easy to manufacture while ensuring that a relatively small area of the ground electrodes is available.

In the embodiment shown, the end caps, ground electrode and optional sealing gasket are provided in pairs. Thus, they each have opposite faces facing each other and opposite back faces facing each other. Here, in the illustrated embodiment, the opposite faces of the first end cap 23, the first ground electrode 21 and the optional first gasket 25 are in the same direction as the opposite faces of the second end cap 24, the second ground electrode 22 and the optional second gasket 26, which may be referred to as first surfaces, for example. Similarly, in the illustrated embodiment, the opposite faces of the first end cap 23, the first ground electrode 21 and the optional first gasket 25 are in the same direction as the opposite faces of the second end cap 24, the second ground electrode 22 and the optional second gasket 26, for example referred to as second surfaces. Accordingly, the surfaces of the high voltage discharge device 40 and its components may also be similarly defined.

Thus, in some embodiments of the invention, a ground electrode for an ozone generator may be provided. The ground electrode may include a contact surface formed at one of the first and second surfaces for abutting the high voltage discharge device and at least one micro air channel formed recessed from the contact surface. In some embodiments of the present invention, the ground electrode includes a first air distribution passage and a second air distribution passage formed in the other of the first and second surfaces. In some embodiments of the present invention, the ground electrode further includes a first through hole connecting the first air distribution passage with a first end of the micro air passage and a second through hole connecting the second air distribution passage with a second end of the micro air passage. In some embodiments, the ground electrode includes a through vent hole connected to the second gas distribution channel of the ground electrode. In some embodiments, the ground electrode includes a routing channel formed in the other of the first and second surfaces for distributing a cooling fluid. In some embodiments, the first ground electrode includes a through-flow hole connected to a routing channel of the first ground electrode. In some embodiments, the ground electrode includes a recessed region formed in one of the first and second surfaces, the contact surface and at least one micro air via being located in the recessed region. In some embodiments, the vent hole is located at an end of the second air distribution duct and outside an envelope of the recessed region. In some embodiments, the through-flow aperture is located at an end of the second gas distribution channel outside an envelope of the recessed region. The ground electrode according to embodiments of the invention may be a single piece as such, without the need for a blocking element, and without the need for further accessories, such as a flow channel blocking element.

Here, in the ground electrode in some embodiments of the present invention, the contact surface and the micro air channel are provided on the first surface, and the air distribution channel are provided on the second surface. In some embodiments of the invention, the ground electrode is provided with a contact surface and a micro air channel on the second surface, and the air channel are arranged on the first surface.

The exemplary embodiments shown are described below in conjunction with the accompanying drawings.

Referring to fig. 1A to 1F in combination with fig. 2A to 2E, a first ground electrode 21 according to an embodiment of the present invention is shown. As shown, the first ground electrode 21 may include a contact surface 210 formed in an opposite surface 200 (e.g., a first surface) facing the second ground electrode to be proximate to the high-voltage discharge device 40 and at least one, e.g., a plurality of micro air channels 212 (three here) recessed from the contact surface. As best shown in fig. 2C, the micro-airways are horizontally extending.

With continued reference to fig. 2A through 2E, the first ground electrode 21 may include a recess region 2100 formed in the opposite face 200. As best shown in fig. 2C, the contact surface 210 and micro-airways 212 are located within the recessed region 2100.

Referring to fig. 1A to 1F in combination with fig. 2A to 2E, the first ground electrode 21 includes a first air distributing passage 213 and a second air distributing passage 214 formed in a back-facing surface 202 (e.g., a second surface) facing away from the second ground electrode. In the illustrated embodiment, the first and second gas distribution channels may be arranged in an L-shape, and optionally symmetrically with respect to each other. As best shown in fig. 2A, the first ground electrode may further include first through holes 215 (three in this case) connecting the first air distribution passage 213 with a first end of the micro air passage 212 and second through holes 216 (three in this case) connecting the second air distribution passage 214 with a second end of the micro air passage 212. As best shown in fig. 2C, a dimple 2121 may be formed at an end (first end) of the micro-airway 212 that is recessed from the micro-airway, the first through-hole 215 being located in the dimple 2121. Similarly, a dimple 2122 may be formed at the end (second end) of the micro-airway 212 that is recessed from the micro-airway, the second through-hole 216 being located in the dimple 2122. The concave seat is arranged to be beneficial to smooth reaction airflow and improve the gas reaction efficiency.

Here, not only can the convenience of manufacturing and installation be greatly improved by dividing the reaction structure such as the micro gas channel and the gas distribution structure on the opposite surface of the ground electrode, but also it is important to allow the gas access structure to be conveniently installed under the condition that the volume space is limited, and at the same time, it is ensured that the efficient gas reaction efficiency can be obtained even under the very compact module structure.

Referring back to fig. 1A-1F and 4A-4C, the first end cap 23 may include a vent 238. As best shown in fig. 1F and 1D, the first end cap 23 may include a through vent hole 238 communicating with the first air distribution passage 213 of the first ground electrode 21. Referring to fig. 1A to 1F and 2A to 2E in combination, the vent hole 238 of the first end cap 23 may be disposed adjacent to an end of the first air distribution passage 213 of the first ground electrode 21.

With continued reference to fig. 2A to 2E, the first ground electrode 21 may include a through vent hole 218 connected to the second air distribution passage 214 of the first ground electrode 21. As best shown in fig. 2A, the vent hole 218 of the first ground electrode 21 may be disposed adjacent to an end of the second air duct 214.

As shown in fig. 1A to 1F and fig. 2A to 2E and fig. 4A to 4C, the vent hole 238 of the first end cap 23 may be located outside the envelope of the recessed region 2100 of the first ground electrode 21, i.e., the vent hole 238 is located outside the recessed region 2100 in plan projection. As shown in fig. 1A to 1F and fig. 2A to 2E, the vent hole 218 of the first ground electrode 21 may be located outside an envelope of the concave region 2100 of the first ground electrode 21. From this, not only can further prolong the passageway in order to improve the gas yield for the compact structure of this ozone generation module, still can effectively guarantee under compact structure moreover to stride the gas circulation of electrode board and can not influence effectual gas reaction.

As shown in fig. 1A to 1F and fig. 2A to 2E and fig. 4A to 4C, the vent hole 238 of the first end cap 23 and/or the vent hole 218 of the first ground electrode 21 may be located at a corner of the first end cap and/or the first ground electrode. For example, in the illustrated embodiment, the vent 238 may be located in the upper right corner of the first end cap (also corresponding to the first ground electrode) opposite; the vent hole 218 may be located in the upper left corner of the first ground electrode (also corresponding to the first end cap) facing away from. This enables full use of the space of the compact ozone generating module without affecting its effective function.

As shown in fig. 1A to 1F and fig. 2A to 2E, the first ground electrode 21 according to the embodiment of the present invention may further include a distribution passage 211 formed in the opposite surface 202 opposite to the second ground electrode 22 for distributing a cooling fluid. Here, not only the convenience of manufacture and installation can be greatly improved by providing the flow structure of the cooling fluid on the opposite surface of the ground electrode, but it is also important to allow the fluid inlet structure to be conveniently installed with a limited volume space while also ensuring that efficient cooling efficiency can be obtained even in a very compact module structure.

As in the embodiment shown in fig. 2A, the routing path 211 of the first ground electrode 21 may be meandered in the back-to-back surface 202 (second surface).

Referring back to fig. 1A-1F, the first end cap 23 may include a through flow hole 237. As best shown in fig. 1F and 1D, the first end cap 23 may include a through-flow hole 237 communicating with the routing channel 211 of the first ground electrode 21. Referring to fig. 1A to 1F and 2A to 2E in combination, the through-hole 237 of the first cap 23 may be disposed adjacent to an end (e.g., a first end) of the routing channel 211 of the first ground electrode 21.

With continued reference to fig. 2A to 2E, the first ground electrode 21 may include a through-flow hole 217 connected to the routing channel 211 of the first ground electrode 21. As best shown in fig. 2A, the through-hole 217 of the first ground electrode 21 may be disposed adjacent to an end (e.g., a second end) of the routing channel 211.

As shown in fig. 1A-1F and 2A-2E, flowbore 237 of first end cap 23 may be located outside the envelope of recessed region 2100. As shown in fig. 1A to 1F and fig. 2A to 2E, the through-holes of the first ground electrodes 21 may be located outside the envelope of the depression region 2100. This not only further lengthens the cooling path but also effectively ensures cooling fluid flow across the electrode plates in a compact configuration without affecting the effective gas reaction.

As shown in fig. 1A to 1F and fig. 2A to 2E, the through-holes 237 of the first end cap 23 and/or the through-holes 217 of the first ground electrode 21 are located at corners of the first end cap 23 and/or the first ground electrode 21. For example, in the illustrated embodiment, the through-flow hole 237 may be located in the lower right corner of the first end cap (also corresponding to the first ground electrode) facing away from; flow-through hole 217 may be located in the lower left corner of the first ground electrode (also corresponding to the first end cap) facing away from. This enables full use of the space of the compact ozone generating module without affecting its effective function.

In the embodiment shown in fig. 1A to 1F, the vent hole and the through-flow hole of the first end cap and the vent hole and the through-flow hole of the first ground electrode are located at four corners of the end cap and/or the first ground electrode, respectively, wherein the vent hole is located at an upper corner and the through-flow hole is located at a lower corner.

Referring to fig. 1A to 1F in combination with fig. 3A to 3G, the second ground electrode 22 according to the embodiment of the present invention is shown. As shown, the second ground electrode 22 may include a contact surface 220 formed in an opposite surface 200 (e.g., a second surface) facing the first ground electrode to abut the high voltage discharge device 40 and at least one, e.g., a plurality of micro air channels 222 (three here) recessed from the contact surface. As best shown in fig. 3C, the micro-airways are horizontally extending.

With continued reference to fig. 3A-3G, the second ground electrode 22 may include a recessed region 2200 formed in the opposing face 200. As best shown in fig. 3C, the contact surface 220 and the micro-airways 222 are located within the recessed region 2200. In an embodiment of the present invention, the recessed region 2200 of the second ground electrode may be deeper than the recessed region 2100 of the first ground electrode, but it is conceivable to have the same depth or vice versa. As best shown in fig. 3B and 3C, the second ground electrode 22 may further include a receiving groove 229 for receiving the joint portion 453 of the high voltage discharge device 40. The receiving groove 229 may communicate with the recessed region 2200.

Referring to fig. 1A to 1F in combination with fig. 3A to 3G, the second ground electrode 22 includes a first air distribution passage 223 and a second air distribution passage 224 formed in a back-facing surface 202 (e.g., a first surface) that faces away from the first ground electrode. In the illustrated embodiment, the first and second gas distribution channels may be arranged in an L-shape, and optionally symmetrically with respect to each other. As best shown in fig. 2A, the first ground electrode may further include first through holes 225 (three in this case) connecting the first air distribution passage 223 with a first end of the micro air passage 222 and second through holes 216 (three in this case) connecting the second air distribution passage 226 with a second end of the micro air passage 222. As best shown in fig. 2C, a recess 2221 recessed from the micro-airway may be formed at the end (first end) of the micro-airway 222, the first through-hole 225 being located in the recess 2221. Similarly, at the end (second end) of the micro-airway 212 may be formed a recess 2222 recessed from the micro-airway, the second through-hole 216 being located in the recess 2222. The concave seat is arranged to be beneficial to smooth reaction airflow and improve the gas reaction efficiency.

Here, not only can the convenience of manufacturing and installation be greatly improved by separately arranging the reaction structure such as micro gas channel and the gas distribution structure on the opposite surface of the ground electrode, but also it is important to allow the gas access structure to be conveniently installed under the condition that the volume space is limited, and at the same time, it is ensured that the efficient gas reaction efficiency can be obtained even under the very compact module structure.

Referring back to fig. 1A-1F, the second end cap 24 may include a vent hole 248. As best shown in fig. 1F and 1D, the second end cap 24 may include a vent hole 248 communicating with the first air distribution passage 223 of the second ground electrode 22. Referring to fig. 1A to 1F and 3A to 3G in combination, the vent hole 248 of the second end cap 24 may be disposed adjacent to the end of the first air distribution passage 223 of the second ground electrode 22.

With continued reference to fig. 3A-3G, the second ground electrode 22 may include a vent hole 228 therethrough in communication with the second air distribution passage 224 of the second ground electrode 22. As best shown in fig. 3A, the vent hole 228 of the second ground electrode 22 may be disposed adjacent to an end of the second air distribution passage 224.

As shown in fig. 1A to 1F and 3A to 3G, the vent hole 248 of the second end cap 24 may be located outside the envelope of the recessed region 2200 of the second ground electrode 22. As shown in fig. 1A to 1F and fig. 3A to 3G, the vent hole 228 of the second ground electrode 22 may be located outside the envelope of the recessed region 2200 of the second ground electrode 22. From this, not only can further prolong the passageway in order to improve the gas yield for the compact structure of this ozone generation module, still can effectively guarantee under compact structure moreover to stride the gas circulation of electrode board and can not influence effectual gas reaction.

As shown in fig. 1A to 1F and 3A to 3G, the vent hole 248 of the second end cap 24 and/or the vent hole 228 of the second ground electrode 22 may be located at a corner of the second end cap and/or the second ground electrode. For example, in the illustrated embodiment, the vent 248 may be located in the upper left corner of the opposite face of the second endcap (also corresponding to the second ground electrode) (the upper right corner of the opposite face of the second endcap/second ground electrode); the vent hole 228 may be located in the upper right corner of the back-to-front face of the second ground electrode (also corresponding to the second end cap) (upper left corner of the second end cap/second ground electrode opposing face). This enables full use of the space of the compact ozone generating module without affecting its effective function.

As shown in fig. 1A to fig. 1F and fig. 3A to fig. 3G, the second ground electrode 22 according to the embodiment of the present invention may further include a distribution passage 221 formed in the opposite surface 202 opposite to the second ground electrode 22 for distributing the cooling fluid. Here, not only can the convenience of manufacture and installation be greatly improved by providing the flow structure of the cooling fluid on the opposite surface of the ground electrode, but it is also important to be able to allow the fluid access structure to be conveniently installed with a limited volume space while also ensuring that efficient cooling efficiency can be obtained even in a very compact module structure.

In the embodiment shown in fig. 2A, the routing path 221 of the second ground electrode 22 may be meandered in the back-facing surface 202 (first surface).

Referring back to fig. 1A-1F, the second end cap 24 may include a through-flow aperture 247. As best shown in fig. 1F and 1D, the second end cap 24 may include a through-flow hole 247 communicating with the flow path 221 of the second ground electrode 22. Referring to fig. 1A to 1F and fig. 3A to 3G in combination, the through hole 247 of the second end cap 24 may be disposed adjacent to an end (e.g., a first end) of the distribution passage 221 of the second ground electrode 22.

With continued reference to fig. 3A to 3G, the second ground electrode 22 may include a through-flow hole 227 connected to the flow path 221 of the second ground electrode 22. As best shown in fig. 3A, the through hole 227 of the second ground electrode 22 may be disposed adjacent to an end (e.g., a second end) of the routing channel 221.

As shown in fig. 1A-1F and 3A-3G, the flowbore 247 of the second end cap 24 may be located outside the envelope of the recessed region 2100. As shown in fig. 1A to 1F and fig. 3A to 3G, the through-hole of the second ground electrode 22 may be located outside the envelope of the recessed region 2200. This not only further lengthens the cooling path but also effectively ensures cooling fluid flow across the electrode plates in a compact configuration without affecting the effective gas reaction.

As shown in fig. 1A to 1F and fig. 3A to 3G, the through-hole 247 of the second end cap 24 and/or the through-hole 227 of the second ground electrode 22 are located at the corner of the second end cap 24 and/or the second ground electrode 22. For example, in the illustrated embodiment, vent hole 247 may be located in the lower left corner of the opposite side of the second endcap (also corresponding to the second ground electrode) (lower right corner of the opposite side of the second endcap/second ground electrode); flow aperture 227 may be located in the lower right corner of the opposite face of the second ground electrode (also corresponding to the second end cap) (lower left corner of the opposite face of the second end cap/second ground electrode). This enables full use of the space of the compact ozone generating module without affecting its effective function.

In the embodiment shown in fig. 1A to 1F, the vent hole and the through hole of the second end cap and the vent hole and the through hole of the second ground electrode are respectively located at four corners of the end cap and/or the second ground electrode, wherein the vent hole is located at an upper corner, and the through hole is located at a lower corner.

Referring back to fig. 1A-1F in conjunction with fig. 2A-2E and 3A-3G, in the assembled integrated ozone generation module, the vent hole 218 of the first ground electrode 21 can be aligned with the vent hole 228 of the second ground electrode 22 (e.g., both in the upper right corner of the first surface/the upper left corner of the second surface). Optionally, the vent holes 238 of the first end cap may overlap/align with the vent holes 248 of the second end cap in a planar projection (e.g., both in the upper left corner of the first surface/the upper right corner of the second surface).

Thus, gas circulation can be formed through the vent hole 238 of the first end cap 23, the first gas distribution passage 213 of the first ground electrode 21, the micro-gas passage 212 (from the first end to the second end) of the first ground electrode 21, the second gas distribution passage 214 of the first ground electrode 21, the vent hole 218 of the first ground electrode 21 and the vent hole 228 of the second ground electrode 22, the second gas distribution passage 226 of the second ground electrode 22, the micro-gas passage 222 (from the second end to the first end) of the second ground electrode 22, the first gas distribution passage 224 of the second ground electrode 22, and the vent hole 248 of the second end cap 24 (both forward and reverse flows are possible). Such a structure allows the ozone generating module of the embodiment of the present invention to realize a considerably long effective gas reaction channel in an extremely compact structure, thereby effectively improving the gas production rate. This can sufficiently separate the inflow/outflow ports, thereby utilizing a relatively compact space.

Also, this configuration may allow separate vents to be used interchangeably. For example, in some embodiments, the vent 238 may be used as a reactant gas inlet and the vent 248 as an ozone outlet, i.e., a reaction/flow path from the vent of the first end cap to the vent of the second end cap. In some embodiments, the vent hole 248 may be used as a reactant gas inlet and the vent hole 238 as an ozone outlet, i.e., a reaction/flow path from the vent hole of the second end cap to the vent hole of the first end cap. This is particularly advantageous in small, miniature applications, as it provides flexibility in terms of installation space.

Similarly, referring back to fig. 1A-1F in conjunction with fig. 2A-2E and 3A-3G, in the assembled integrated ozone generation module, the through-holes 217 of the first ground electrode 21 can be aligned with the through-holes 227 of the second ground electrode 22 (e.g., both at the bottom right corner of the first surface/bottom left corner of the second surface). Optionally, the flow aperture 237 of the first end cap may overlap/align with the flow aperture 247 of the second end cap in a planar projection (e.g., both in the lower left corner of the first surface/the lower right corner of the second surface).

Accordingly, it is possible to form the circulation through the through hole 237 of the first end cap 23, the one end (e.g., the first end) of the distribution passage 211 of the first ground electrode 21, the other end (e.g., the second end) of the distribution passage 211 of the first ground electrode 21, the through hole 217 of the first ground electrode 21, the through hole 227 of the second ground electrode 22, the one end (e.g., the second end) of the distribution passage 221 of the second ground electrode, the other end (e.g., the first end) of the distribution passage 221 of the second ground electrode 22, and the through hole 247 of the second end cap 24 (both the forward and reverse directions of the flow are possible), so that not only can the module cooling fluid distribution structure having an extremely high compactness be obtained, but also the cooling fluid flow path can be sufficiently extended, the heat exchange effect of the cooling fluid can be sufficiently utilized, and the maximized cooling effect can be obtained in an extremely compact structure. This can sufficiently separate the inflow/outflow ports, thereby utilizing a relatively compact space.

Also, this configuration may allow separate flow apertures to be used interchangeably. For example, in some embodiments, flow bore 237 may be used as a cooling fluid inlet and flow bore 247 may be used as a cooling fluid outlet, i.e., a cooling fluid flow path from the flow bore of the first end cap to the flow bore of the second end cap. In some embodiments, the vent holes 247 may serve as cooling fluid inlets and the through-flow holes 237 serve as cooling fluid outlets, i.e., cooling fluid flow paths from the through-flow holes of the second end cap to the through-flow holes of the first end cap. This is particularly advantageous in small, miniature applications, as it provides flexibility in terms of installation space.

It will be appreciated by those skilled in the art that unless otherwise specified (e.g., through vent/through-flow apertures, etc.), the micro-vias and gas-distributing structures provided on opposite surfaces of the ground electrode in the illustrated embodiment are in the form of sinks.

With continued reference to fig. 1A to 1F, the first sealing gasket 25 may include a flow passage hole 251 aligned with the gas distribution passage 211 of the first ground electrode 21, a first gas passage hole 253 aligned with the first gas distribution passage 213 of the first ground electrode 21, and a second gas passage hole 254 aligned with the second gas distribution passage 214 of the first ground electrode 21. As best shown in fig. 1F, the first sealing gasket 25 may include a sealing rib 2511 surrounding the flow passage hole 251, a sealing rib 2531 surrounding the first air passage hole 253, and a sealing rib 2541 surrounding the second air passage hole 254.

With continued reference to fig. 1A to 1F, the second gasket 26 may include a flow passage hole 261 aligned with the flow distribution passage 221 of the second ground electrode 22, a first air passage hole 263 aligned with the first air distribution passage 223 of the second ground electrode 22, and a second air passage hole 264 aligned with the second air distribution passage 224 of the second ground electrode 22. Although not shown, the second gasket may also include a sealing rib surrounding the flow passage hole, a sealing rib surrounding the first air passage hole, and a sealing rib surrounding the second air passage hole.

FIG. 1F best illustrates that a sealing fin according to an embodiment of the invention may be provided on the surface facing the end cap; the sealing rib is not provided at the surface facing the ground electrode, i.e., the surface facing the ground electrode is flat. This enables the tightening effect of the end caps to be fully exploited to achieve a good sealing effect at the same time without affecting the effective flow of gas/cooling fluid.

And more particularly to fig. 1F, a high voltage discharge apparatus 40 in accordance with an embodiment of the present invention is shown. The high voltage discharge device 40 may include a first dielectric plate 43 closely attached to the first ground electrode 21, a second dielectric plate 44 closely attached to the second ground electrode 22, and a sealing gasket 45 surrounding the first and second dielectric plates 43 and 44. In the illustrated embodiment, the high voltage discharge device 40 optionally includes first and second thermally conductive plates 41, 42 disposed between a first dielectric plate 43 and a second dielectric plate 44. The illustrated heat-conducting plate can provide a good uniform heat load effect.

In the illustrated embodiment, the sealing gasket 45 may include a joint 453 for electrically connecting the high voltage fuse and at least one resilient conductive sheet, two in the illustrated embodiment, a first resilient conductive sheet 451 and a second resilient conductive sheet 452, extending from the joint, which may abut the first and second dielectric sheets, respectively. As shown in fig. 1F, the connector portion 453 can be sleeved with a connector (not shown) to connect a high voltage fuse. In the embodiment shown, the heat-conducting plates 41, 42 may comprise notches 411 and 421 for housing the elastic conducting plates. As shown in fig. 1F, the sealing gasket 45 may further include a sealing gasket body having a frame shape to receive the dielectric plate and the optional heat conductive plate therein. In the illustrated embodiment, the tab portion 453 of the sealing gasket 45 is received in the receiving groove 229 as previously described, while the sealing gasket body 450 may be received in and constrained by the recessed areas 2100, 2200.

Referring to fig. 5A-5D, an embodiment of a high voltage fuse 32 is shown, such as may be used in an integrated ozone generation module according to an embodiment of the present invention. The illustrated high voltage fuse 32 may include a first wire 321 at a first end; a second wire 322 at a second end; a fuse 325; a thermally conductive insulating plate 326 disposed within the fuse tube 325; at least one (illustratively one sheet of fully circumferentially wrapped) insulating and heat insulating film 327; a fuse 328 extending within the sealed chamber and connecting the first and second leads and an extinguishing particle 329 or an extinguishing fluid contained within the fuse 325. The extinguishing particles 329 are, for example, quartz sand. In the illustrated embodiment, the high voltage fuse 32 may further include a first resilient insulating sheath 323 disposed over the fuse tube at the first end and a second resilient insulating sheath 324 disposed over the fuse tube at the second end.

As shown in fig. 5A and 5C, the at least one insulating and heat insulating film 327 covers the heat conducting and insulating plate 326 to enclose the sealed cavity. Therefore, the high-voltage safety device for the ozone generator can have the capability of long-term stable operation and has extremely high safety. By way of explanation and not limitation, the thermally conductive insulating plate, in particular, on the one hand, allows the high temperatures which are subjected to severe conditions and which would normally cause fuses to be rapidly conducted away by means of the thermally conductive insulating plate, and also ensures that the thermally conductive dielectric insulating plate maintains a high structural stability; on the other hand, the fuse wire can effectively conduct extremely high temperature which is possibly caused when the fuse wire is in overload failure to the whole heat-conducting insulating plate, so that the insulating and heat-insulating film is melted and extinguishing particles or extinguishing fluid are caused to cover the fuse wire, and the phenomenon that fire is caused or the generated combustion is extinguished as soon as possible is avoided.

As shown in fig. 5D, the heat conductive and insulating plate 326 may include a plurality of elongated holes 3260, 3262, 3264 (for example, an odd number, here, 3) spaced apart in the axial direction, and a spacer portion 3266, 3267 located between the plurality of elongated holes. In some embodiments, the fusible link extends along the plurality of elongated holes and straddles the spacer. Thus, the operational stability and the structural strength of the high-voltage fuse device can be greatly improved by the fuse wire extending in the elongated hole and straddling the spacer. In the embodiment shown in fig. 5C, the fusible links extend along the plurality of elongated holes and alternately straddle the spacer portions on the top and bottom surfaces of the heat-conductive insulating plate. This can further balance fuse structure loading, providing greater operational stability and structure length.

As shown in fig. 5D, the elongated holes 3260, 3262, 3264 can include acute positioning angles 3261, 3263, 3265 at the axial ends. The acute angle can further increase the operational stability of the high-voltage fuse, which in particular allows better alignment of the wires and fuses at both ends.

As shown in fig. 5D, the high voltage fuse device further includes two electrical connection portions 3268, 3269 at both ends of the thermally conductive insulating plate for electrically connecting both ends of the fusible link to the first and second conductive wires, respectively. Referring collectively to fig. 5A and 5C, the electrical connections 3268, 3269 are encased between the thermally conductive and insulating plate and the insulating and thermally insulating film. Such an encapsulated electrical connection prevents the connection point from becoming the primary heat transfer point for fuse failure, which is believed to significantly improve the operational stability of the high voltage fuse. Preferably, the electrical connection is a weld, such as a solder.

In one embodiment, the thermally conductive and insulating plate is made of a high temperature resistant inorganic dielectric material, preferably ceramic.

In one embodiment, the safety tube is transparent, preferably a transparent quartz tube. This may provide better failure monitoring capabilities for the operator or monitoring device.

In some embodiments, the insulating and heat insulating film may have a melting point higher than that of the fuse.

Unless specifically stated otherwise, methods or steps recited in accordance with embodiments of the present invention do not necessarily have to be performed in a particular order and still achieve desirable results. In some embodiments, multitasking and parallel processing may also be possible or may be advantageous.

While various embodiments of the invention have been described herein, the description of the various embodiments is not intended to be exhaustive or to limit the invention to the precise forms disclosed, and features and components that are the same or similar to one another may be omitted for clarity and conciseness. As used herein, "one embodiment," "some embodiments," "examples," "specific examples," or "some examples" are intended to apply to at least one embodiment or example, but not to all embodiments, in accordance with the present invention. The above terms are not necessarily meant to refer to the same embodiment or example. Various embodiments or examples and features of various embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Exemplary systems and methods of the present invention have been particularly shown and described with reference to the foregoing embodiments, which are merely illustrative of the best modes for carrying out the systems and methods. It will be appreciated by those skilled in the art that various changes in the embodiments of the systems and methods described herein may be made in practicing the systems and/or methods without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (11)

1. An integrated ozone generation module is characterized by comprising a first end cover positioned at a first end, a second end cover positioned at a second end, a first ground electrode and a second ground electrode which are arranged between the first end cover and the second end cover, and a high-voltage discharge device arranged between the first ground electrode and the second ground electrode;

the first ground electrode includes a contact surface formed in an opposite surface facing the second ground electrode to be in close contact with the high-voltage discharge device and at least one micro air channel formed recessed from the contact surface;

the first ground electrode includes a first air distribution passage and a second air distribution passage formed in a back-facing surface facing away from the second ground electrode;

the first ground electrode further comprises a first through hole for connecting the first air distribution channel with the first end of the micro air channel and a second through hole for connecting the second air distribution channel with the second end of the micro air channel;

the second ground electrode includes a contact surface formed in an opposite surface facing the first ground electrode to be in close contact with the high-voltage discharge device and at least one micro air channel formed recessed from the contact surface;

the second ground electrode includes a first air distribution passage and a second air distribution passage formed in a back-to-back surface facing away from the first ground electrode;

The second ground electrode further comprises a plurality of first through holes which communicate the first air distribution channel with the first end of the micro air channel and a plurality of second through holes which communicate the second air distribution channel with the second end of the micro air channel.

2. The integrated ozone generation module as claimed in claim 1,

the first end cover comprises a through vent hole of a first air distribution channel communicated with the first ground electrode;

the second end cover comprises a through vent hole communicated with the first air distribution channel of the second ground electrode.

3. The integrated ozone generation module as claimed in claim 2,

the first ground electrode comprises a through air vent connected with the second air distribution channel of the first ground electrode;

the second ground electrode comprises a through vent hole connected with the second air distribution channel of the second ground electrode.

4. The integrated ozone generation module according to any one of claims 1 to 3,

the first ground electrode includes a distribution passage formed in a back-facing surface facing away from the second ground electrode for distributing a cooling fluid;

the second ground electrode includes a distribution passage formed in a back-facing surface facing away from the first ground electrode for distributing a cooling fluid.

5. The integrated ozone generation module as claimed in claim 4,

the first end cover comprises a through flow hole communicated with a cloth flow channel of the first ground electrode;

the second end cover comprises a through hole communicated with the cloth flow channel of the second ground electrode.

6. The integrated ozone generation module of claim 5,

the first ground electrode comprises a through hole which is connected with the distribution channel of the first ground electrode and penetrates through the distribution channel;

the second ground electrode comprises a through flow hole which is connected with the distribution channel of the second ground electrode and penetrates through the distribution channel.

7. The integrated ozone generation module of claim 4, further comprising a first gasket disposed between the first end cap and the first ground electrode and a second gasket disposed between the second end cap and the second ground electrode.

8. The integrated ozone generation module of claim 7,

the first sealing gasket comprises a flow channel hole aligned with the distribution channel of the first ground electrode, a first air channel hole aligned with the first air distribution channel of the first ground electrode and a second air channel hole aligned with the second air distribution channel of the first ground electrode;

The second is sealed to be filled up including aligning the runner hole of the cloth passageway of second ground electrode, aligning the first gas channel hole of the first cloth gas way of second ground electrode with align the second gas channel hole of the second cloth gas way of second ground electrode.

9. The integrated ozone generation module as claimed in claim 8,

the first gasket includes a sealing rib surrounding the flow passage hole, a sealing rib surrounding the first air passage hole, and a sealing rib surrounding the second air passage hole;

the second gasket includes a sealing rib surrounding the flow passage hole, a sealing rib surrounding the first air passage hole, and a sealing rib surrounding the second air passage hole.

10. The integrated ozone generation module according to any one of claims 1 to 9, wherein the high voltage discharge device comprises a first dielectric plate clinging to the first ground electrode, a second dielectric plate clinging to the second ground electrode, a sealing gasket surrounding the first dielectric plate and the second dielectric plate, and a first heat conduction plate and a second heat conduction plate which are optionally arranged between the first dielectric plate and the second dielectric plate, wherein the sealing gasket comprises a joint part used for electrically connecting the high voltage safety device and at least one elastic conducting strip extending from the joint part, and the elastic conducting strip is butted against the first dielectric plate and the second dielectric plate.

11. An ozone generator comprising an integrated ozone generation module according to any one of claims 1 to 10.

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