CN220449802U - Ozone generator module with multidimensional expandability - Google Patents

Abstract

The utility model discloses an ozone generator module with multi-dimensional expandability, which comprises an ozone generating set and an assembling platform, wherein the ozone generating set comprises N ozone generating units, the lower end surfaces of the ozone generating units are provided with an air flow input interface, an air flow output interface, a cooling water input interface and a cooling water output interface, the assembling platform penetrates through an air flow total input hole, an air flow total output hole, a cooling water total input hole and a cooling water total output hole along the length direction of the assembling platform, each interface of the lower end surfaces of the ozone generating units is correspondingly communicated with an air flow input connecting hole, an air flow output connecting hole, a cooling water input connecting hole and a cooling water output connecting hole of an installation plane respectively, the two ends of the assembling platform are flange end surfaces, and sealing grooves for accommodating sealing gaskets are arranged on the flange end surfaces; the ozone generator module is used for assembling a plurality of ozone generating units through the assembling platform, a plurality of total conveying holes are integrated in the assembling platform, the mounting is simple, the workload is small, and the multidimensional expansion can be performed according to the ozone supply demand and the space environment.

Description

Ozone generator module with multidimensional expandability

Technical Field

The utility model relates to the technical field of ozone generators, in particular to an ozone generator module with multidimensional expandability.

Background

Ozone has high oxidation characteristics and can be effectively sterilized, and therefore, the ozone generator is widely applied to various fields of sewage treatment, medical treatment and health, environmental protection industry and the like, the technology of the ozone generator has been developed continuously for centuries, wherein the plate-type DBD ozone generator has the basis of modular design due to the advantages of small volume, high efficiency, high cost performance and the like, the application range is wide, the market share is high, the plate-type DBD ozone generator still has a lot of improvement spaces for the modular design of the plate-type ozone generator in the prior art, such as poor expansibility, the ozone generator cannot be flexibly assembled according to the demand of unused supply and the space environment, the ozone generator is expanded from length, height or width, meanwhile, the modular assembly efficiency is low, standardized and series production is not easy to be carried out on a mounting platform, the workload of mounting connection is increased by times along with the increase of the ozone generator, and the modular development of the plate-type ozone generator is difficult to popularize.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provide an ozone generator module with multidimensional expandability so as to solve the problems in the prior art.

In order to achieve the above object, the technical scheme of the present utility model is as follows:

an ozone generator module with multidimensional expandability comprises an ozone generating group and an assembling platform for installing the ozone generating group, wherein the ozone generating group comprises N ozone generating units which are mutually parallel and are uniformly arranged along the length direction of the assembling platform, and N is more than or equal to 2;

the lower end face of the ozone generating unit is provided with an air flow input interface, an air flow output interface, a cooling water input interface and a cooling water output interface, and sealing ring grooves are respectively arranged on the air flow input interface, the air flow output interface, the cooling water input interface and the cooling water output interface, and sealing rings are embedded in the sealing ring grooves;

the upper plane of the assembly platform is an installation plane, the installation plane supports the lower end face of the ozone generating unit, and the air flow input interface, the air flow output interface, the cooling water input interface and the cooling water output interface are respectively correspondingly communicated with an air flow input connecting hole, an air flow output connecting hole, a cooling water input connecting hole and a cooling water output connecting hole which are arranged on the upper plane of the assembly platform, and are respectively sealed by sealing rings, and the lower ends of the air flow input connecting hole, the air flow output connecting hole, the cooling water input connecting hole and the cooling water output connecting hole are respectively communicated with the air flow input connecting hole, the air flow total output hole, the cooling water total input connecting hole and the cooling water total output connecting hole;

the flange end faces are arranged at two ends of the assembly platforms and are used for connecting adjacent assembly platforms in series, sealing grooves are formed in the flange end faces, sealing gaskets are arranged in the sealing grooves, orifices of the air flow total input holes, the air flow total output holes, the cooling water total input holes and the cooling water total output holes are all located at the bottoms of the sealing grooves, sealing gaskets are clamped between the sealing grooves of the adjacent assembly platforms, and communication holes are formed in the sealing gaskets corresponding to the positions of the orifices of the air flow total input holes, the air flow total output holes, the cooling water total input holes and the cooling water total output holes.

Preferably, positioning grooves are formed in two sides of the ozone generating unit, limiting plates are correspondingly arranged on two sides of the assembling platform in a detachable mode, limiting convex strips extending in the length direction are respectively arranged on one side face, opposite to the two limiting plates, of the two limiting plates, and the limiting convex strips are connected with the matched sides of the positioning grooves in an inserting mode.

Further preferably, the limiting plate is further integrally formed with a hanging part, and the hanging part is an inverted U-shaped hanging plate formed by outwards extending the other side surface of the limiting plate.

Further preferably, the mounting plane is provided with a fixing screw hole, and the fixing screw hole, the air flow input connecting hole, the air flow output connecting hole, the cooling water input connecting hole and the cooling water output connecting hole are linearly arranged along the width direction.

Still preferably, the ozone generating unit comprises two ground polar plates and a high-voltage component clamped between the two ground polar plates, two symmetrical discharge chambers are formed in the ozone generating unit, a plurality of cooling water flow channels, an air inlet flow channel and an air outlet flow channel are arranged in the ground polar plates, the cooling water flow channels are uniformly distributed on the cooling section layer in parallel, the cooling section layer is located under the discharge chambers, the air inlet flow channel comprises an air transmission branch and an air inlet branch which are connected in a communicating manner, the air outlet flow channel comprises an output branch and an air outlet branch which are connected in a communicating manner, the tail end of the air transmission branch is an air flow input interface, the tail end of the output branch is an air flow output interface, and the air transmission branch and the output branch are parallel to the cooling water flow channels and are all located on the cooling section layer.

Further preferably, the heat insulation composite pipe is arranged in the air flow total input hole and the cooling water total input hole in an interference mode, and the air flow input connecting hole and the cooling water input connecting hole are communicated with the heat insulation composite pipe.

Compared with the prior art, the ozone generator module with the multidimensional expandability is formed by assembling a plurality of ozone generating units through the assembling platform, the assembling platform is used as a base station for installing and supporting the ozone generating units, a plurality of total conveying holes for inputting and outputting air flow and cooling water flow are integrated in the assembling platform, and the ozone generating units are communicated through corresponding connecting holes on an installing plane, so that the ozone generator module is simple to install and small in installation workload, and is easy to realize expansion in the width direction because of no need of installing and arranging complicated air flow pipelines and cooling waterway pipelines, and in addition, the assembling platform can be used for carrying out serial assembly in the length direction and lamination expansion in the height direction, so that the ozone generator module can be subjected to multidimensional expansion according to ozone supply requirements and space environment, is easy to carry out multidimensional box-in assembly, and is beneficial to realizing standardized production of the module.

Drawings

FIG. 1 is a schematic view of an assembly structure of an ozone generator module of the present utility model extending in a longitudinal direction;

FIG. 2 is a schematic perspective view of an ozone generator module according to the present utility model;

FIG. 3 is a schematic perspective view of the assembled platform of FIG. 2;

FIG. 4 is a schematic cross-sectional view of the ozone generator unit of FIG. 2;

fig. 5 is a schematic perspective view of the ozone generating unit in fig. 2;

fig. 6 is a schematic cross-sectional view of a cooling section layer of the ground plate of fig. 4.

In the figure: 100. a support rod; 200. an ozone generating group; 210. an ozone generating unit; 211. a ground plate; 212. a high voltage component; 213. an intake runner; 213a, gas delivery branches; 213b, a communication leg; 213c, process holes; 213d, an air inlet branch; 214. a gas outlet flow passage; 214a, an output branch; 214b, an outlet branch; 215. a cooling water flow passage; 215a, a cooling water input interface; 215b, a cooling water output interface; 215c, an airflow input interface; 215d, an airflow output interface; 220. a high voltage electrode joint; 230. a limiting plate; 231. a hanging part; 232. positioning the connecting part; 232a, limit convex strips; 240. assembling a platform; 241. a flange end face; 241a, sealing groove; 242. a mounting plane; 242a, air flow input connection hole; 242b, cooling water input ports; 242c, an air flow output connecting hole; 242d, cooling water output connecting holes; 243. an air flow total input hole; 244. a cooling water total input hole; 245. a total air flow output hole; 246. a cooling water total output hole; 300. and a sealing gasket.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are only preferred embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

1-6, an ozone generator module with multi-dimensional expandability comprises an ozone generating set and an assembling platform 240 for installing the ozone generating set, wherein the length direction expansion can be performed through the serial connection of the assembling platform 240, and because the air flow total input hole 243, the air flow total output hole 245, the cooling water total input hole 244 and the cooling water total output hole 246 are integrated in the assembling platform 240, the communication of a water channel and an air channel is realized synchronously when the ozone generator unit is installed, the air channel module and the water channel module do not need to be independently installed on the side surface or the upper end surface, the side surface and the upper end surface are not limited by the installation space, the width direction expansion and the height direction expansion can be conveniently performed by combining a support rod 100 of an equipment box body, and in addition, because the air flow input interface 215c, the air flow output interface 215d, the cooling water input interface 215a and the cooling water output interface 215b are all positioned on the lower end surface of the ozone generating unit 210, and the high-voltage electrode joint 220 is positioned on one side surface of the ozone generator module, so that the ozone generator module can be stacked in the height direction;

referring again to fig. 1-2, N ozone generating units 210 are used as an ozone generating set, an ozone generator module can be formed by assembling the N ozone generating units 210 outside the equipment box, N is greater than or equal to 2, the assembling platform 240 assembles the N ozone generating units 210 along the length direction, the ozone generating units 210 are mutually parallel and uniformly arranged on the mounting plane 242, because the air flow input interface 215c, the air flow output interface 215d, the cooling water input interface 215a and the cooling water output interface 215b are all arranged on the lower end surface of the ozone generating unit 210, as shown in fig. 3, the mounting plane 242 of the assembling platform 240 is provided with the air flow input connecting hole 242a, the air flow output connecting hole 242c, the cooling water input connecting hole 242b and the cooling water output connecting hole 242d, when the ozone generating unit is placed and installed, each interface of the lower end surface of the ozone generating unit 210 should correspond to the corresponding connecting hole on the mounting plane 242, in order to realize the sealing connection of the multiple interfaces on the ozone generating unit 210 synchronously, a circle of sealing ring grooves are concentrically arranged on the peripheries of the air flow input interface 215c, the air flow output interface 215d, the cooling water input interface 215a and the cooling water output interface 215b, sealing rings are embedded in the sealing ring grooves, the pore diameters of all the connecting holes are respectively smaller than the inner diameters of the corresponding sealing rings, as shown in fig. 5-6, the air flow input connecting hole 242a, the air flow output connecting hole 242c, the cooling water input connecting hole 242b and the cooling water output connecting hole 242d are respectively vertically communicated with each other in the assembling platform 240, and an air flow total input hole 243, an air flow total output hole 245, a cooling water total input hole 244 and a cooling water total output hole 246 are respectively and vertically communicated with each other in the assembling platform 240 along the length direction, when the ozone generator module expands to a certain extent along the length, the conversion rate in the discharging chamber is affected by the heat exchange between all the total output holes in the assembling platform 240, that is, a part of cold energy will be dissipated by the cooling water, the input temperature of the oxygen gas flow will also rise, which is unfavorable for the conversion rate in the ozone generating unit 210, therefore, at least the air flow total input hole 243 and the cooling water total input hole 244 are provided with heat insulation composite pipes in an interference manner, and the air flow input connection hole 242a and the cooling water input connection hole 242b penetrate through the upper peripheral wall of the heat insulation composite pipes and are respectively communicated with the upper peripheral wall of the heat insulation composite pipes, and of course, the air flow total output hole 245 and the cooling water total output hole 246 can also be provided with heat insulation composite pipes as well, which further obstruct relative heat exchange;

in order to facilitate the serial connection of the assembly platforms 240 for installing the ozone generating set, the extension of the length direction is realized, the two ends of the assembly platforms 240 are flange end surfaces 241, sealing grooves 241a for installing sealing gaskets 300 are formed on the flange end surfaces 241, communication holes corresponding to the orifices of the air flow total input holes 243, the air flow total output holes 245, the cooling water total input holes 244 and the cooling water total output holes 246 are respectively formed on the sealing gaskets 300, as shown in fig. 1, after the two serial connection assembly platforms 240 are connected through the flange end surfaces 241, the sealing gaskets 300 are clamped between the two opposite sealing grooves 241a, and sealing between the opposite total input holes is realized;

in this embodiment, since the ozone generating unit 210 is connected to the assembly platform 240 at the lower end through threads, the fastening force of a single dimension is easy to loosen due to vibration during operation, therefore, by implementing limiting from two sides of the ozone generating unit 210, the connection reliability of the ozone generating unit 210 and the assembly platform 240 is further improved, positioning slots penetrate through the lower sides of two sides of the ozone generating unit 210 along the thickness direction, the positioning slots are in a semicircular structure, as shown in fig. 3, limiting plates 230 are correspondingly and detachably arranged at two sides of the assembly platform 240, the limiting plates 230 extend along the length direction of the assembly platform 240 and are provided with positioning connection parts 232 and hanging parts 231, the positioning connection parts 232 are used for detachably connecting with two sides of the assembly platform 240, one side opposite to the two positioning connection parts 232 is respectively provided with a limiting convex strip 232a extending along the length direction, the limiting convex strip 232a is matched with the positioning slot, and all the ozone generating units 210 in the limiting ozone generating unit 210 are connected in series, so that the ozone generating unit 210 can be prevented from being separated from the installation plane 242; as shown in fig. 1, the hanging part 231 is used for expanding the width of the ozone generator module and installing, the hanging part 231 is an inverted U-shaped hanging plate formed by extending the other side surface of the limiting plate 230, and after a plurality of ozone generator modules are connected in series along the length direction, the ozone generator modules are directly hung on an ozone generating set in the equipment box body, and after the two end parts are connected with the equipment box body, the installation of the length unit is quickly realized.

In this embodiment, in order to facilitate positioning and accurate installation of the ozone generating unit 210, the fixing screw hole of the installation plane 242, the air input connection hole 242a, the air output connection hole 242c, the cooling water input connection hole 242b and the cooling water output connection hole 242d are all arranged in a row along the width direction for accurate installation and sealing, wherein the ozone generating unit 210 in this embodiment is preferably a laminated plate type double discharge chamber sharing high voltage electrodes, as shown in fig. 4, which comprises two ground plates 211 and a high voltage assembly 212 sandwiched between the two ground plates 211, two symmetrical discharge chambers are formed therein, in order to realize collinear arrangement of the air input interface 215c, the air output interface 215d, the cooling water input interface 215a and the cooling water output interface 215b, the cooling water flow channel 215, the air inlet flow channel 213 and the air outlet flow channel 214 are all built-in the ground plates 211, and the cooling water flow channel 215 are uniformly distributed on the cooling section layer, and forms a folding path to realize the circulation of cooling water, the gas delivery branch 213a of the gas inlet channel 213 and the output branch 214a of the gas outlet channel 214 are both positioned on the cooling cross-section layer and are arranged parallel to the cooling water channel 215, as shown in fig. 5, of course, the cooling water channel 215, the gas delivery branch 213a and the output branch 214a are all positioned on the same cooling cross-section layer, therefore, the structure and arrangement of the gas inlet channel 213 and the gas outlet channel 214 need to be arranged according to the structure of the discharge chamber, the gas inlet of the ozone generating unit 210 shown in fig. 5 is positioned at one end of the discharge chamber, the gas outlet is positioned at the middle part of the discharge chamber, the cooling cross-section layer is positioned under the discharge chamber, the gas delivery branch 213a is positioned at the middle part of the ground plate 211 and is communicated with the discharge chamber through the gas inlet branch 213d which is vertically communicated with the gas inlet branch, the output branch 214a is positioned at the outer side of the cooling channel, in order to reserve a sufficient sealing space between the cooling channel interface and the gas flow input interface 215c, the output branch 214a is offset to the outside of the air inlet, and is connected to the air outlet branch 214b of the vertical communication discharge chamber through the communication branch 213b, and the communication branch 213b is drilled by the side surface of the ground plate 211, so that a process hole 213c is formed on the side surface of the ground plate 211, and a plug is required to be arranged to plug the process hole 213 c.

Reference herein to "upper", "lower", "side", "outer", "inner", "lengthwise", "widthwise", and like directional terms are used in the coordinates or positional relationship shown in the corresponding drawings. These terms are used primarily to better describe the utility model and its embodiments and are not intended to limit the apparatus, elements or components indicated to the particular orientation or to be constructed and operated in a particular orientation;

also, some of the above terms may be used to indicate other meanings besides azimuth or positional relationships, for example, the terms "upper", "inner", etc. may also be used to indicate some kind of dependency or connection relationship in some cases. The specific meaning of these terms in the present utility model will be understood by those of ordinary skill in the art according to the specific circumstances.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. An ozone generator module with multidimensional scalability, characterized in that: the device comprises an ozone generating set and an assembling platform for installing the ozone generating set, wherein the ozone generating set comprises N ozone generating units, the N ozone generating units are mutually parallel and uniformly arranged along the length direction of the assembling platform, and N is more than or equal to 2;

the lower end face of the ozone generating unit is provided with an air flow input interface, an air flow output interface, a cooling water input interface and a cooling water output interface, sealing ring grooves are respectively arranged on the air flow input interface, the air flow output interface, the cooling water input interface and the cooling water output interface, and sealing rings are embedded in the sealing ring grooves;

the assembly platform is provided with an air flow input hole, an air flow output hole, a cooling water input hole and a cooling water output hole in a penetrating manner along the length direction of the assembly platform, the upper plane of the assembly platform is an installation plane, the installation plane is in supporting connection with the lower end face of the ozone generating unit, the air flow input interface, the air flow output interface, the cooling water input interface and the cooling water output interface are respectively correspondingly communicated with the air flow input connecting hole, the air flow output connecting hole, the cooling water input connecting hole and the cooling water output connecting hole which are arranged on the upper plane of the assembly platform, and are respectively sealed by the sealing ring, and the lower ends of the air flow input connecting hole, the air flow output connecting hole, the cooling water input connecting hole and the cooling water output connecting hole are respectively communicated with the air flow input connecting hole, the air flow output connecting hole, the cooling water input connecting hole and the cooling water output connecting hole;

the two ends of the assembly platform are flange end faces used for being connected in series with the adjacent assembly platform, a sealing groove is arranged on the flange end faces, a sealing gasket is arranged in the sealing groove, the air flow total input hole, the air flow total output hole, the cooling water total input hole and the cooling water total output hole are all positioned at the bottom of the sealing groove, the sealing gasket is clamped between the sealing grooves of the adjacent assembling platforms, and communication holes are respectively formed in the sealing gasket at the positions corresponding to the air flow total input holes, the air flow total output holes, the cooling water total input holes and the cooling water total output holes.

2. The ozone generator module with multi-dimensional scalability according to claim 1, wherein: the ozone generating device is characterized in that positioning grooves are formed in two sides of the ozone generating unit, limiting plates are correspondingly arranged on two sides of the assembling platform in a detachable mode, limiting convex strips extending in the length direction are respectively arranged on one side face, opposite to the limiting plates, of the two sides of the assembling platform, and the limiting convex strips are in plug-in connection with the sides of the positioning grooves.

3. The ozone generator module with multi-dimensional scalability according to claim 2, wherein: the limiting plate is also integrally formed with a hanging part, and the hanging part is an inverted U-shaped hanging plate formed by outwards extending the other side surface of the limiting plate.

4. The ozone generator module with multi-dimensional scalability according to claim 1, wherein: the installation plane is provided with a fixed screw hole, and the fixed screw hole, the air flow input connecting hole, the air flow output connecting hole, the cooling water input connecting hole and the cooling water output connecting hole are linearly arranged along the width direction.

5. The ozone generator module with multi-dimensional scalability as claimed in claim 4, wherein: the ozone generating unit comprises two ground polar plates and a high-voltage component clamped between the two ground polar plates, two symmetrical discharge chambers are formed in the high-voltage component, a plurality of cooling water flow channels, an air inlet flow channel and an air outlet flow channel are arranged in the ground polar plates, the cooling water flow channels are uniformly distributed on a cooling section layer in parallel, the cooling section layer is located under the discharge chambers, the air inlet flow channel comprises an air delivery branch and an air inlet branch which are connected in a communicating manner, the air outlet flow channel comprises an output branch and an air outlet branch which are connected in a communicating manner, the tail end of the air delivery branch is an air flow input interface, the tail end of the output branch is an air flow output interface, and the air delivery branch and the output branch are parallel to the cooling water flow channels and are located on the cooling section layer.

6. The ozone generator module with multi-dimensional scalability as claimed in claim 5, wherein: the air flow total input hole and the cooling water total input hole are internally provided with heat insulation composite pipes in an interference mode, and the air flow input connecting hole and the cooling water input connecting hole are communicated with the heat insulation composite pipes.