Stacked plate ozone generator integrated box
By installing partition plates and optimizing the gas cooling structure within the support box, the stacked plate ozone generator integrated box solves the problems of low gas output and large space occupation in the existing technology, and achieves efficient ozone generation in a small space.
Patent Information
- Authority / Receiving Office
- WO · WO
- Patent Type
- Applications
- Current Assignee / Owner
- WUXI SIRUI ELECTRONICS EQUIP TECH CO LTD
- Filing Date
- 2025-12-05
- Publication Date
- 2026-07-02
AI Technical Summary
Existing stacked plate ozone generators have low gas output and require a large space when used in combination.
A stackable plate ozone generator integrated box is designed. By setting multiple partition plates in the support box, an ozone generating unit, a cooling unit and a gas guiding unit are installed, and the gas path and cooling structure are optimized to achieve a compact layout.
The ozone generator increases ozone output within a smaller space, featuring a compact and reasonable structure that improves its efficiency.
Smart Images

Figure CN2025140203_02072026_PF_FP_ABST
Abstract
Description
A stacked plate ozone generator integrated box Technical Field
[0001] This utility model belongs to the field of ozone generator technology, specifically relating to a stacked plate ozone generator integrated box. Background Technology
[0002] An ozone generator is a device used to produce ozone gas. Because ozone is easily decomposed and cannot be stored, it needs to be produced and used on-site. Therefore, ozone generators are usually required in places where ozone is used.
[0003] Chinese utility model patent application number 202322801533.7 discloses a stacked plate ozone generator housing, comprising: a support assembly including an upper support plate and a lower support plate spaced apart, and multiple support rods connecting the upper and lower support plates; and a generator assembly including multiple cylindrical ozone generating units stacked between the upper and lower support plates, two sets of gas guiding mechanisms connected to each cylindrical ozone generating unit, and two sets of cooling mechanisms connected to each cylindrical ozone generating unit; one set of gas guiding mechanisms is used to input oxygen, and the other set is used to output ozone; one set of cooling mechanisms is used to input cooling water, and the other set is used to output cooling water. However, a single stacked plate ozone generator typically has a low output volume, therefore these stacked plate ozone generators need to be combined for use, and existing combination methods usually occupy a large amount of space. Technical issues
[0004] The purpose of this invention is to overcome the shortcomings of existing technologies and provide a stackable plate ozone generator integrated box. Technical solutions
[0005] To achieve the above objectives, the technical solution adopted by this utility model is: a stacked plate ozone generator integrated box, which includes:
[0006] A support box, wherein the support box comprises at least a plurality of partition plates;
[0007] Multiple sets of ozone generating units are installed one-to-one on the partition plate; each set of ozone generating units includes one or more stacked ozone generating devices arranged side by side.
[0008] Multiple cooling units are provided, and each cooling unit corresponds to one of the partition plates. Each cooling unit includes a cooling module in the same number as the stacked ozone generator. The cooling module includes an inlet pipe connected to the stacked ozone generator, an outlet pipe connected to the stacked ozone generator, a cooling plate connected to the outlet pipe, and a return pipe connected to the cooling plate.
[0009] The gas guiding unit includes multiple gas guiding modules corresponding to the stacked ozone generator, an oxygen inlet pipe connected to the multiple gas guiding modules, a nitrogen inlet pipe connected to the multiple gas guiding modules, an exhaust pipe connected to the multiple gas guiding modules, and multiple ozone outlet pipes connected to the multiple gas guiding modules.
[0010] Ideally, each gas-guiding module includes an oxygen inlet branch pipe connected to the oxygen inlet pipe, a first pneumatic valve installed on the oxygen inlet branch pipe, and a first flow meter installed on the oxygen inlet branch pipe. The oxygen inlet branch pipe is connected to the stacked plate ozone generator.
[0011] Furthermore, each gas guiding module also includes a nitrogen inlet branch pipe connected to the nitrogen inlet pipe, a second pneumatic valve installed on the nitrogen inlet branch pipe, a second flow meter installed on the nitrogen inlet branch pipe, a mixing pipe connected to the oxygen inlet branch pipe and the nitrogen inlet branch pipe and connected to the stacked plate ozone generator, an inlet branch pipe connected to the oxygen inlet branch pipe and connected to the stacked plate ozone generator, and an outlet branch pipe connected to the stacked plate ozone generator.
[0012] Furthermore, each group of the gas guiding modules also includes a transfer pipe connected to the gas outlet branch pipe, an exhaust branch pipe connected to the transfer pipe and the exhaust pipe, and an ozone outlet branch pipe connected to the transfer pipe and one of the ozone outlet pipes.
[0013] Optimally, the support box includes a support base, a top cover disposed above the support base, and multiple side plates installed between the support base and the top cover to form an accommodating space. The multiple side plates are installed on the multiple side plates and are arranged vertically and at intervals within the accommodating space.
[0014] Optimally, the cooling module further includes a bracket and multiple drive plates, the bracket being mounted on the partition plate, the cooling plate being mounted on the bracket, and the multiple drive plates being mounted on both surfaces of the cooling plate. Beneficial effects
[0015] Due to the application of the above technical solutions, this utility model has the following advantages compared with the prior art: The stacked plate ozone generator integrated box of this utility model, by setting multiple partition plates in the support box so that each partition plate is equipped with an ozone generating unit containing one or more stacked plate ozone generating devices, and in conjunction with the cooling unit and the gas guiding unit, can increase the ozone output in a small space, with a compact structure and reasonable arrangement. Attached Figure Description
[0016] Figure 1 is a structural schematic diagram of the integrated box of the stacked plate ozone generator of this utility model;
[0017] Figure 2 is a structural schematic diagram of the integrated box of the stacked plate ozone generator of this utility model from another perspective. Embodiments of the present invention
[0018] The present invention will be further described below with reference to the embodiments shown in the accompanying drawings.
[0019] The following descriptions of embodiments are taken with reference to the accompanying drawings, illustrating specific embodiments in which this utility model can be implemented. Directional terms used in this utility model, such as "upper," "lower," "front," "rear," "left," "right," "inner," "outer," and "side," are merely for directional reference to the drawings. Therefore, the directional terms used are for illustration and understanding of this application, and not for limiting this application. Furthermore, in the specification, unless explicitly stated otherwise, the words "comprising" or "including" should be understood to mean including the element, but not excluding any other elements.
[0020] As shown in Figures 1 and 2, the stacked plate ozone generator integrated box mainly includes a support box 1, an ozone generating unit 2, an air guiding unit 3, and a cooling unit.
[0021] The support housing 1 includes a support base 11, side plates 12, a top cover 13, and partition plates 14. The top cover 13 is located above the support base 11 (usually directly above it and cooperating with the support base 11); there are multiple side plates 12, which are installed between the support base 11 and the top cover 13 to form an accommodating space (only some side plates 12 are shown in Figures 1 and 2). The arrangement of the side plates 12 can usually be set according to the specific shape of the support housing 1 (such as the support housing 1 being cubic or cylindrical in shape); there are multiple partition plates 14, and their number can be conventionally selected according to the height of the support housing 1 and the height of the ozone generating unit 2. They are usually installed on multiple side plates 12 and spaced vertically within the aforementioned accommodating space.
[0022] There are multiple sets of ozone generating units 2, which are installed one-to-one on the partition plates 14 (i.e., the number of sets of ozone generating units 2 is the same as the number of partition plates 14). Each set of ozone generating units 2 includes one or multiple stacked plate ozone generating devices 21 arranged side by side (the specific number of stacked plate ozone generating devices 21 in each set of ozone generating units 2 can be conventionally selected according to the size of the partition plates 14). In this embodiment, each set of ozone generating units 2 includes two stacked plate ozone generating devices 21 arranged side by side. The stacked plate ozone generator 21 can be any conventional one, preferably the one disclosed in Chinese Utility Model Patent Application No. 202322801533.7 (in which it is defined as a stacked plate ozone generator housing), wherein each generator assembly includes multiple cylindrical ozone generating units stacked together (the cylindrical ozone generating unit is a deformed cylindrical structure); specifically, in order to clarify the connection relationship between the stacked plate ozone generator 21 and the cooling unit and the gas guiding unit, the two sets of liquid inlet pipes (one set for liquid inlet, one set for liquid outlet) and the two sets of drainage pipes (one set for gas inlet, one set for gas outlet) of the stacked plate ozone generator housing are specifically mentioned here.
[0023] There are multiple cooling units, the number of which matches the number of partition plates 14, ensuring a one-to-one correspondence between the cooling units and partition plates 14. Each cooling unit includes a cooling module 4, the number of which matches the number of stacked ozone generators 21, allowing each cooling module 4 to work in conjunction with the stacked ozone generators 21 to cool them. Each cooling module 4 includes an inlet pipe 40 (connected to the aforementioned liquid inlet pipe) connected to the stacked ozone generator 21, an outlet pipe 44 (connected to the aforementioned liquid outlet pipe) connected to the stacked ozone generator 21, a cooling plate 42 connected to the outlet pipe 44, and a return pipe 45 connected to the cooling plate 42. This allows the cooling water to cool the stacked ozone generator 21 and then the cooling plate 42, thus improving the cooling utilization rate. In this embodiment, the cooling module 4 also includes a bracket 41 and multiple drive boards 43. The bracket 41 is mounted on the partition plate 14, and the cooling plate 42 is mounted on the bracket 41. The multiple drive boards 43 are mounted on both surfaces of the cooling plate 42, so that the multiple drive boards 43 are connected one-to-one with the aforementioned cylindrical ozone generating unit for control (the circuit structure of the drive board 43 can be disclosed in Chinese Utility Model Patent Application No. 202322815202.9). This also enables synchronous cooling of the drive boards 43, extending their service life.
[0024] The gas guiding unit 3 includes multiple gas guiding modules corresponding to the stacked ozone generator 21, an oxygen inlet pipe 31 connected to the multiple gas guiding modules, a nitrogen inlet pipe 32 connected to the multiple gas guiding modules, an exhaust pipe 33 connected to the multiple gas guiding modules, and multiple ozone outlet pipes 30 connected to the multiple gas guiding modules. The oxygen inlet pipe 31, nitrogen inlet pipe 32, and exhaust pipe 33 are arranged parallel to each other and vertically, and are installed on the inside of a side plate 12 through multiple first adapter blocks; while the multiple ozone outlet pipes 30 are also arranged parallel to each other and vertically, and are installed on the inside of another side plate 12 (opposite to the aforementioned side plate 12) through multiple second adapter blocks.
[0025] Each gas guiding module includes an oxygen inlet branch pipe 34 connected to the oxygen inlet pipe 31, a first flow meter 341 installed on the oxygen inlet branch pipe 34, and a first pneumatic valve installed on the oxygen inlet branch pipe 34 (the first pneumatic valve is located downstream of the first flow meter 341, defined according to the gas flow direction, the same below). The oxygen inlet branch pipe 34 is connected to the stacked plate ozone generator 21. Each gas guiding module also includes a nitrogen inlet branch pipe 35 connected to the nitrogen inlet pipe 32, and a second flow meter 351 installed on the nitrogen inlet branch pipe 35. The system includes a second pneumatic valve installed on the nitrogen inlet branch pipe 35; a mixing pipe 36 (used to mix oxygen and nitrogen) connected to the oxygen inlet branch pipe 34 and the nitrogen inlet branch pipe 35 and connected to the stacked plate ozone generator 21; an inlet branch pipe 37 (connected to the aforementioned inlet drain pipe) connected to the oxygen inlet branch pipe 34 and the stacked plate ozone generator 21; and an outlet branch pipe 38 (connected to the aforementioned outlet drain pipe) connected to the stacked plate ozone generator 21. In this embodiment, two adjacent sets of inlet branch pipes 37 can be merged using a connecting pipe before being connected to the mixing pipe 36, and similarly, two adjacent sets of outlet branch pipes 38 can be merged using a connecting pipe before being connected to subsequent structures (i.e., subsequent transfer pipes), thereby reducing the complexity of the gas path within the entire stacked plate ozone generator integrated box.
[0026] In this embodiment, each gas guiding module further includes a transfer pipe 39 connected to the gas outlet branch pipe 38, an exhaust branch pipe connected to the transfer pipe 39 and the exhaust pipe 33, and an ozone outlet branch pipe connected to the transfer pipe 39 and the ozone outlet pipe 30. A pneumatic valve is installed on both the exhaust branch pipe and the ozone outlet branch pipe. When the gas from the ozone outlet pipe 30 is used, the exhaust branch pipe is usually closed; when the gas from the ozone outlet pipe 30 is not needed, the ozone outlet branch pipe can be closed and the exhaust branch pipe can be opened to allow the gas to be discharged into the atmosphere.
[0027] The above embodiments are only for illustrating the technical concept and features of this utility model, and are intended to enable those skilled in the art to understand the content of this utility model and implement it accordingly. They should not be construed as limiting the scope of protection of this utility model. All equivalent changes or modifications made in accordance with the spirit and essence of this utility model should be included within the scope of protection of this utility model.
Claims
1. A stacked plate ozone generator integrated box, characterized in that, It includes: Support box (1), the support box (1) includes at least a plurality of partition plates (14); Multiple sets of ozone generating units (2) are installed on the partition plate (14) in a one-to-one correspondence; each set of ozone generating units (2) includes one or multiple stacked ozone generating devices (21) arranged side by side. Multiple cooling units are provided, and each cooling unit corresponds to a partition plate (14). Each cooling unit includes a cooling module (4) in the same number as the stacked ozone generator (21). The cooling module (4) includes an inlet pipe (40) connected to the stacked ozone generator (21), an outlet pipe (44) connected to the stacked ozone generator (21), a cooling plate (42) connected to the outlet pipe (44), and a return pipe (45) connected to the cooling plate (42). The gas guiding unit (3) includes multiple gas guiding modules corresponding to the stacked plate ozone generator (21), an oxygen inlet pipe (31) connected to the multiple gas guiding modules, a nitrogen inlet pipe (32) connected to the multiple gas guiding modules, an exhaust pipe (33) connected to the multiple gas guiding modules, and multiple ozone outlet pipes (30) connected to the multiple gas guiding modules.
2. The stacked plate ozone generator integrated tank according to claim 1, characterized in that: Each of the gas guiding modules includes an oxygen inlet branch pipe (34) connected to the oxygen inlet pipe (31), a first pneumatic valve installed on the oxygen inlet branch pipe (34), and a first flow meter (341) installed on the oxygen inlet branch pipe (34). The oxygen inlet branch pipe (34) is connected to the stacked plate ozone generator (21).
3. The stacked plate ozone generator integrated tank according to claim 2, characterized in that: Each gas guiding module also includes a nitrogen inlet branch pipe (35) connected to the nitrogen inlet pipe (32), a second pneumatic valve installed on the nitrogen inlet branch pipe (35), a second flow meter (351) installed on the nitrogen inlet branch pipe (35), a mixing pipe (36) connected to the oxygen inlet branch pipe (34) and the nitrogen inlet branch pipe (35) and connected to the stacked plate ozone generator (21), an inlet branch pipe (37) connected to the oxygen inlet branch pipe (34) and connected to the stacked plate ozone generator (21), and an outlet branch pipe (38) connected to the stacked plate ozone generator (21).
4. The stacked plate ozone generator integrated tank according to claim 3, characterized in that: Each of the gas guiding modules further includes a transfer pipe (39) connected to the gas outlet branch pipe (38), an exhaust branch pipe connected to the transfer pipe (39) and connected to the exhaust pipe (33), and an ozone outlet branch pipe connected to the transfer pipe (39) and connected to one of the ozone outlet pipes (30).
5. The stacked plate ozone generator integrated tank of claim 1, wherein: The support box (1) includes a support base (11), a top cover (13) disposed above the support base (11), and multiple side plates (12) installed between the support base (11) and the top cover (13) to form an accommodating space. Multiple partition plates (14) are installed on the multiple side plates (12) and are arranged vertically and intermittently within the accommodating space.
6. The stacked plate ozone generator integrated tank of claim 1, wherein: The cooling module (4) also includes a bracket (41) and multiple drive plates (43). The bracket (41) is mounted on the partition plate (14), the cooling plate (42) is mounted on the bracket (41), and the multiple drive plates (43) are mounted on both surfaces of the cooling plate (42).