CN220202050U - Electrolytic ozone generating device - Google Patents

Abstract

The utility model discloses an electrolytic ozone generating device, which belongs to the technical field of ozone generation, and comprises a bracket and further comprises: two sets of electrolysis-type ozone generation components, electrolysis-type ozone generation components are all installed at the both ends of support for carry the raw materials respectively to the conveying component in two sets of electrolysis-type ozone generation components, and conveying component establishes on the support, the support includes: the utility model has the advantages that when one group of electrolytic ozone generating components are utilized for electrolysis, raw water in the other group of electrolytic ozone generating components can be fed and discharged, so that the space time is shortened, the electrolysis efficiency is improved, and the ozone generation amount is maintained.

Description

An electrolytic ozone generating device

Technical field

The utility model relates to the technical field of ozone generation, specifically an electrolytic ozone generation device.

Background technique

Ozone is an allotrope of oxygen. It has extremely poor stability under normal temperature and pressure. It can decompose into oxygen by itself at normal temperature. Ozone can be used for food purification, drinking water purification, disinfection and sterilization, air purification, fruit and vegetable preservation, mildew prevention, bathing, beauty, health care, fish farming, watering flowers, deodorization, etc. At present, the main methods for producing ozone are corona discharge method and PEM electrolysis method. Compared with the corona discharge method, the PEM electrolysis method has the advantages of high ozone purity, no nitrogen oxides, and easy operation.

However, current electrolytic ozone generating devices usually work intermittently. Specifically, after electrolyzing raw water to generate ozone, it is usually necessary to discharge the electrolyzed raw water and then inject new raw water. In this process, a gap will be created in which the electrolytic ozone generating device cannot operate, which will affect the electrolysis efficiency. Although there are currently equipment for replenishing raw material water, the replenished raw material water will be mixed with the electrolyzed raw material water. At this time, since there is no ozone in the electrolyzed raw material water, then at this time, the mixed raw material The ozone content in the water is low. If electrolysis is performed at this time, the amount of ozone generated this time will be low during the same electrolysis time, which will affect the electrolysis efficiency. Therefore, an electrolytic ozone generating device was invented.

Utility model content

In view of the above and/or existing problems in an existing electrolytic ozone generating device, the present utility model is proposed.

Therefore, the purpose of this utility model is to provide an electrolytic ozone generating device that can solve the above-mentioned existing problems.

In order to solve the above technical problems, according to one aspect of the present utility model, the utility model provides the following technical solutions:

An electrolytic ozone generating device, which includes a bracket and:

Two sets of electrolytic ozone generating components, with electrolytic ozone generating components installed at both ends of the bracket;

The transport components are used to transport raw water to two sets of electrolytic ozone generating components respectively, and the transport components are arranged on the bracket.

As a preferred solution of the electrolytic ozone generating device according to the present invention, the bracket includes:

base plate;

A support plate, the support plates are fixedly installed at both ends of the top of the bottom plate;

A top plate with support plates fixedly installed at both ends of the bottom of the top plate;

A collection box is placed on top of the base plate.

As a preferred solution of the electrolytic ozone generating device of the present invention, the electrolytic ozone generating component includes:

An electrolytic box, which is fixedly installed on the top of the top plate;

A partition, which is fixedly installed on the inner wall of the middle end of the electrolytic box;

Anode area, the space on the left side of the partition plate and the electrolytic box is set as the anode area;

The cathode area, the space on the right side of the separator and the electrolytic box is set as the cathode area.

As a preferred solution of the electrolytic ozone generating device of the present invention, the electrolytic ozone generating component further includes:

An anode conductive joint, the anode conductive joint is fixedly installed on the left top of the electrolytic box;

A cathode conductive joint, which is fixedly installed on the top of the right side of the electrolytic box;

An anode plate, the anode plate is fixedly installed on the bottom of the anode conductive joint, and one end of the anode plate extends into the anode area;

The cathode plate is fixedly installed on the bottom of the cathode conductive joint, and one end of the anode plate extends into the cathode area.

As a preferred solution of the electrolytic ozone generating device of the present invention, the electrolytic ozone generating component further includes:

A first exhaust hole, the first exhaust hole is opened on the left inner wall of the electrolytic box, and the first exhaust hole is connected with the anode area;

A second exhaust hole is opened on the inner wall of the right top of the electrolytic box, and the second exhaust hole is connected with the cathode area.

As a preferred solution of the electrolytic ozone generating device of the present invention, the electrolytic ozone generating component further includes:

Insulating sleeves, the outer surfaces of the anode conductive joint and the cathode conductive joint are provided with insulating sleeves;

There is a drain pipe of the solenoid valve on it. The drain pipe is fixedly installed on the bottom inner wall of the electrolytic box, and a collection box is provided directly below the drain pipe.

As a preferred solution of the electrolytic ozone generating device of the present invention, the anode plate and the cathode plate both include:

electrolyte membrane;

Silicone rubber sealing rings, both sides of the electrolyte membrane are wrapped by silicone rubber sealing rings;

Microporous metal plate, the microporous metal plate is located on the outside of the silicone rubber sealing ring;

Reaction holes, the silicone rubber sealing ring and the microporous metal plate are each provided with a number of corresponding reaction holes.

As a preferred solution of the electrolytic ozone generating device of the present invention, the transport component includes:

A water pump, which is fixedly installed on the top of the middle end of the top plate;

Hard pipe, the output end of the water pump is fixedly installed with a hard pipe;

There is a pipe with a solenoid valve on it. One end of the hard pipe is fixedly installed with two sets of pipes through a tee joint, and one end of the pipe is fixedly installed on the inner wall of the electrolytic box.

Compared with existing technology:

By arranging two sets of electrolytic ozone generating assemblies, and by arranging conveying assemblies for respectively transporting raw water to the two sets of electrolytic ozone generating assemblies, it is possible to achieve electrolysis by using one set of electrolytic ozone generating assemblies. The raw material water in another set of electrolytic ozone generating components can be loaded and unloaded, thereby reducing the idle time, not only improving the electrolysis efficiency, but also maintaining the amount of ozone generated.

Description of drawings

Figure 1 is a schematic front view of the structure of the utility model;

Figure 2 is an enlarged schematic diagram of the structure at point A in Figure 1 of the present utility model;

Figure 3 is a schematic diagram of the structure of the bracket of the present utility model;

Figure 4 is a schematic structural diagram of the cathode conductive joint and cathode plate of the present invention.

In the figure: bottom plate 10, support plate 11, top plate 12, collection box 13, electrolytic box 21, separator 22, anode area 23, cathode area 24, anode conductive joint 25, cathode conductive joint 26, anode plate 27, cathode plate 28 , first exhaust hole 29, second exhaust hole 30, insulating sleeve 31, drain pipe 32, water pump 41, hard pipe 42, pipe 43, microporous metal plate 51, reaction hole 52, silicone rubber sealing ring 53, Electrolyte membrane 54.

Detailed ways

In order to make the purpose, technical solutions and advantages of the present utility model clearer, the embodiments of the present utility model will be further described in detail below with reference to the accompanying drawings.

The utility model provides an electrolytic ozone generating device, please refer to Figures 1-4, including a bracket;

The bracket includes: bottom plate 10, support plate 11, top plate 12, collection box 13;

The support plates 11 are fixedly installed at both ends of the top of the base plate 10 , the support plates 11 are fixedly installed at both ends of the bottom of the top plate 12 , and the collection box 13 is placed on the top of the base plate 10 .

It also includes: two sets of electrolytic ozone generating components, with electrolytic ozone generating components installed on both ends of the bracket;

The electrolytic ozone generating component includes: electrolytic box 21, separator 22, anode area 23, cathode area 24, anode conductive joint 25, cathode conductive joint 26, anode plate 27, cathode plate 28, first exhaust hole 29, second The exhaust hole 30, the insulating sleeve 31, and the drain pipe 32 with a solenoid valve on it;

The electrolytic box 21 is fixedly installed on the top of the top plate 12, and the partition 22 is fixedly installed on the inner wall of the middle end of the electrolytic box 21. The space on the left side of the partition 22 and the electrolytic box 21 is set as the anode area 23. The partition 22 and the electrolytic box The space on the right side of 21 is set as the cathode area 24, the anode conductive joint 25 is fixedly installed on the left top of the electrolytic box 21, the anode conductive joint 25 is connected to an external power supply, and the cathode conductive joint 26 is fixedly installed on the right top of the electrolytic box 21. The cathode conductive joint 26 is connected to an external power supply, the anode plate 27 is fixedly installed on the bottom of the anode conductive joint 25, and one end of the anode plate 27 extends into the anode area 23, the cathode plate 28 is fixedly installed on the bottom of the cathode conductive joint 26, and the anode One end of the plate 27 extends into the cathode area 24. A first exhaust hole 29 is opened on the left inner wall of the electrolytic box 21. The first exhaust hole 29 has the function of discharging ozone, and the first exhaust hole 29 is connected to the anode area. 23 are connected, the second exhaust hole 30 is opened on the inner wall of the right top of the electrolytic box 21, the second exhaust hole 30 has the function of discharging hydrogen, and the second exhaust hole 30 is connected with the cathode area 24, and the anode The outer surfaces of the conductive joint 25 and the cathode conductive joint 26 are provided with insulating sleeves 31. The drain pipe 32 is fixedly installed on the bottom inner wall of the electrolytic box 21, and a collection box 13 is provided directly below the drain pipe 32. By setting The insulating sleeve 31 has the function of improving safety, and the insulating sleeve 31 is made of insulating material.

Both the anode plate 27 and the cathode plate 28 include: an electrolyte membrane 54, a silicone rubber sealing ring 53, a microporous metal plate 51, and a reaction hole 52;

Both sides of the electrolyte membrane 54 are wrapped by silicone rubber sealing rings 53. Catalyst particles are added to the silicone rubber sealing rings 53. The catalyst particles can accelerate the electrolysis reaction. The electrolyte membrane 54 in the anode plate 27 is an anode electrolyte membrane. The electrolyte membrane 54 is a negative electrolyte membrane, and the microporous metal plate 51 is located on the outside of the silicone rubber sealing ring 53. A number of one-to-one corresponding reaction holes 52 are provided in the silicone rubber sealing ring 53 and the microporous metal plate 51. The reaction holes The arrangement of 52 can facilitate the raw material water to reach the electrolyte membrane 54 through the reaction hole 52, where an electrolysis reaction occurs, and the generated gas is also discharged through the reaction hole 52.

It also includes: a transport component for transporting raw water to two sets of electrolytic ozone generating components respectively, and the transport component is located on the bracket;

The transportation component includes: a water pump 41, a hard pipe 42, and a pipe 43 with a solenoid valve on it;

The water pump 41 is fixedly installed on the top of the middle end of the top plate 12. The input end of the water pump 41 is connected to the external raw water source through a pipeline. The output end of the water pump 41 is fixedly installed with a hard pipe 42. One end of the hard pipe 42 is fixedly installed with two tee joints. A pipe 43 is assembled, and one end of the pipe 43 is fixedly installed on the inner wall of the electrolytic box 21 .

Working principle: start the solenoid valve on a set of pipes 43, and then use the water pump 41 to make the raw water flow into a set of electrolytic boxes 21 through the hard pipe 42 and a set of pipes 43, until the raw water in the set of electrolytic boxes 21 is at When the amount is appropriate, the transportation is stopped, and the anode conductive joint 25 and the cathode conductive joint 26 are energized. After the electricity is energized, the raw material water will be electrolyzed through the anode plate 27 and the cathode plate 28, and then two gases, ozone and hydrogen, will be produced, and The generated ozone and hydrogen will flow out through the first exhaust hole 29 and the second exhaust hole 30 respectively. After the electrolysis of the raw material water in the electrolytic box 21 is completed, it can pass through the solenoid valve on the drain pipe 32 Let the electrolyzed raw material water flow into the collection box 13 through the drain pipe 32;

Among them, when one group of electrolytic ozone generating components is electrolyzing raw material water, the electrolyzed raw material water in another group of electrolytic ozone generating components can be discharged into the collection box 13, and then new raw materials can be discharged. Water is injected into another set of electrolytic ozone generating components.

Although the present invention has been described above with reference to the embodiments, various modifications may be made and components thereof may be replaced with equivalents without departing from the scope of the invention. In particular, as long as there is no structural conflict, various features in the embodiments disclosed in the present invention can be combined with each other in any way. The description of these combinations is not exhaustive in this specification only. For the sake of omitting space and saving resources. Therefore, the present invention is not limited to the specific embodiments disclosed herein, but includes all technical solutions falling within the scope of the claims.

Claims (1)

1. An electrolytic ozone generating device, including a bracket, characterized in that it also includes: Two sets of electrolytic ozone generating components, with electrolytic ozone generating components installed at both ends of the bracket; Conveying components used to transport raw water to two sets of electrolytic ozone generating components respectively, and the transporting components are located on the bracket; The bracket includes: base(10); Support plate (11), the support plate (11) is fixedly installed at both ends of the top of the bottom plate (10); Top plate (12), support plates (11) are fixedly installed at both ends of the bottom of the top plate (12); A collection box (13) placed on top of the bottom plate (10); The electrolytic ozone generating component includes: Electrolysis box (21), the electrolysis box (21) is fixedly installed on the top of the top plate (12); The partition (22) is fixedly installed on the inner wall of the middle end of the electrolytic box (21); Anode area (23), the space on the left side of the partition (22) and the electrolytic box (21) is set as the anode area (23); Cathode area (24), the space on the right side of the separator (22) and the electrolytic box (21) is set as the cathode area (24); The electrolytic ozone generating component also includes: Anode conductive joint (25), the anode conductive joint (25) is fixedly installed on the left top of the electrolytic box (21); Cathode conductive joint (26), the cathode conductive joint (26) is fixedly installed on the top of the right side of the electrolytic box (21); An anode plate (27), the anode plate (27) is fixedly installed on the bottom of the anode conductive joint (25), and one end of the anode plate (27) extends into the anode area (23); Cathode plate (28), the cathode plate (28) is fixedly installed on the bottom of the cathode conductive joint (26), and one end of the anode plate (27) extends into the cathode area (24); The electrolytic ozone generating component also includes: A first exhaust hole (29), the first exhaust hole (29) is opened on the left inner wall of the electrolytic box (21), and the first exhaust hole (29) is connected with the anode area (23); A second exhaust hole (30) is opened on the inner wall of the right top of the electrolytic box (21), and the second exhaust hole (30) is connected to the cathode area (24) Pass; The electrolytic ozone generating component also includes: Insulating sleeves (31), the outer surfaces of the anode conductive joint (25) and the cathode conductive joint (26) are provided with insulating sleeves (31); A drain pipe (32) of a solenoid valve is provided on it. The drain pipe (32) is fixedly installed on the bottom inner wall of the electrolytic box (21), and a collection box is provided directly below the drain pipe (32). (13); The anode plate (27) and the cathode plate (28) both include: electrolyte membrane(54); Silicone rubber sealing ring (53), both sides of the electrolyte membrane (54) are wrapped by silicone rubber sealing ring (53); Microporous metal plate (51), the microporous metal plate (51) is located on the outside of the silicone rubber sealing ring (53); Reaction holes (52), a number of one-to-one corresponding reaction holes (52) are provided in the silicone rubber sealing ring (53) and the microporous metal plate (51); The conveying components include: Water pump (41), the water pump (41) is fixedly installed on the top of the middle end of the top plate (12); Hard pipe (42), the output end of the water pump (41) is fixedly installed with the hard pipe (42); There is a pipe (43) with a solenoid valve on it. One end of the hard pipe (42) is fixedly installed with two sets of pipes (43) through a tee joint, and one end of the pipe (43) is fixedly installed on the electrolytic box (21). on the inner wall.