CN213446218U

CN213446218U - Ozone generator

Info

Publication number: CN213446218U
Application number: CN202021191692.XU
Authority: CN
Inventors: 张柏松; 何勇; 周豪
Original assignee: Zhongwu Zhijian Wuhan Technology Co Ltd
Current assignee: Zhongwu Zhijian Wuhan Technology Co Ltd
Priority date: 2020-06-24
Filing date: 2020-06-24
Publication date: 2021-06-15
Anticipated expiration: 2030-06-24

Abstract

The utility model discloses an ozone generator, include: the machine shell comprises a first accommodating cavity and a second accommodating cavity, wherein the first accommodating cavity is provided with an air inlet, and the second accommodating cavity is provided with an air outlet; the ionization assembly comprises an ionization cylinder, a positive electrode and a negative electrode, one end of the ionization cylinder is communicated with the first accommodating cavity, the other end of the ionization cylinder is communicated with the second accommodating cavity, the positive electrode is fixed on the inner wall of the ionization cylinder, the negative electrode is fixed on the inner wall of the ionization cylinder, and the negative electrode is opposite to the positive electrode; the radiating assembly comprises a first radiating pipe and a second radiating pipe, wherein the first radiating pipe is arranged on the inner wall of the first containing cavity, and the second radiating pipe is arranged on the inner wall of the second containing cavity. The oxygen is cooled, and when the oxygen enters the ionization cylinder, the temperature of the ionization cylinder can be reduced, so that the ozone generated in the ionization cylinder is prevented from being rapidly decomposed. Then the temperature of the ozone generated by ionization is reduced, so that the temperature of the ozone is further reduced, the decomposition speed of the ozone is reduced, and the working efficiency of the ozone generator is improved.

Description

Ozone generator

Technical Field

The utility model relates to a sanitary safety field, concretely relates to ozone generator.

Background

The ozone generator generally adopts a high-voltage corona electric field to cause oxygen molecules to generate electrochemical reaction so as to generate ozone, but in the process of forming the high-voltage corona electric field, current passes through a conductor to inevitably generate electric heat. The temperature in the ozone generator is increased by the electric heat, and the ozone decomposition speed is greatly increased along with the temperature increase, so that the ozone generated by the ozone generator is not used and is decomposed, and the working efficiency of the ozone generator is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the technical insufficiency, provide an ozone generator, solve the technical problem among the prior art.

In order to achieve the above technical purpose, the technical solution of the present invention includes an ozone generator, which includes:

the air conditioner comprises a machine shell, a first air inlet, a second air inlet, a first air outlet and a second air outlet, wherein the machine shell comprises a first accommodating cavity and a second accommodating cavity;

the ionization assembly comprises an ionization cylinder, a positive electrode and a negative electrode, one end of the ionization cylinder is communicated with the first accommodating cavity, the other end of the ionization cylinder is communicated with the second accommodating cavity, the positive electrode is fixed on the inner wall of the ionization cylinder, the negative electrode is fixed on the inner wall of the ionization cylinder, and the negative electrode is opposite to the positive electrode;

the radiating assembly comprises a first radiating pipe and a second radiating pipe, wherein the first radiating pipe is arranged on the first accommodating cavity inner wall, and the second radiating pipe is arranged on the second accommodating cavity inner wall.

Compared with the prior art, the beneficial effects of the utility model include: firstly, oxygen is introduced into the air inlet, then the oxygen is introduced into the first containing cavity, meanwhile, the first radiating pipe cools the oxygen in the first containing cavity, then the oxygen enters the ionization cylinder, and under the action of electric fields of the positive electrode and the negative electrode, the oxygen generates ozone through electrochemical reaction. The chamber is acceptd to the ozone entering second that generates, after the cooling of second cooling tube, via the gas outlet discharge. The utility model provides a technical scheme at first cools down oxygen, when oxygen got into the ionization section of thick bamboo, can reduce the temperature of ionization section of thick bamboo to the ozone that has just generated in having avoided the ionization section of thick bamboo decomposes fast. Then the temperature of the ozone generated by ionization is reduced, so that the temperature of the ozone is further reduced, the decomposition speed of the ozone is reduced, and the working efficiency of the ozone generator is improved.

Drawings

Fig. 1 is a schematic structural view of an ozone generator according to an embodiment of the present invention;

FIG. 2 is a schematic view of an ozone generator according to an embodiment of the present invention;

FIG. 3 is a schematic view of the internal assembly of the ozone generator according to the embodiment of the present invention;

fig. 4 is an exploded schematic view of a heat sink and an ionization assembly of an ozone generator according to an embodiment of the present invention;

fig. 5 is an exploded view of the housing of the ozone generator according to the embodiment of the present invention;

fig. 6 is a schematic sectional view of a housing body of an ozone generator according to an embodiment of the present invention;

fig. 7 is a schematic structural view of an ionization assembly of an ozone generator according to an embodiment of the present invention;

fig. 8 is a schematic cross-sectional view of an ionization cylinder of an ozone generator according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The utility model provides an ozone generator, it includes casing 100, ionization subassembly 200, radiator unit 300 and water supply unit 400, casing 100 provides the space of buffer memory for the gas, and ionization subassembly 200 is used for generating high voltage corona electric field to make oxygen take place electrochemical reaction and generate ozone, and radiator unit 300 is used for reducing the inside temperature of casing 100, thereby avoids ozone to decompose because of the high temperature fast, and water supply unit 400 carries the cooling water to radiator unit 300.

The casing 100 includes a first receiving cavity 110 and a second receiving cavity 120, the first receiving cavity 110 has an air inlet 111, and the second receiving cavity has an air outlet 121. The material for the casing 100 should be made of corrosion-resistant material in consideration of the strong corrosiveness of ozone.

Considering that there are parts to be disassembled and assembled inside the casing 100, the casing 100 further includes an upper end cover 112 and a lower end cover 122 in addition to the casing body 100, the upper end cover 112 is detachably fixed on the upper end of the casing body 100, and the lower end cover 122 is detachably fixed on the lower end of the casing body 100. Meanwhile, the air inlet 111 is opened in the upper end cover 112, and the air outlet 121 is opened in the lower end cover 122.

The ionization assembly 200 comprises an ionization cylinder 210, a positive electrode 220 and a negative electrode 230, wherein one end of the ionization cylinder 210 is communicated with the first containing cavity 110, the other end of the ionization cylinder is communicated with the second containing cavity 120, the positive electrode 220 is fixed on the inner wall of the ionization cylinder 210, the negative electrode 230 is fixed on the inner wall of the ionization cylinder 210, and the negative electrode 230 is opposite to the positive electrode 220. The positive electrode 220 and the negative electrode 230 are used for generating a high voltage corona electric field so as to generate an electrochemical reaction of ozone, and after oxygen in the first receiving cavity 110 flows between the positive electrode 220 and the negative electrode 230, the oxygen is used for generating ozone under the action of the electric field, and the ozone enters the second receiving cavity 120. The voltage and frequency parameters of the positive electrode 220 and the negative electrode 230 are well known to those skilled in the art and will not be described in detail herein.

A guide plate 211 is arranged at one end of the ionization cylinder 210 close to the second containing cavity 120, the guide plate 211 is provided with a convex surface 211a, the convex surface 211a is opposite to the end surface of the ionization cylinder 210, a connecting rib 211b extends out of the outer edge of the guide plate 211, and the free end of the connecting rib 211b is fixed on the inner wall of the ionization cylinder 210. The guide plate 211 is used to guide the ozone discharged from the ionization cylinder 210 to flow to the side wall of the second accommodating cavity 120, so as to fully contact with the second heat dissipation pipe 320, thereby improving the heat exchange efficiency of the ozone and reducing the temperature of the ozone.

Considering that dust is easily accumulated on the ionization cylinder 210 due to the electric field, a filter screen 240 is disposed at an end of the ionization cylinder 210 close to the first receiving cavity 110.

The heat dissipating assembly 300 includes a first heat dissipating tube 310 and a second heat dissipating tube 320, wherein the first heat dissipating tube 310 is disposed on the inner wall of the first receiving cavity 110, and the second heat dissipating tube 320 is disposed on the inner wall of the second receiving cavity 120. The first heat pipe 310 is used for reducing the temperature of the oxygen in the first receiving cavity 110, and the second heat pipe 320 is used for reducing the temperature of the ozone in the second receiving cavity 320.

In order to improve the heat exchange efficiency of the first radiating pipe 310 and the second radiating pipe 320, the present embodiment preferably adopts the following manner: the first heat pipe 310 is formed in a spiral shape and arranged along the inner wall of the first receiving chamber 110, and the second heat pipe 320 is formed in a spiral shape and arranged along the inner wall of the second receiving chamber 120.

In order to simplify the refrigerant delivery of the heat dissipation pipe, one end of the first heat dissipation pipe 310 is connected to one end of the second heat dissipation pipe 320, and a connection point between the first heat dissipation pipe 310 and the second heat dissipation pipe 320 needs to penetrate through the wall panel between the first receiving cavity 110 and the second receiving cavity 120. Of course, the first radiating pipe 310 and the second radiating pipe 320 respectively penetrate the outer wall of the cabinet 100, and the connection point of the first radiating pipe 310 and the second radiating pipe 320 is located at the outer wall of the cabinet 100. For the specific embodiment, it can be changed according to actual requirements as long as the first heat dissipation tube 310 and the second heat dissipation tube 320 can be connected in a butt joint manner, and the refrigerant can be provided for the first heat dissipation tube 310 and the second heat dissipation tube 320 through the same refrigerant delivery system.

Still include water supply assembly 400, water supply assembly 400 includes water tank 410, water pump 420, inlet tube 430, wet return 440 and water suction pipe 450, inlet tube 430 one end is extended into water tank 410, the end of intaking of water pump 420 is connected to the inlet tube 410 other end, the output of water pump 420 is connected to inlet tube 430 one end, the free end of second cooling tube 320 is connected to the inlet tube 430 other end, the free end of first cooling tube 310 is connected to wet return 440 one end, wet return 440 other end intercommunication water tank 410, water suction pipe 450 one end intercommunication water tank 410, the end of intaking of water pump 420 is connected to the other end. .

The top end of the water tank 410 is provided with a clamping groove 411, the bottom end of the casing 100 extends to form a clamping key 123, and the clamping key 123 is embedded in the clamping groove 411.

Firstly, oxygen is introduced into the air inlet 111, and then the oxygen is introduced into the first containing cavity 110, meanwhile, the first heat dissipation pipe 310 cools the oxygen in the first containing cavity 110, and then the oxygen enters the ionization cylinder 210, and under the action of the electric fields of the positive electrode 220 and the negative electrode 230, the oxygen generates ozone through electrochemical reaction. The generated ozone enters the second accommodating cavity 120, is cooled by the second heat dissipating pipe 320, and is discharged through the air outlet 121. The utility model provides a technical scheme at first cools down oxygen, when oxygen got into ionization section of thick bamboo 210, can reduce ionization section of thick bamboo 210's temperature to the ozone that has just produced among the ionization section of thick bamboo 210 decomposes fast has been avoided. Then the temperature of the ozone generated by ionization is reduced, so that the temperature of the ozone is further reduced, the decomposition speed of the ozone is reduced, and the working efficiency of the ozone generator is improved.

The above description of the present invention does not limit the scope of the present invention. Any other corresponding changes and modifications made according to the technical idea of the present invention should be included in the scope of the claims of the present invention.

Claims

1. An ozone generator, comprising:

2. The ozone generator as claimed in claim 1, wherein the first heat dissipating pipe is formed in a spiral shape and arranged along an inner wall of the first receiving chamber, and the second heat dissipating pipe is formed in a spiral shape and arranged along an inner wall of the second receiving chamber.

3. The ozone generator as claimed in claim 2, wherein one end of the first heat pipe is connected to one end of the second heat pipe.

4. The ozone generator as claimed in claim 3, further comprising a water supply assembly, wherein the water supply assembly comprises a water tank, a water pump, a water inlet pipe, a water return pipe and a water suction pipe, one end of the water inlet pipe extends into the water tank, the other end of the water inlet pipe is connected to the water inlet end of the water pump, one end of the water inlet pipe is connected to the output end of the water pump, the other end of the water inlet pipe is connected to the free end of the second heat dissipation pipe, one end of the water return pipe is connected to the free end of the first heat dissipation pipe, the other end of the water return pipe is connected to the water tank, one end of the water suction pipe is connected.

5. The ozone generator as claimed in claim 4, wherein the top end of the water tank is provided with a slot, the bottom end of the housing extends to form a latch, and the latch is embedded in the slot.

6. The ozone generator as claimed in claim 1, wherein a guide plate is disposed at an end of the ionization cylinder near the second receiving cavity, the guide plate has a convex surface facing an end surface of the ionization cylinder, and a connecting rib extends from an outer edge of the guide plate, and a free end of the connecting rib is fixed to an inner wall of the ionization cylinder.

7. The ozone generator of claim 1, wherein a filter screen is disposed at an end of the ionization cylinder adjacent to the first receiving cavity.