CN109954415B

CN109954415B - Ozone water mixing device and cleaning equipment with same

Info

Publication number: CN109954415B
Application number: CN201910342810.8A
Authority: CN
Inventors: 沈选举; 叶秀友; 鲁建湘; 张能
Original assignee: Zhejiang Uish Environment Technology Co ltd
Current assignee: Zhejiang Uish Environment Technology Co ltd
Priority date: 2019-04-26
Filing date: 2019-04-26
Publication date: 2024-05-14
Anticipated expiration: 2039-04-26
Also published as: CN109954415A

Abstract

The invention discloses an ozone water mixing device and cleaning equipment with the same, comprising a base, a gas diffusion plate, a main body, a runner body and an upper cover, wherein the main body comprises an upper part and a lower part, and is provided with a through hole for communicating the upper part and the lower part; a closed cavity is formed between the lower part of the main body and the base in a matched manner, and the gas diffusion plate is arranged in the cavity and divides the cavity into a gas diffusion cavity positioned at the lower part and a first mixing cavity positioned at the upper part; the base is provided with an air inlet communicated with the air diffusion cavity; the main body is provided with a water inlet communicated with the first mixing cavity; a sealed second mixing part is formed between the upper part of the main body and the upper cover in a matched manner, a spiral flow passage is formed in the second mixing part, the flow passage comprises an inflow part and an outflow part, and the through hole is communicated with the inflow part; the second mixing part is provided with a water outlet communicated with the outflow part. The invention has simple structure, high concentration of the generated ozone water and better cleaning and sterilizing of articles.

Description

Ozone water mixing device and cleaning equipment with same

Technical Field

The invention relates to the technical field of cleaning equipment, in particular to an ozone water mixing device and cleaning equipment with the same.

Background

With the continuous development of society, the requirements of human beings on sanitation, environment and health are increasingly urgent. However, at present, chemical fertilizers and pesticides are basically sprayed on plants to enable the surfaces of the fruits and vegetables to be still possible to have partial toxic organic matter residues after the fruits and vegetables are ripe, and if the residues cannot be effectively and thoroughly removed before eating, chronic accumulation is gradually formed in human bodies after eating, and the residues are harmful to the human bodies for a long time. Various meats have a large amount of salmonella bacteria, and the flushing with water can cause bacterial splatter, which contaminates the tableware and can cause disease. The traditional disinfection mode is to use disinfection solution, bleaching powder or equipment for electrolyzing tap water to generate chlorine to dissolve in water to generate hypochlorous acid, but the disinfection mode can generate halogenated substances during disinfection to cause secondary pollution; ozone disinfection is also adopted in the market, but simple explosive gas stones or jet devices are used for dissolving oxygen, so that ozone is difficult to dissolve in water, the ozone concentration in water cannot meet the disinfection requirement, a large amount of ozone can volatilize into the air to cause air pollution, and meanwhile, the existing disinfection device is large in size, troublesome to carry and has an improved space.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides the ozone water mixing device and the cleaning equipment with the mixing device, and the mixing device can better mix ozone and water to generate high-concentration ozone water, so that the cleaning and disinfecting effects of the cleaning equipment on articles are improved.

In order to achieve the above purpose, the invention provides an ozone water mixing device, which comprises a base, a gas diffusion plate, a main body, a runner body and an upper cover, wherein the main body comprises an upper part and a lower part, and a through hole is arranged in the middle of the main body corresponding to the upper part and the lower part;

A closed cavity is formed between the lower part of the main body and the base in a matched manner, and the gas diffusion plate is arranged in the cavity and divides the cavity into a gas diffusion cavity positioned at the lower part and a first mixing cavity positioned at the upper part;

The base is provided with an air inlet communicated with the air diffusion cavity;

The main body is provided with a water inlet communicated with the first mixing cavity;

a sealed second mixing part is formed between the upper part of the main body and the upper cover in a matched manner, a spiral flow passage is formed in the second mixing part, the flow passage comprises an inflow part and an outflow part, and the through hole is communicated with the inflow part;

the second mixing part is provided with a water outlet communicated with the outflow part.

Further provided is that: the upper part of the main body is provided with a baffle with a spiral structure, the upper cover covers the upper part of the main body, the upper end part of the baffle is in sealing fit with the lower end surface of the upper cover, and a spiral flow passage is formed between the upper part of the main body and the upper cover.

Further provided is that: the outflow portion is provided on the side wall of the upper portion of the main body or the upper cover.

Further provided is that: a flow channel body is arranged between the main body and the upper cover, the upper layer of the main body seals the lower port of the flow channel body, and the upper cover seals the upper port of the flow channel body;

The flow channel body is internally provided with at least two layers of sub-mixing parts from bottom to top, the sub-mixing parts are internally provided with guide ribs which are spirally arranged, the sub-mixing part positioned at the lowest part is matched with the upper part of the main body to form a cavity with a spiral flow dividing channel, the sub-mixing part positioned at the uppermost part is matched with the upper cover to form a cavity with a spiral flow dividing channel, and the inner structure of the sub-mixing part positioned in the middle is provided with a spiral flow dividing channel;

And communication ports which enable the branch flow passages to be connected end to end are arranged between the adjacent branch mixing parts.

Further provided is that: when the number of the sub-mixing parts is even, the water outlets are arranged in the middle of the upper cover;

when the number of the sub-mixing parts is odd, the water outlets are arranged on the side wall of the runner body.

Further provided is that: a first sealing gasket is arranged between the lowest mixing part and the upper part of the main body, the flow guide rib is propped against the first sealing gasket, and a first via hole communicated with the through hole is arranged on the first sealing gasket;

a second sealing gasket is arranged between the uppermost sub-mixing part and the upper cover, and the diversion ribs are propped against the second sealing gasket;

and when the number of the sub-mixing parts is even, the second sealing gasket is provided with second through holes communicated with the water outlet.

A cleaning device comprises a shell, an ozone generating device, an air pump, a water outlet device, a controller and a mixing device;

The controller is used for controlling the operation of the cleaning equipment;

the ozone generating device, the air pump and the mixing device are arranged on the shell, the air pump is connected with the inlet of the ozone generating device, and the air pump is used for sucking air outside the shell and supplying the air to the ozone generating device;

The outlet of the ozone generating device is connected with the air inlet of the mixing device and is used for supplying the generated ozone to the mixing device;

the water inlet of the mixing device is connected with a water source, the water outlet of the mixing device is connected with a water outlet device, and the mixing device supplies the generated ozone water to the water outlet device.

Further provided is that: and a one-way valve is arranged on the air inlet pipeline between the ozone generating device and the mixing device.

Further provided is that: a pressure reducing valve and an electromagnetic valve are arranged on a water inlet pipeline between the mixing device and the water source.

Compared with the prior art, the ozone water mixing device has a simple and small structure, divides ozone into smaller micro-nano bubbles through the gas diffusion plate, and effectively prolongs the mixing path and time of ozone and water through the spiral flow passage, so that the solubility of ozone can be effectively improved, the concentration of generated ozone water is improved, and the cleaning effect and the disinfection effect of cleaning equipment are effectively improved.

Drawings

FIG. 1 is a schematic view of an axial separation structure (guide rib) of an ozone water mixing device of the invention;

FIG. 2 is a schematic cross-sectional structure of an ozone water mixing device;

FIG. 3 is a schematic view of an axial separation structure (barrier) of an ozone water mixing device;

Fig. 4 is a schematic structural view of the cleaning apparatus.

The following reference numerals are attached thereto in combination with the accompanying drawings:

1. A housing; 2. an ozone generating device; 3. a controller; 4. an air pump; 5. a mixing device; 51. a main body; 511. an upper part; 512. a lower part; 513. a through hole; 514. a water inlet; 52. a base; 521. an air inlet; 53. an upper cover; 531. a water outlet; 54. a flow channel body; 541. a sub-mixing section; 542. a flow guiding rib; 55. a gas diffusion plate; 56. a first gasket; 561. a first via; 57. a second gasket; 571. a second via; 58. a gas diffusion chamber; 59. a first mixing chamber; 510. a baffle; 6. a one-way valve; 7. a pressure reducing valve; 8. an electromagnetic valve; 9. and a water outlet device.

Detailed Description

One embodiment of the present invention will be described in detail below with reference to the attached drawings, but it should be understood that the scope of the present invention is not limited by the embodiment.

The invention relates to an ozone water mixing device, as shown in fig. 1 and 2, which comprises a main body 51, an upper cover 53, a base 52 and a gas diffusion plate 55; the main body 51 includes an upper portion 511 and a lower portion 512, and a through hole 513 is provided at the middle of the upper portion 511 and the lower portion 512; the base 52 cooperates with the lower portion 512 of the main body 51 to form a closed chamber, and the gas diffusion plate 55 is horizontally disposed in the chamber and divides the chamber into a first mixing chamber 59 at the upper portion 511 and a gas diffusion chamber 58 at the lower portion 512; the base 52 is provided with an air inlet 521 communicated with the air diffusion chamber 58, and the lower part 512 of the main body 51 is provided with an water inlet 514 communicated with the first mixing chamber 59; the upper cover 53 is located above the upper portion 511 of the main body 51, and a sealed second mixing part is formed between the upper cover and the upper cover, the second mixing part is internally provided with a spiral flow passage, the flow passage comprises an inflow part and an outflow part, and a through hole 513 on the main body 51 is communicated with the inflow part of the flow passage; thereby ozone gets into gas diffusion chamber 58 through air inlet 521, ozone permeates into first mixing chamber 59 through the gas diffusion hole on the gas diffusion plate 55 and forms less micro-nano bubble, water gets into first mixing chamber 59 through water inlet 514, ozone and water preliminary mix in first mixing chamber 59, then get into the second mixing part of upper portion 511 through-hole 513, mix once more through spiral runner, the water that flows at a high speed can form spiral rivers in spiral runner, cut the ozone bubble and form less micro-nano bubble, effectually improve the solubility of ozone, the concentration of ozone water has been improved.

As shown in fig. 1 and 2, a flow channel body 54 may be disposed between the upper portion 511 and the upper cover 53 of the main body 51, the flow channel body 54 having a spiral flow channel therein, and the upper portion 511 and the upper cover 53 of the main body 51 are respectively in sealing engagement with the lower port and the upper port of the flow channel body 54, so that a second mixing portion is formed by engagement between the upper portion 511 of the main body 51, the flow channel body 54 and the upper cover 53; the flow channel body 54 has at least two layers of sub-mixing parts 541 from bottom to top, spiral guide ribs 542 are arranged in the sub-mixing parts 541, a cavity with spiral flow distribution channels is formed between the sub-mixing part 541 at the lowest layer and the upper part 511 of the main body 51 in a matching manner, and the guide ribs 542 in the sub-mixing part 541 at the lowest layer are in sealing contact with the end surface of the upper part 511 of the main body 51; the upper cover 53 and the upper mixing part 541 at the uppermost layer are matched to form a cavity with a spiral flow dividing channel, and the flow guide ribs 542 in the upper mixing part 541 at the uppermost layer are in sealing contact with the lower end surface of the upper cover 53; a cavity having a spiral-shaped flow dividing passage is formed in the intermediate mixing portion 541; communication ports are arranged between the cavities between adjacent layers of the runner body 54, and the communication ports enable adjacent flow distribution channels to be connected end to form continuous runners.

As further shown in fig. 3, the spiral flow channel has a single-layer structure, the upper portion 511 of the main body 51 is provided with the baffle 510 with a spiral structure, the upper cover 53 is in sealing fit with the upper portion 511 of the main body 51, and the upper end portion of the baffle 510 is in sealing contact with the upper cover 53, so that the upper portion 511 of the main body 51 and the upper cover 53 are matched to form the second mixing portion with the spiral flow channel.

In the above-described aspect, when the number of the sub-mixing portions 541 of the flow path body 54 is an even number, the water outlet 531 is provided in the middle of the upper cover 53; when the number of the sub-mixing portions 541 is an odd number, the water outlet 531 is provided on the side wall of the flow path body 54; further preferably, a first gasket 56 is disposed between the lowermost mixing portion 541 and the upper portion 511 of the main body 51, the guide rib 542 is pressed against the first gasket 56, and the first gasket 56 is provided with a first through hole 561 communicating with the through hole 513; a second sealing gasket 57 is arranged between the uppermost sub-mixing part 541 and the upper cover 53, and the diversion ribs 542 are pressed against the second sealing gasket 57; when the number of the sub-mixing portions 541 is even, the second gasket 57 is provided with second through holes 571 communicating with the water outlet 531.

A cleaning apparatus as shown in FIG. 4 comprises a housing 1, an ozone generating device 2, a mixing device 5, an air pump 4, a controller 3, a water outlet device 9, a one-way valve 6, an electromagnetic valve 8 and a pressure reducing valve 7; the controller 3 is used for controlling the cleaning equipment to work; an ozone generating device 2, a mixing device 5 and an air pump 4 are arranged in the housing 1, the air pump 4 is connected with an inlet of the ozone generating device 2 and is used for sucking air outside the housing 1 and supplying the air to the ozone generating device 2; the outlet of the ozone generating device 2 is connected to the inlet 521 of the mixing device 5 for supplying the generated ozone to the gas diffusion chamber 58 of the mixing device 5; the water inlet 514 of the mixing device 5 is connected with a water source, and the water outlet 531 of the mixing device 5 is connected with the water outlet device 9.

Further preferably, a one-way valve 6 is arranged on the air inlet pipeline between the ozone generating device 2 and the mixing device 5, so that the backflow phenomenon can be effectively avoided; a pressure reducing valve 7 and an electromagnetic valve 8 are arranged on the water inlet pipeline between the mixing device 5 and the water source.

The above disclosure is merely an example of the present invention, but the present invention is not limited thereto, and any variations that can be considered by a person skilled in the art should fall within the protection scope of the present invention.

Claims

1. The ozone water mixing device is characterized by comprising a base, a gas diffusion plate, a main body, a runner body and an upper cover, wherein the main body comprises an upper part and a lower part, and a through hole is formed in the middle of the main body corresponding to the upper part and the lower part;

A runner body is arranged between the upper part of the main body and the upper cover, the upper part of the main body seals the lower port of the runner body, and the upper cover seals the upper port of the runner body;

A communication port which enables the branch flow channels to be connected end to end is arranged between the adjacent branch mixing parts;

When the number of the sub-mixing parts is even, the middle part of the upper cover is provided with water outlets;

when the number of the sub-mixing parts is odd, the side wall of the runner body is provided with water outlets.

2. The ozone water mixing device according to claim 1, wherein a first sealing gasket is arranged between the lowest mixing part and the upper part of the main body, the guide rib is pressed against the first sealing gasket, and a first through hole communicated with the through hole is arranged on the first sealing gasket;

3. A cleaning apparatus comprising a housing, ozone generating means, an air pump, water outlet means, a controller, and a mixing device according to any one of claims 1-2;

The controller is used for controlling the operation of the cleaning equipment;

4. A cleaning apparatus according to claim 3, wherein a one-way valve is provided in the air inlet line between the ozone generating means and the mixing means.

5. The cleaning apparatus of claim 4, wherein a pressure reducing valve and a solenoid valve are provided on the water inlet line between the mixing device and the water source.