CN214327906U - Low-pressure hydrolysis ozone generating device based on airflow - Google Patents

Abstract

The embodiment of the application discloses an ozone generating device is hydrolysised to low pressure based on air current for improve the production rate of ozone. The embodiment of the application comprises the following steps: a pure water barrel, a generator, an ozone-resistant air pump and a three-way joint; the pure water barrel is communicated with the generator by using a pipeline; the ozone-resistant pump is communicated with the pure water barrel through a pipeline and is used for guiding outside air to a pipeline through which ozone is discharged; the three-way joint is arranged at the intersection of the water replenishing pump, the pure water barrel and a pipeline communicated with the generator; the pure water tank is used for providing water to the generator, and when the generator works, the generator is used for preparing ozone through a hydrolysis mode. Because the ozone-resistant pump is used for guiding the outside air into the pipeline through which the ozone is discharged, the ozone discharge speed is higher by utilizing the air convection principle.

Description

Low-pressure hydrolysis ozone generating device based on airflow

Technical Field

The embodiment of the application relates to the field of electronic ozone preparation, in particular to a low-pressure hydrolysis ozone generating device based on airflow.

Background

With the increase of the per capita income, the consumption level is also increased; the consumption level is increased more and more, and correspondingly, the generated garbage is increased. Whether the recyclable garbage or the non-recyclable garbage is accumulated, the recyclable garbage or the non-recyclable garbage inevitably generates odor pollution, and the odor can seriously affect the health of human beings and also cause secondary pollution.

In the prior art, the device for treating malodorous gas utilizes uv photodissociation technique, ozone oxidation's processing technology and photooxidation technique combination technology process malodorous gas, make it can be quick effectual produce a large amount of ozone and ozone have strong oxidizing property, so make its treatment effect to malodorous gas improve by a wide margin, but because ozone gas can have certain aqueous vapor when outwards discharging after being produced, meet cold air and can become water then be detained in exhaust duct, and ozone meets water and forms ozone water, ozone water has strong corrosivity, lead to exhaust duct to use the life to reduce.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a low pressure ozone generating device that hydrolysises based on air current for in the pipeline that discharges the process with external air drainage to ozone, utilize the air convection principle, make the emission rate of ozone faster.

The present application provides in a first aspect an airflow-based low pressure hydrolysis ozone generator comprising: a pure water barrel, a generator, an ozone-resistant air pump and a three-way joint; the pure water barrel is communicated with the generator by using a pipeline; the ozone-resistant pump is communicated with the pure water barrel through a pipeline and is used for guiding outside air to a pipeline through which ozone is discharged; the three-way joint is arranged at the intersection of a water replenishing pipeline, the pure water barrel and a pipeline communicated with the generator; the pure water barrel is used for providing water to the generator, when the generator works, the generator is used for preparing ozone in a hydrolysis mode, and the ozone is discharged through the generator, the pure water barrel and the ozone-resistant gas pump through pipelines.

Optionally, the low-pressure hydrolysis ozone generating device based on the air flow further comprises an ozone-resistant adjusting valve, and the ozone-resistant adjusting valve is arranged on the pure water barrel and a pipeline communicated with the ozone-resistant air pump.

Optionally, the low-pressure hydrolysis ozone generating device based on the air flow further comprises an ozone-resistant one-way valve, and the ozone-resistant one-way valve is arranged on the ozone-resistant adjusting valve and the ozone-resistant air pump communicating pipeline.

Optionally, a pure water barrel ozone port is arranged above the top of the pure water barrel and used for discharging ozone.

Optionally, the low-pressure hydrolysis ozone generating device based on the air flow further comprises a water replenishing pump, the water replenishing pump is communicated with the pure water barrel through a pipeline, and the water replenishing pump is used for supplying water to the pure water barrel.

Optionally, a pure water bung hole is arranged at the top of the pure water bucket, and the pure water bung hole is communicated with the generator through a pipeline.

Optionally, a water inlet and a water outlet are arranged at the top of the water replenishing pump; the water outlet is communicated with the pure water barrel through a pipeline.

Optionally, the top of the generator is provided with a generator ozone outlet and a generator hydrogen outlet; the generator ozone gas outlet is communicated with the pure water barrel through a pipeline, and the generator hydrogen port is communicated with the pure water barrel port through a pipeline.

Optionally, the pure water tank and the generator using pipeline communication comprises: the generator is arranged outside the bottom of the pure water barrel and is communicated with the pure water barrel by using a pipeline.

Optionally, the ozone-resistant pump and the pure water bucket use the pipeline intercommunication to include: the ozone-resistant gas pump is externally arranged on the left side of the top of the pure water barrel and is communicated with the pure water barrel through a pipeline.

According to the technical scheme, the embodiment of the application has the following beneficial effects:

the high-efficiency low-pressure hydrolysis ozone generating device is provided with a pure water barrel, a generator, an ozone-resistant air pump and a three-way joint; the pure water barrel is communicated with the generator by using a pipeline, and the ozone-resistant pump is used for guiding outside air to the pipeline through which ozone is discharged; the ozone-resistant pump is communicated with the pure water barrel through a pipeline; the three-way joint is arranged at the junction of two pipelines communicated by the water supplementing pipeline, the pure water barrel and the generator; the pure water bucket is used for providing water to the generator, works as the generator during operation, the generator is used for taking place to hydrolyze and prepares ozone, and ozone passes through the pipeline the generator pure water bucket with ozone resistant air pump discharges, because ozone resistant air pump is used for discharging the pipeline of process with external air drainage to ozone in, utilizes the air convection principle for ozone's exhaust velocity is faster.

Drawings

Fig. 1 is a schematic structural diagram of an airflow-based low-pressure hydrolysis ozone generating device according to an embodiment of the present application.

Detailed Description

In the present application, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "middle", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are used only for explaining relative positional relationships between the respective members or components, and do not particularly limit specific mounting orientations of the respective members or components.

Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meaning of these terms in this application will be understood by those of ordinary skill in the art as appropriate.

Furthermore, the terms "mounted," "disposed," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

In addition, the structures, the proportions, the sizes, and the like, which are illustrated in the accompanying drawings and described in the present application, are intended to be considered illustrative and not restrictive, and therefore, not limiting, since those skilled in the art will understand and read the present application, it is understood that any modifications of the structures, changes in the proportions, or adjustments in the sizes, which are not necessarily essential to the practice of the present application, are intended to be within the scope of the present disclosure without affecting the efficacy and attainment of the same.

Referring to fig. 1, in a first aspect, the present application provides an apparatus for generating ozone by low pressure hydrolysis based on airflow, comprising: a pure water barrel 101, a generator 102, an ozone-resistant gas pump 103 and a three-way joint 104; the pure water barrel 101 is communicated with the generator 102 by a pipeline; the ozone-resistant gas pump 103 is communicated with the pure water barrel 101 by using a pipeline, and the ozone-resistant gas pump 103 is used for guiding outside air to a pipeline through which ozone is discharged; the three-way joint 104 is arranged at the junction of two pipelines of the water replenishing pipeline, the pure water barrel 101 and the generator 102; the pure water tank 101 is used to supply water to the generator 102, and when the generator 102 is operated, the generator 102 is used to prepare ozone by hydrolysis, and the ozone is discharged through the generator 102, the pure water tank 101, and the ozone-resistant pump 103 via pipes.

In practical application, the generated liquid in the pure water tank 101 is led to the generator 102 through a pipeline, so that the generator 102 can electrolyze the generated liquid after being powered on to obtain ozone and hydrogen, the generated ozone flows from the generator 102 to the pure water tank through the pipeline, and the ozone reaching the pure water tank 101 is discharged to the outside through a water pipeline and the ozone-resistant pump 103; the generated hydrogen gas will enter the pure water tank 101 from the generator through the pipe and the three-way joint 104.

In this embodiment, the ozone-resistant pump 103 drains a small amount of air from the outside into the pipeline through which ozone is discharged during the discharge of ozone generated in the generator 102, and accelerates the discharge speed of ozone by using the air convection principle, and secondly, since ozone is corrosive, accelerating the discharge speed of ozone can prolong the service life of the discharge pipeline for discharging ozone. The use of the three-way joint 104 enables the hydrogen gas which is guided into the water inlet pipeline of the generator 102 and the pure water barrel 101 through pipeline connection to exist, and the volume of the hydrogen gas occupies the water inlet pipeline, so that the ozone discharged to the pure water barrel 101 can not enter the water inlet pipeline due to the flow instability of the gas to corrode the water inlet pipeline.

Optionally, the low-pressure hydrolysis ozone generating device based on the air flow further comprises an ozone-resistant adjusting valve 105, wherein a pure water barrel ozone port 107 and an ozone-resistant one-way valve 106, which are arranged above the top of the pure water barrel 101, are arranged on a pipeline for communicating the pure water barrel 101 and the ozone-resistant pump 103; the ozone-resistant one-way valve 106 is arranged on a pipeline which is communicated with the ozone-resistant regulating valve 105 and the ozone-resistant air pump 103; the pure water barrel ozone port 107 is used for discharging ozone.

In practical application, after the generator 102 generates liquid through electrolysis, ozone and hydrogen are obtained, the ozone in the generator 102 enters the pure water barrel 101 through a pipeline, and then is guided to the ozone-resistant air pump 103 from the pure water barrel ozone port 107 arranged at the top of the pure water barrel 101 through a pipeline, the ozone-resistant air pump 103 discharges the ozone from the pipeline to the outside, when the ozone-resistant air pump 103 introduces outside air, the ozone-resistant adjusting valve 105 is used for adjusting the pressure of the ozone-resistant air pump 103 relative to the outside, so that the pressure difference exists between the inside and the outside of the ozone-resistant air pump 103, the ozone is discharged from the pipeline to the outside, and the ozone-resistant one-way valve 106 arranged on the pipeline communicated with the ozone-resistant adjusting valve 105 and the ozone-resistant air pump 103 is used for preventing the ozone which is discharged to the outside from entering the discharge pipeline from the pipeline.

In this embodiment, the ozone-resistant valve 105 makes the ozone-resistant pump 103 have different internal and external pressures, so that the ozone discharge is more stable and clean.

Optionally, the low-pressure hydrolysis ozone generating device based on the air flow further comprises a water replenishing pump 108, and a water inlet 110 and a water outlet 111 are arranged at the top of the water replenishing pump 108; the water outlet 111 is communicated with the pure water barrel 101 through a pipeline, the water inlet 110 is used for supplying water resources to the water outlet 111, the water replenishing pump 108 is communicated with the pure water barrel 101 through a pipeline, and the water replenishing pump 108 is used for replenishing water to the pure water barrel 101.

In practical applications, the generation liquid needs to be filled into the deionized water tank 101 before the deionized water tank 101 supplies the generation liquid to the generator 102, and in this embodiment, the generation liquid is automatically pumped and drained into the deionized water tank 101 by using the replenishment pump 108, so that the generation liquid in the deionized water tank 101 is sufficient.

In the present embodiment, the amount of work for manually storing the treatment liquid in the deionized water tank 108 can be reduced by replenishing the treatment liquid in the deionized water tank 101 using the replenishment pump 108.

The water replenishing pump uses the gear teeth of the water replenishing pump to be mutually separated to form low pressure, the generated liquid is sucked into the water replenishing pump 108 from the water inlet 110 and is pushed to the gear end of the water outlet 111 close to the other side from the gear end of the shell wall close to the water inlet 110, the gears close to the water outlet 111 are mutually folded to form high pressure, and the generated liquid is pushed into the pure water barrel 101 from the water outlet 111 to be replenished to the pure water barrel 101.

Optionally, the top of the pure water tank 101 is provided with a pure water tank opening 109, the top of the generator 102 is provided with a generator ozone outlet 112, the side wall surface is provided with a generator hydrogen opening 113, the generator ozone outlet 112 communicates the generator 102 with the pure water tank 101 by using a pipeline, and the generator hydrogen opening 113 is in butt joint with the pure water tank opening 109 by using another pipeline, so that the generator 102 communicates with the pure water tank 101.

In practical application, after the generator 102 electrolyzes the generating liquid to generate ozone and hydrogen, the hydrogen in the generator 102 is introduced from the generator hydrogen port 113 of the generator 102 to the pure water tank water port 109 above the top of the pure water tank 101, and the hydrogen is introduced from the generator 102 to the pure water tank 101 through a pipeline communicated by a three-way joint. The pure water tank water port 109 of the pure water tank 101 is arranged above the top of the pure water tank 101, so that the density of the hydrogen gas is smaller than that of the air, and the hydrogen gas can float upwards, so that the pure water tank water port 109 is more suitable for collecting or guiding the hydrogen gas generated by the flow generator 102 in operation when arranged above the pure water tank 101. Ozone in the generator 102 is led from the generator ozone outlet 112 of the generator 102 to the pure water bucket ozone port 107 of the pure water bucket 101 by a pipeline to lead the generated ozone gas from the generator 102 to the pure water bucket 101, and the ozone gas passes through the pure water bucket 101 and is discharged to the outside through the pure water bucket ozone port 108 provided above the top of the pure water bucket 101.

Optionally, the generator 102 is externally disposed at the bottom of the pure water tank 101, the generator 102 is communicated with the pure water tank 101 by a pipeline, and the ozone-resistant pump 103 is externally disposed at the top of the pure water tank 101 and communicated with the pure water tank 101 by a pipeline.

In practical application, the generation liquid in the generator 102 is obtained by draining the generation liquid in the pure water tank 101 through a pipeline during generation liquid drainage, so that the generator 102 is externally arranged at the bottom of the pure water tank 101, the gravity factor of the generation liquid is utilized, and the generation liquid can be drained to the generator 102 without increasing or decreasing or reducing the pressure in the pipeline for communicating the generator 102 with the pure water tank 101 during drainage. Ozone generated in the generator 102 is discharged to the outside through the ozone-resistant gas pump 103 after entering the pure water tank 101, and the ozone-resistant gas pump 103 is externally provided to the left side of the top of the pure water tank 101 and communicates with the pure water tank 101 using a pipe, so that the discharged ozone is discharged from the left side of the apparatus.

It is intended that the foregoing description of the disclosed embodiments enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. An airflow-based low pressure hydrolysis ozone generator, comprising:

a pure water barrel, a generator, an ozone-resistant air pump and a three-way joint; the pure water barrel is communicated with the generator by using a pipeline; the ozone-resistant pump is communicated with the pure water barrel through a pipeline and is used for guiding outside air to a pipeline through which ozone is discharged; the three-way joint is arranged at the intersection of a water replenishing pipeline, the pure water barrel and a pipeline communicated with the generator; the pure water barrel is used for providing water to the generator, when the generator works, the generator is used for preparing ozone in a hydrolysis mode, and the ozone is discharged through the generator, the pure water barrel and the ozone-resistant gas pump through pipelines.

2. The gas flow based low pressure hydrolysis ozone generator as claimed in claim 1, further comprising an ozone-resistant regulating valve disposed on a pipe connecting the pure water tank and the ozone-resistant pump.

3. The airflow-based low-pressure hydrolysis ozone generating device according to claim 2, further comprising an ozone-resistant check valve, wherein the ozone-resistant check valve is disposed on the pipeline connecting the ozone-resistant regulating valve and the ozone-resistant air pump.

4. The gas flow based low pressure ozone generator for hydrolysis as claimed in claim 1, wherein the pure water tank has an ozone outlet for discharging ozone above the top of the pure water tank.

5. The gas flow based low pressure hydrolysis ozone generator as claimed in any one of claims 1 to 4, further comprising a water make-up pump in communication with the pure water tank through a pipe, the water make-up pump being used to supply water to the pure water tank.

6. The gas flow based low pressure hydrolysis ozone generator as claimed in any one of claims 1 to 4, wherein the top of the pure water barrel is provided with a pure water barrel opening, and the pure water barrel opening is communicated with the generator through a pipeline.

7. The airflow-based low-pressure hydrolysis ozone generating device as claimed in claim 5, wherein the top of the water replenishing pump is provided with a water inlet and a water outlet; the water outlet is communicated with the pure water barrel through a pipeline.

8. The airflow based low pressure hydrolysis ozone generator as claimed in claim 6, wherein the generator top is provided with a generator ozone outlet and a generator hydrogen outlet; the generator ozone gas outlet is communicated with the pure water barrel through a pipeline, and the generator hydrogen port is communicated with the pure water barrel port through a pipeline.

9. The airflow based low pressure hydrolysis ozone generator as claimed in any one of claims 1 to 4, wherein the pure water tank and the generator usage pipe communication comprises: the generator is arranged outside the bottom of the pure water barrel and is communicated with the pure water barrel by using a pipeline.

10. The airflow based low pressure hydrolysis ozone generator as claimed in any one of claims 1 to 4, wherein the ozone resistant pump in communication with the pure water tank using pipe comprises: the ozone-resistant gas pump is externally arranged on the left side of the top of the pure water barrel and is communicated with the pure water barrel through a pipeline.

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