CN217418826U - Ozone generator experimental device - Google Patents

Abstract

The utility model provides an ozone generator experimental device, which comprises an ozone generator, a first air source component and a second air source component, wherein the first air source component and the second air source component can respectively provide a first air source and a second air source for the ozone generator through an air inlet pipeline; the first gas source is oxygen with a first preset concentration, and the second gas source is nitrogen with a second preset concentration. By adopting the structure, the first gas source and the second gas source are mixed and then are sent to the ozone generator to produce ozone, and the influence of the added nitrogen on the yield of the ozone generator is researched by changing the concentrations of the first gas source and the second gas source; the ozone generator experimental device can be used as a novel ozone generator, the first air source and the second air source which are high in yield are matched, the yield of the ozone generator can be greatly improved, and the energy consumption of the ozone generator is reduced.

Description

Ozone generator experimental device

Technical Field

The utility model relates to an ozone machine technical field, concretely relates to ozone generator experimental apparatus.

Background

Ozone is an allotrope of oxygen, has strong oxidizing property, is an oxidant stronger than oxygen, can perform an oxidation reaction at a lower temperature, can be used as a strong oxidant, a bleaching agent, a fur deodorizer, an air purifying agent, a sanitizer and the like, and is applied to many fields.

Ozone is usually produced by an ozone generator, the ozone generator in the prior art is divided into a closed type and an open type, the closed type means that oxygen reacts in a closed device to output ozone with higher concentration, the closed type ozone generator usually adopts high-concentration oxygen as a gas source to generate ozone in an electrolysis mode and other modes, and because ozone is extremely easy to reduce and decompose, in the process of outputting the generated ozone to the outside of the ozone generator, partial ozone is reduced and decomposed, so that the final output ozone concentration is lower, and the ozone yield is lower.

Therefore, how to provide an ozone generator with high ozone yield is a technical problem to be solved urgently by the technical personnel in the field.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an ozone generator that ozone productivity is higher.

In order to solve the technical problem, the utility model provides an ozone generator experimental device, which comprises an ozone generator, a first air source component and a second air source component, wherein the first air source component and the second air source component can respectively provide a first air source and a second air source for the ozone generator through an air inlet pipeline, the second air source component comprises a gas flowmeter, and the gas flowmeter can control the air inlet flow of the second air source; the first gas source is oxygen with a first preset concentration, and the second gas source is nitrogen with a second preset concentration.

By adopting the structure, the first gas source and the second gas source are mixed and then are sent to the ozone generator to produce ozone, and the influence of adding nitrogen on the yield of the ozone generator is researched by changing the concentrations of the first gas source and the second gas source; the ozone generator experimental device can be used as a novel ozone generator, and the first air source and the second air source which are high in yield are matched, so that the yield of the ozone generator can be greatly improved, and the energy consumption of the ozone generator is reduced.

Optionally, the second air source assembly includes a compressor and a filter, and the second air source is filtered compressed air.

Optionally, the second air source assembly further includes a cold dryer, a suction dryer and an air source triple piece which are sequentially communicated with the downstream of the compressor and the filter, and the downstream of the air source triple piece is connected with the air flow meter and the air inlet pipeline.

Optionally, a detection component is disposed between the gas source triplet and the gas flow meter, and the detection component is capable of detecting at least the pressure of the second gas source therebetween.

Optionally, the gas flow meter is capable of controlling the opening of the gate valve to control the flow of the second gas source.

Optionally, the ozone generator further comprises an air outlet pipeline, and the ozone generator can output ozone from the air outlet pipeline.

Optionally, the air inlet pipeline and the air outlet pipeline are both made of metal.

Drawings

Fig. 1 is a schematic structural diagram of an experimental device of an ozone generator provided by the embodiment of the utility model.

The reference numerals in fig. 1 are explained as follows:

the air conditioner comprises an ozone generator 1, an air inlet pipeline 2, an air flow meter 3, a compressor 4, a filter 5, a cold dryer 6, a suction dryer 7, an air source triple piece 8 and an air outlet pipeline 9.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the present invention will be further described in detail with reference to the accompanying drawings and specific embodiments.

The embodiment of the utility model provides an ozone generator experimental apparatus, please refer to fig. 1, including ozone generator 1, first air supply subassembly and second air supply subassembly can provide first air supply and second air supply for ozone generator 1 respectively through air inlet pipe 2, and the second air supply subassembly includes gas flowmeter 3, and gas flowmeter 3 can control the air input flow of second air supply; the first gas source is oxygen with a first preset concentration, and the second gas source is nitrogen with a second preset concentration.

By adopting the structure, the first gas source and the second gas source are mixed and then are sent to the ozone generator 1 to produce ozone, and the influence of adding nitrogen on the yield of the ozone generator 1 is researched by changing the concentrations of the first gas source and the second gas source; the ozone generator experimental device can be used as a novel ozone generator, the first air source and the second air source which are high in yield are matched, the yield of the ozone generator 1 can be greatly improved, and the energy consumption of the ozone generator 1 is reduced.

Specifically, as shown in fig. 1, the influence of the nitrogen concentration on the yield of the ozone generator 1 can be conveniently measured by changing the oxygen concentration of the first gas source and the nitrogen concentration of the second gas source, controlling the gas inflow of the second gas source through the gas flowmeter 3 to change the ratio of the first gas source to the second gas source, and then measuring the ozone concentration output by the ozone generator 1.

Because part of the ozone can be reduced into oxygen in the output process, and after nitrogen with certain concentration is added, the output speed of the ozone can be increased, and the ozone does not react with the ozone to reduce the ozone, the output ozone amount is increased, and the yield of the ozone generator 1 is improved; and because the concentration of the oxygen input into the ozone generator 1 is reduced, the power required by the ozone generator 1 can be reduced, and the energy consumption of the ozone generator 1 is indirectly reduced.

After the influence of the nitrogen concentration on the yield of the ozone generator 1 is tested, the proportion of a first air source and a second air source with higher yield can be selected, and the whole ozone generator experimental device is used as a novel ozone generator, so that the ozone generator has the effects of higher yield and lower power consumption.

The first concentration of predetermineeing concentration, second and predetermineeing concentration and first air supply, the concrete concentration of second air supply that describe above can be according to the demand of experiment in practical application and decide, first air supply subassembly and the concrete structure of second air supply subassembly the utility model discloses do not restrict yet, as long as first air supply subassembly and second air supply subassembly can provide the required first air supply of experiment and second air supply can.

The second air source component in the embodiment comprises a compressor 4, a filter 5, a cold dryer 6, a suction dryer 7 and an air source triple piece 8 which are sequentially communicated, and the downstream of the air source triple piece 8 is connected with an air flow meter 3 and an air inlet pipeline 2.

Referring to fig. 1, in the present embodiment, compressed air is used as a second air source, and the compressed air can be regarded as nitrogen with a concentration of 78%; the compressor 4 can compress air, the filter 5 can filter impurities such as dust in the compressed air, the freeze dryer 6 is a freeze dryer and is used for reducing the temperature of the compressed air and removing moisture in the compressed air, the suction dryer 7 is a compressed air adsorption dryer and is used for further removing moisture in the compressed air, the air source triple piece 8 is an integrally arranged pressure reducing valve, a filter and an oil mist separator and can stabilize the pressure, filter and remove oil of the compressed air, and finally the compressed air is output as a second air source and is output to the downstream gas flow meter 3 and the downstream air inlet pipeline 2.

It is understood that the second gas source can be other gas sources besides compressed air, so as to study the influence of different nitrogen ratios on the yield of the ozone generator 1; the second air supply subassembly also can constitute by other parts, and it is specific can be according to required step and the operation of preparing of second air supply in the practical application and decide, the utility model discloses do not injecing this, as long as the second air supply subassembly can provide the second air supply for gas flowmeter 3 and the inlet line 2 of low reaches to the influence of nitrogen gas to ozone generator 1 productivity of supply research can.

In this embodiment, a detection component is arranged between the air source triple piece 8 and the gas flow meter 3, and the detection component can at least detect the pressure of the second air source between the two.

Specifically, the detection part is the manometer that sets up in air supply trigeminy piece 8 in this embodiment, and it can be comparatively convenient learn the gas pressure of gas flowmeter 3 upper reaches, make the second air supply flow that gas flowmeter 3 can better control entering air inlet pipe 2. Of course, the detection component can also be other detection devices except the pressure gauge, and it can also detect other parameters except pressure, for example, temperature, etc. to further study the influence of other parameters on the yield of the ozone generator 1, the utility model discloses do not limit to this.

The embodiment further comprises a valve arranged between the gas flow meter 3 and the gas inlet pipeline 2, the gas flow meter 3 can control the opening degree of the valve to control the flow of the second gas source, of course, the gas flow meter 3 can also control the flow of the second gas source in other manners, and the actual application condition of the second gas source assembly can be determined.

The embodiment further comprises an outlet pipeline 9, and the ozone generator 1 can output ozone from the outlet pipeline 9. As shown in fig. 1, the first gas source and the second gas source are mixed in the gas inlet pipeline 2, reacted in the ozone generator 1 to produce ozone, and then discharged through the gas outlet pipeline 9 to provide ozone for the downstream.

In this embodiment, the air inlet pipeline 2 and the air outlet pipeline 9 are made of metal. So set up, air inlet pipeline 2 and air outlet pipeline 9 all have better stability, and corrosion resistance is stronger, can effectively prolong ozone generator experimental apparatus's whole life, indirect reduce cost.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (7)

1. An ozone generator experimental device is characterized in that: the device comprises an ozone generator (1), a first gas source assembly and a second gas source assembly, wherein the first gas source assembly and the second gas source assembly can respectively provide a first gas source and a second gas source for the ozone generator (1) through a gas inlet pipeline (2), the second gas source assembly comprises a gas flow meter (3), and the gas flow meter (3) can control the gas inlet flow of the second gas source; the first gas source is oxygen with a first preset concentration, and the second gas source is nitrogen with a second preset concentration.

2. The ozone generator experimental device of claim 1, wherein: the second air source assembly comprises a compressor (4) and a filter (5), and the second air source is compressed air after being filtered.

3. The ozone generator experimental device of claim 2, wherein: the second air source assembly further comprises a cold dryer (6), a suction dryer (7) and an air source triple piece (8) which are sequentially communicated with the downstream of the compressor (4) and the downstream of the filter (5), and the downstream of the air source triple piece (8) is connected with the air flow meter (3) and the air inlet pipeline (2).

4. The ozone generator experimental device of claim 3, wherein: and a detection component is arranged between the air source triple piece (8) and the gas flowmeter (3), and the detection component can at least detect the pressure of the second air source between the air source triple piece and the gas flowmeter.

5. The ozone generator test device of any one of claims 1 to 4, wherein: the gas flow meter (3) is arranged between the gas flow meter (3) and the air inlet pipeline (2), and the opening degree of the valve can be controlled by the gas flow meter (3) to control the flow of the second gas source.

6. The ozone generator test device of any one of claims 1 to 4, wherein: the ozone generator further comprises an air outlet pipeline (9), and the ozone generator (1) can output ozone from the air outlet pipeline (9).

7. The ozone generator experimental device of claim 6, wherein: the air inlet pipeline (2) and the air outlet pipeline (9) are both made of metal materials.

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