JPS63282106A - Ozone generator - Google Patents

Abstract

PURPOSE:To maintain stability of ozone output of an ozone generator, independent of ambient temp. by equipping a refrigerating system between the ozone generator and an air charging system. CONSTITUTION:The air transferred from a air pump 5 to the ozone generator 1 via a cooling chamber 4 is impressed high voltage with the generator and ozone comes out from a ozone nozzle 3. In this case, the air in the cooling chamber 4 is continually cooled with an evaporator 10 in a cooling system 6 and the temp. of evaporation in the evaporator 10 is constantly adjusted to >=0 deg.C and near 0 deg.C with a constant-pressure expansion expansion valve 9. According to the procedure, the temp. of air supplied to the ozone generator 1 can be kept at constant temp. lower than ambient temp. of the generator. Therefore, not only the efficiency of ozone generation is increased but the ozone output is kept constant and concentration of ozone is easily controlled, independent of ambient temp. of the generator 1.

Description

[Detailed description of the invention] (b) Industrial application fields The present invention relates to an ozone generator.

(b) Prior Art It is generally known that ozone (0,) is effective in sterilizing and deodorizing the air, purifying water, preserving food for a long period of time, and exterminating pests. As a device for generating ozone, for example, as shown in Japanese Patent Publication No. 57-32858, there is an ozone generator equipped with an intake port for raw air and an ozone outlet, and an ozone generator for generating the air. Most are constructed with an air pump that pumps air into the intake port.

No. 1 Problem to be Solved by the Invention However, according to the ozone generator configured as described above, the temperature of the raw air is not controlled in any way, so the temperature of the air varies greatly depending on the environment in which it is used. The amount of ozone generated varies greatly depending on the difference in air temperature.On the other hand, the appropriate concentration of ozone varies depending on the field of use. However, if the concentration is inappropriate, it may cause problems such as adverse effects on the human body, deterioration of organic materials, and corrosion of metals.

The present invention was made in view of the above, and an object of the present invention is to stably ensure the amount of ozone generated in an ozone generator without depending on the environment in which the device is used, particularly the temperature environment.

B) Means for Solving the Problems The present invention provides a cooling device for cooling the air in the air piping between an ozone generator and an air supply device that supplies raw air to the ozone generator. It was established.

(e) Effect The ozone generator of the present invention has the above-described configuration, whereby the air supplied from the air supply device to the ozone generator is cooled to a constant temperature by the evaporator of the refrigeration device, and the air is cooled to a temperature lower than the ambient temperature. It can be sent to the ozone generator in a temperature state, increasing the efficiency of ozone generation, and is less affected by changes in the ambient temperature of the ozone generator (the amount of ozone generated can be quantified, Ozone concentration can be easily controlled by simply controlling the generator to start and stop.

(f) Example Embodiments of the present invention will be described below based on the drawings.

In Fig. 1, 1 is an air intake port 2 and an ozone outlet 3.
This ozone generator is connected to an air pump 5 via a cooling chamber 4 via piping. Reference numeral 6 denotes a refrigeration system configured by sequentially connecting a refrigerant compressor 7, a condenser 8, a constant pressure expansion valve 9, and an evaporator 10 with piping. The evaporator 10 is installed within the cooling chamber 4 and cools the air within the chamber.

FIG. 2 shows an example of the structure inside the cooling chamber 4, in which 10 is the evaporator, 11 is a refrigerant inlet, 12 is a refrigerant outlet, 13 is an air inlet, 14 is an air outlet, and 15 is a drain having a solenoid valve 16. Showing the tube. Here, the cooling chamber 4 is installed inclined from the horizontal plane, and the air population 13 is provided below the air outlet 14.

In the ozone generator configured in this way, a high voltage is applied to the air sent from the air pump 5 to the ozone generator 1 via the cooling chamber 4 in the generator, and ozone ( 03) occurs. Here, the air in the cooling chamber 4 is constantly cooled by the evaporator 10 of the refrigeration device 6, and the evaporation temperature of the evaporator 10 is
The constant pressure expansion valve 9 always adjusts the temperature to below 0°C (and close to 0°C.) This allows the air supplied to the ozone generator 1 to be kept at a temperature lower than the ambient temperature of the generator. It is possible to maintain a constant temperature (e.g. 0 to 10℃), which not only increases the efficiency of ozone generation (
The lower the temperature of the raw material air, in other words, the higher the specific weight, the higher the efficiency of ozone generation.)
The amount of ozone generated can be constantly quantified without being affected by the ambient temperature of the ozone generator 1, and the ozone concentration can be easily managed. For example, operation of the ozone generator 1,
Ozone concentration can be managed simply by controlling the stop time. This makes it easier to manage the ozone concentration of ozone generators used for air purification in hospitals, hotels, restaurants, etc., or for pool water treatment, where ozone concentration must be strictly controlled.

Furthermore, since the cooling chamber 4 is installed at an angle from the horizontal plane and the air population 13 is located below the air outlet 14, water condensed on the evaporator 10 is transferred to the ozone generator 1.
Moreover, this water can be quickly discharged from the drain pipe 15, and ozone generation efficiency can be maintained at a good level.

Furthermore, if the refrigeration device 6 is controlled so that the evaporation temperature is approximately constant at about 0 to 1° C., there will be no frost on the evaporator 10, making it possible to eliminate the need for a defrosting device. Thereby, the temperature of the air supplied to the ozone generator 1 can be further stabilized, and the ozone concentration can be managed with higher precision.

(G) Effects of the Invention As described above, according to the present invention, the air supplied to the ozone generator can be maintained at a constant cooled temperature without being affected by the ambient temperature. This not only improves ozone generation efficiency, but also reduces fluctuations in the amount of ozone generated and facilitates ozone concentration management.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram of an ozone generator showing an embodiment of the present invention, and FIG. 2 is an explanatory diagram of the cooling chamber shown in FIG. 1. l”°・Ozone generator, 4...Cooling room, 5...
Air pump, 6... Refrigeration device, 10... Evaporator.

Claims (2)

[Claims] (1) An ozone generator characterized in that a refrigeration device for cooling the air is provided in the air piping between the ozone generator and an air supply device that supplies air as a raw material to the ozone generator. (2) The ozone generator according to claim 1, wherein the refrigeration device is controlled so that the evaporation temperature is a substantially constant value that does not fall below 0°C.