JP3350402B2 - Dry cleaning equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dry cleaning apparatus for washing a laundry while using a petroleum solvent as a dry cleaning liquid and adding ozone gas supplied from an ozone gas generator to the petroleum solvent. is there.

[0002]

2. Description of the Related Art In a dry cleaning apparatus using a petroleum-based solvent as a dry-cleaning liquid, there is a danger of ignition or explosion due to the use of a petroleum-based solvent. A method is employed in which air in the gas phase of the washing tub is replaced with a nonflammable gas such as nitrogen or argon.

In a dry cleaning apparatus using a petroleum-based solvent, the contaminants and odor components of the articles to be washed are dissolved in the solvent during the washing operation, so that these contaminants and odor components in the solvent are removed. In order to keep the petroleum-based solvent in a clean state, ozone gas supplied from an ozone gas generator is added to the solvent, and the action of the ozone gas oxidizes, decomposes and aggregates contaminants and odorous components in the solvent, and filters and adsorbs. A method of removing contaminants and odor components that have been oxidized, decomposed, or aggregated with a material has been adopted.

[0004]

The air in the gas phase of the washing tub is replaced with a nonflammable gas such as nitrogen or argon in order to prevent the solvent from igniting or exploding in the conventional dry cleaning apparatus using a petroleum solvent. The method of adding ozone gas to the solvent in order to keep the petroleum-based solvent in a clean state is both an independent inert gas supply device and an ozone gas supply device. There was a problem that. In addition, since high-purity non-combustible gas such as nitrogen or argon is supplied, the price becomes high, the running cost of the dry cleaning device becomes expensive, and non-combustible gas with oxygen substantially 0% is supplied. Therefore, there was a danger that the working environment would become oxygen-deficient.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and it is possible to keep a petroleum-based solvent in a clean state and clean the laundry to be washed, and to reduce the cost of an apparatus capable of preventing ignition and explosion of the petroleum-based solvent. It is another object of the present invention to provide a dry cleaning apparatus which has a low running cost.

[0006]

According to one aspect of the present invention, there is provided a dry cleaning apparatus using a petroleum-based solvent as a dry cleaning liquid from a discharge side of a washing tub to a circulation pump. An ozone addition unit is provided at an appropriate position in the liquid circulation system, an ozone generator is provided, and an ozone gas supplied from the ozone generator is added to the dry cleaning liquid via the ozone addition unit. The generator is a device that generates ozone gas using the oxygen-enriched air generated by the oxygen-enricher as a raw material gas, and is discharged from the oxygen-enricher when the oxygen-enriched air is generated by the oxygen-enricher. Nitrogen-enriched air is supplied to the gas phase of the dry cleaning liquid circulation system between the discharge side of the washing tub and the circulation pump and / or the gas phase of the washing tub. Characterized in that it enter.

[0007] The invention described in claim 2 is the first invention.
In the dry cleaning device described in the above, the oxygen enricher intermittently sends the compressed air supplied from the compressor to the adsorption tank, and repeatedly pressurizes and depressurizes the adsorbent in the adsorption tank, thereby intermittently enriching the oxygen. An oxygen enrichment device that generates air and intermittently discharges nitrogen-enriched air, and circulates dry-cleaning liquid from the washing tub discharge side to a circulation pump using the nitrogen-enriched air from the oxygen-enrichment device. It is introduced into the gas phase of the system and / or the gas phase of the washing tub.

[0008]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing a configuration of a dry cleaning apparatus using a petroleum-based solvent of the present invention. This dry cleaning device is a dry cleaning machine 1,
It comprises a heat exchanger 9, an ozone generator 10, a control means 17, and the like. The dry cleaning machine 1 includes a solvent storage tank 2,
It includes a button trap 3, a pre-filter 4, a circulation pump 5, a cartridge filter tank 6, a carbon tank 7, a washing tub 8, and the like. Further, the ozone generator 10 includes an oxygen enricher 15 having a configuration described in detail later.

The button trap 3 is for removing large foreign matters such as buttons contained in the solvent. An air diffuser 11 is provided inside the button trap 3, and ozone gas is guided from the ozone generator 10 to the air diffuser 11 by a pipe R3. )). The nitrogen-enriched air discharged from the oxygen enricher 15 is supplied to the gas phase of the washing tub 8 and / or the gas phase of the solvent storage tank 2 through the buffer tank 16. .

FIG. 2 is a diagram showing the configuration of the oxygen enricher 15 installed inside the ozone generator 10. As shown, the oxygen enricher 15 includes a compressor 15-1, a filter 15-2, valves 15-3 to 15-6, and an adsorption tank 15-.
7, adsorption tank 15-8 and oxygen-oxygen buffer tank 15-
9 is provided.

From the compressor 15-1 to the filter 15-
The compressed air supplied through the suction tank 15 is opened and closed by alternately opening and closing the valve 15-3 and the valve 15-5.
7 and the adsorption tank 15-8, and alternately open and close the valve 15-4 and the valve 15-6 (the valve 15-
When valve 3 is open, valve 15-4 is closed and valve 1 is closed.
When the valve 5-5 is closed, the valve 15-6 is opened). An adsorbent for adsorbing nitrogen in the air is contained in the adsorption tanks 15-7 and 15-8, and a valve 15-3 is provided.
To 15-6 as described above, the adsorbent is repeatedly pressurized and depressurized, and the adsorbent 15-7 and the adsorber 1
In 5-8, the adsorption of nitrogen and the generation of oxygen-enriched air are performed alternately.

The oxygen-enriched air alternately generated in the adsorption tanks 15-7 and 15-8 is supplied to the oxygen buffer tank 15-.
The ozone gas is supplied to an ozonizer discharge cell (not shown) that generates ozone by the discharge of the ozone gas generator 10 to generate ozone gas. The generated ozone gas is supplied to the air diffuser 11. Also, the valve 15
-4 and the valve 15-6 are alternately opened, so that the adsorption tank 15 is opened.
The nitrogen-enriched air alternately discharged from −7 and the adsorption tank 15-8 is supplied to the gas phase of the washing tub 8 and / or the gas phase of the solvent storage tank 2 through the buffer tank 16.

The oxygen-enriched air generated in the adsorption tanks 15-7 and 15-8 has an oxygen (O ₂ ) concentration of 90%, which is higher than that of ordinary air (20% to 21%). The nitrogen-enriched air discharged from the adsorption tanks 15-7 and 15-8 has an oxygen concentration of 17% to 15%, which is lower than that of ordinary air. By supplying the nitrogen-enriched air having such a low oxygen concentration to the gas phase of the washing tub 8 and / or the gas phase of the solvent storage tank 2, it is possible to prevent ignition and explosion of the petroleum-based solvent. It becomes possible.

The buffer tank 16 is provided with an adsorption tank 15-.
In order to reduce the fluctuation of the nitrogen-enriched air intermittently supplied from the tank 7 and the adsorption tank 15-8, and to supply the gas to the gas phase of the washing tub 8 and / or the gas phase of the solvent storage tank 2, Provided. If the fluctuation of the nitrogen-enriched air does not matter, the buffer tank 16 may not be provided.

In the dry cleaning apparatus having the above-described structure, the dirt component and the odor component in the solvent that has come into contact with the ozone gas react with the ozone, oxidize, decompose, and aggregate, and enter the solvent storage tank 2 from the button trap 3. The solvent sucked up from the solvent storage tank 2 by the circulating pump 5 through the pre-filter 4 is removed from the solvent by the pre-filter 4 and passes through the cartridge filter tank 6 and the carbon tank 7 arranged in order in the circulation path R1. And flows into the washing tub 8. The solvent that has washed the object to be washed in the washing tub 8 is discharged from the washing tub 8 and returns to the solvent storage tank 2 through the button trap 3.

The cartridge filter tank 6 contains a paper filter of a cartridge, and the carbon tank 7 contains activated carbon. The contaminants and odor components in the solvent that have been oxidized, decomposed, and aggregated by reacting with ozone as described above are collected and adsorbed by the paper filter of the cartridge in the cartridge filter tank 6 and the activated carbon in the carbon tank 7. Removed. The solvent thus cleaned is supplied to the washing tub 8 through the circulation path R1. Also, when the washing tub 8 is stopped and when the batch is washed with the solvent stored in the washing tub 8, the washing tub 8 flows from the circulating passage R1 into the circulating passage R2 branched downstream of the carbon tank 7,
The structure directly returns to the solvent storage tank 2 without passing through the washing tub 8. The heat exchanger 9 is a heat exchanger having a function of lowering the temperature of the solvent.

The circulation path R1 is provided with a temperature sensor 13 for detecting the temperature of the solvent and an electric conductivity sensor 12 for measuring the electric conductivity of the solvent just before the branch point of the circulation path R2. The outputs of the temperature sensor 13 and the conductivity sensor 12 are monitored by the control unit 17. When the temperature of the solvent becomes equal to or higher than a predetermined temperature equal to or lower than its flash point temperature, the control means 1
7 issues an alarm or stops the operation of the ozone generator 10. Also, when the conductivity of the solvent becomes equal to or less than a predetermined value, the control means 17 issues an alarm or the ozone generator 1
0 operation is stopped.

Since the flash point of the petroleum solvent used in the dry cleaning device is 38 ° C. or higher, the solvent temperature during washing is a predetermined temperature (for example, 30 ° C.) below this flash point temperature.
If the dry cleaning device is operated below, ignition and explosion can be prevented in combination with the effect of the introduction of the nitrogen-enriched air. Therefore, if the control means 17 issues an alarm when the temperature of the solvent reaches 30 ° C., and stops the operation of the ozone generator 10, measures against the dry cleaning device are also encouraged, and ignition can be prevented.

Further, there is an experimental example in which if the electric conductivity is 0.0001 μs / cm or more, the petroleum-based solvent does not generate dangerous charging such as ignition or explosion. If the degree becomes equal to or less than a predetermined value of 0.0001 μs / cm or less, an alarm is issued, and if the operation of the ozone generator 10 is stopped, measures for the dry cleaning device are also encouraged, and static electricity easily generated during washing is promoted. Can prevent ignition and explosion. In the above example, the temperature sensor 13 and the conductivity sensor 12 are provided in the solvent circulation path R1 between the washing tub 8 and the carbon tank 7. However, if the position is suitable for solvent temperature detection and conductivity detection, the circulation path R1 Any position may be provided.

As described above, according to this embodiment, the nitrogen-enriched air discharged from the adsorption tank 15-7 and the adsorption tank 15-8 of the oxygen enricher 15 to the atmosphere is washed. Since the gas is supplied to the gas phase of the tank 8 and / or the gas phase of the solvent storage tank 2, the danger of ignition or explosion of the petroleum-based solvent can be suppressed, and the temperature sensor is controlled by the control means 17 as described above. By monitoring the output of the electric conductivity sensor 13 and the electric conductivity sensor 12 and issuing an alarm when the temperature or electric conductivity of the solvent exceeds a predetermined value that may cause a danger of ignition and explosion,
It is possible to completely prevent ignition and explosion of a solvent in a dry cleaning device using a petroleum-based solvent.

The nitrogen-enriched air supplied to the gas-phase portion of the washing tub 8 and / or the gas-phase portion of the solvent storage tank 2 has an oxygen (O ₂ ) concentration of 17% or more even if it is called nitrogen-enriched air. Since the oxygen concentration is 15%, which is lower than the oxygen concentration of normal air (20% to 21%), a high concentration of non-combustible gas such as argon gas or nitrogen gas is supplied to the washing tub 8 and the solvent storage tank 2. Unlike the case, there is no possibility that the surrounding area becomes anoxic or extremely hypoxic, and the danger to the human body is extremely low.

In the case of supplying the nitrogen-enriched air discharged from the oxygen enrichment unit 15, in the case of the solvent storage tank 2, an inlet for the nitrogen-enriched air is provided at a position far from a large opening (for example, a button trap). By supplying the air, the nitrogen-enriched air is effective in spreading to the entire gas phase. Further, since the washing tub 8 is a place where the most cause of inflammation and explosion is generated, supplying nitrogen-enriched air to the gaseous phase portion thereof is effective in suppressing ignition and explosion.

In the above example, the nitrogen-enriched air from the oxygen enricher 15 is supplied to the gas-phase part of the solvent storage tank 2 and the gas-phase part of the washing tub 8, but the present invention is not limited to this. Instead, it is a matter of course that the dry cleaning liquid may be supplied to the gas phase portion of the dry cleaning liquid circulation system between the gas phase portion of the washing tub 8 and the discharge side of the washing tub 8 to the circulation pump.

In the above embodiment, the oxygen enricher 1
5 shows an example in which the ozone generator 10 is built in,
The oxygen-enriching device 15 is installed independently of the ozone generator 10, the oxygen-enriched air generated by the oxygen-enriching device 15 is supplied to the ozone generator 10, and the discharged nitrogen-enriched air is dried by a dry cleaning device. Naturally, it may be configured to supply the gas to the gas phase part of one washing tub 8 and / or the gas phase part of the solvent storage tank.

[0025]

As described above, according to the first aspect of the present invention, the ozone gas supplied from the ozone generator is added to the dry cleaning liquid, which is a petroleum solvent, and at the same time, the oxygen is supplied to the ozone generator. Nitrogen-enriched air discharged from the oxygen-enriching machine that supplies enriched air is introduced into the gas phase of the dry cleaning liquid circulation system and / or the gas phase of the washing tub between the washing tub discharge side and the circulation pump. Therefore, the following excellent effects can be obtained.

(1) By adding ozone to the solvent, the solvent is highly purified, and the sterilizing and bleaching effects of ozone act to wash the laundry much more cleanly than before. The risk of ignition and explosion of the solvent of the dry cleaning device using the method can be greatly reduced.

(2) Compared to the case where a non-flammable gas such as a high-purity argon gas or a nitrogen gas having an oxygen concentration of about 0% is conventionally introduced to prevent the ignition and explosion of the solvent, it is originally in the atmosphere. Since the nitrogen-enriched air released from the oxygen-enriching device is used for preventing and suppressing the ignition and explosion of the solvent, the apparatus price and the running cost are reduced.

(3) When introducing a non-flammable gas such as argon gas or nitrogen gas having a high oxygen concentration of about 0% in order to prevent the solvent from being ignited or exploded, the operator may be deficient in oxygen during the work. Although there is a danger of causing oxygen, here, nitrogen-enriched air containing about 15% of oxygen is introduced from the oxygen enricher, so that the so-called danger of oxygen deficiency can be avoided.

According to the second aspect of the invention, the compressed air supplied from the compressor is intermittently sent to the adsorption tank,
Since the nitrogen-enriched air discharged from the oxygen-enricher configured to repeatedly pressurize and depressurize the adsorbent in the adsorption tank is used for preventing and preventing the ignition and explosion of the solvent, the apparatus price and the running cost are reduced. It will be cheaper.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a dry cleaning device using a petroleum-based solvent of the present invention.

FIG. 2 is a diagram illustrating a configuration example of an oxygen enrichment device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Dry cleaning machine 2 Solvent storage tank 3 Button trap 4 Pre-filter 5 Circulation pump 6 Cartridge filter tank 7 Carbon tank 8 Washing tub 9 Heat exchanger 10 Ozone generator 11 Air diffuser 12 Conductivity sensor 13 Temperature sensor 15 Oxygen enricher 16 buffer tank 17 control means

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-6-304390 (JP, A) JP-A-6-380 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) D06F 43/00 C01B 13/02 C01B 13/11 D06L 1/08

Claims (2)

(57) [Claims] 1. An ozone addition unit is provided at an appropriate position in a dry cleaning liquid circulation system between a washing tub discharge side and a circulation pump of a dry cleaning device using a petroleum-based solvent as a dry cleaning liquid, and an ozone generator is provided. A dry cleaning apparatus for adding ozone gas supplied from the ozone generator to the dry cleaning liquid via the ozone adding section, wherein the ozone generator uses oxygen-enriched air generated by an oxygen enricher as a raw material gas. An apparatus for generating ozone gas as described above, wherein the nitrogen-enriched air discharged from the oxygen-enriched apparatus when the oxygen-enriched apparatus generates oxygen-enriched air is supplied between the washing tub discharge side and the circulation pump. A dry cleaning apparatus, which is introduced into a gas phase of a dry cleaning liquid circulation system and / or a gas phase of a washing tub. 2. The oxygen-enricher intermittently sends compressed air supplied from a compressor to an adsorption tank, and repeatedly pressurizes and depressurizes the adsorbent in the adsorption tank to intermittently generate oxygen-enriched air. An oxygen-enriching device for generating and intermittently discharging nitrogen-enriched air, wherein the nitrogen-enriched air from the oxygen-enriching device is supplied with a dry cleaning liquid circulation system between the washing tub discharge side and a circulation pump. The dry cleaning device according to claim 1, wherein the dry cleaning device is introduced into the gas phase part of the washing tub.