JPH04327853A - Method for removing fumigation gas facility for fumigation process - Google Patents

Abstract

PURPOSE:To easily, safely and effectively subject a bioclean room to fumigation process using formaldehyde gas. CONSTITUTION:Formaldehyde gas made to foam inside a carburetor-mixer 4 is supplied into a fumigation processing chamber 5 and gas contained in the processing chamber after fumigation process is circulated by a blower 6 and allowed to pass through a removing device 8 for removing formaldehyde. In that case, the concentration of the formaldehyde is detected by a gas detecting device 7. An oxidation absorber for formaldehyde and activated carbon are packed in the removing device 8.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fumigation method and equipment used for fumigation using formaldehyde, and more particularly to a fumigation method in a bio-clean room and equipment used therefor.

0002

2. Description of the Related Art Various types of fumigation gases are used for indoor sterilization using fumigation depending on the purpose. Methyl bromide and ethylene oxide are used for fumigation in museums and art galleries. Formaldehyde is also frequently used as a fumigant gas. Formaldehyde is mainly generated by heating formalin to evaporate it or by bringing methyl alcohol into contact with an oxidation catalyst.

[0003] Fumigation treatment using formaldehyde in a storage warehouse such as a silo involves draining formalin in a tank using pressure such as nitrogen gas, sending the formalin into a device that vaporizes it, and then feeding air into the vaporization device using a blower. This is done using equipment that introduces formaldehyde gas into the fumigation chamber.

On the other hand, bioclean rooms need to be disinfected before use, and for this purpose, fumigation treatment with formaldehyde has conventionally been performed. However, unlike a dedicated fumigation room such as a storage warehouse where fumigation treatment can be continued for a long period of time, in the case of a bio-clean room,
After fumigation treatment, the fumigation gas must be exhausted outdoors immediately. Therefore, in the past, it was common for workers to bring a fumigation gas generator into the bioclean room and start generating fumigation gas as needed. After the fumigation treatment is completed, the untreated fumigation gas is forcibly exhausted to the outside by an exhaust fan.

[0005]

[Problems to be Solved by the Invention] As mentioned above, in the conventional technology for fumigation treatment in bio-clean rooms, the task of starting fumigation gas generation was left to human hands. Therefore, the work is complicated, and even if it is only for a short time,
There was a risk of workers being exposed to toxic gases, and there were concerns about safety. Furthermore, directly exhausting fumigation gases harmful to the human body to the outside causes environmental pollution to the surrounding area, so it is necessary to dilute the fumigation gases to a concentration that is harmless to the human body before exhausting them. In addition, when performing fumigation treatment, a gas generator is simply placed on the floor near the center of the treatment room, and as there is not enough airflow, the concentration of fumigation gas tends to be distributed within the room, and the effectiveness of fumigation treatment may vary depending on the location. There was an inconsistency. That is,
Conventional fumigation treatment in bioclean rooms has had the problems of improving the complexity of the work, ensuring worker safety, eliminating environmental pollution, and ensuring uniform treatment effects.

[0006]

[Means for Solving the Problems] In order to solve the above-mentioned problems, the present invention provides a method in which, after the fumigation treatment is completed, the gas in the treatment chamber is passed through a removal device for removing fumigation gas components. , provides a fumigation gas removal method characterized in that the gas that has passed through the removal device is reintroduced into the fumigation treatment chamber and circulated.

The present invention also provides a fumigation gas supply device that supplies formaldehyde gas obtained by heating and vaporizing formalin into a fumigation treatment chamber, a gas detection device that detects the formaldehyde concentration in the gas in the fumigation treatment chamber, and Provided is a fumigation treatment facility comprising a removal device for removing formaldehyde from gas in a treatment chamber after completion of fumigation treatment.

[0008] Furthermore, the removal device may contain an oxidizing agent and/or an oxidizing agent.
Alternatively, it is preferable that fumigation gas components be removed from the gas in the fumigation treatment chamber using an adsorbent.

[0009]

[Operation] In the fumigation gas removal method of the present invention, after the fumigation treatment is completed, the gas in the fumigation treatment chamber is passed through a removal device for removing fumigation gas components. The gas in the processing chamber after the fumigation process is a component gas with a concentration necessary for the fumigation process, and by being introduced into the removal device little by little, the gas becomes a gas containing almost no fumigation gas components.

[0010] The method for removing fumigation gas components in the removal device may be a commonly used wet or dry method depending on the type of agent used as fumigation gas, but when formaldehyde is used, The following method is preferred. That is, formaldehyde is converted into formic acid and fixed using an oxidizing agent such as potassium permanganate. For example, it is a dry method in which formaldehyde is fixed or oxidized and decomposed using an oxidizing absorbent containing potassium permanganate as a main component. Another method is to physically adsorb formaldehyde using an adsorbent such as activated carbon. If the filling amount is sufficiently large, it is possible to obtain the necessary removal performance using only either the oxidizing agent or the adsorbent. If an oxidizing agent and an adsorbent are used together, it can be almost completely removed. The formaldehyde concentration required for fumigation in a bio-clean room is usually 5000 ppm.
Once the fumigation process is completed, it is harmless to the human body.
Formaldehyde must be removed to a concentration below pm. When removing formaldehyde from highly concentrated formaldehyde gas immediately after fumigation treatment, if an adsorbent is used alone, there is a possibility that the formaldehyde once adsorbed may be desorbed. Therefore, when treating formaldehyde gas with a high concentration, it is desirable to use a removal method that uses both an oxidizing agent and an adsorbent.

Further, in the present invention, after the fumigation process is completed, the gas in the processing chamber passes through the removal device little by little along with the air current, removes the chemical components contained therein, and enters the processing chamber again. A blower used to supply fumigation gas into the processing chamber can be used to generate the air flow. In this way, by repeatedly discharging gas containing high concentrations of drug components and introducing gas containing almost no drug components, the drug concentration in the fumigation chamber is reduced to a level that is harmless to the human body. .

The present invention also provides a series of fumigation treatment equipment, consisting of a fumigation gas supply device, a fumigation gas concentration detection device, and a removal device used in the fumigation gas removal method.

The fumigation gas supply device constituting the fumigation treatment equipment of the present invention supplies formaldehyde gas, which is obtained by heating and vaporizing formalin, into a room in which fumigation treatment is performed. Although fumigation gas can be generated using a conventional method, it is preferable to use the following method. In other words, it consists of a chemical tank containing formalin, an inert gas cylinder for pressurization, a flow meter, a blower, a vaporization mixer that vaporizes formalin and mixes the generated formaldehyde gas with air sent by the blower, and a drain separator. Use the equipment that will be used. While adjusting the flow rate of formalin to a required set amount, the formalin in the chemical solution tank is pressurized with an inert gas such as nitrogen gas and sent to the vaporization mixer. If this vaporization mixer is constructed in such a way that a heating heater is placed outside the vaporization section, formalin can be prevented from becoming highly concentrated and exploding. The air introduced into the vaporization mixer sends formaldehyde gas and the like in the vaporization mixer into the drain separator. Formalin that has not been vaporized is separated and discharged by a drain separator, and formaldehyde gas is supplied to the fumigation chamber. At this time, formaldehyde gas is
Since the air is supplied into the processing chamber along with the airflow from the blower, an airflow is generated within the processing chamber.

On the other hand, fumigation treatment using formaldehyde is particularly effective in an atmosphere with a relative humidity of 80% or more. In the fumigation gas supply device as described above, it is also possible to dilute commercially available formalin and put it in a tank, generate a large amount of water vapor at the same time as formaldehyde, and supply it to adjust the relative humidity in the processing chamber. In this case, in order to vaporize a large amount of water, it is necessary to increase the heater capacity of the vaporization mixer.

[0015] The gas detection device constituting the fumigation treatment equipment of the present invention detects the inside of the fumigation treatment chamber while supplying the fumigation gas and while passing the gas in the fumigation treatment chamber through the removal device to remove formaldehyde. This system monitors the formaldehyde concentration of each device and notifies you when each set concentration has been reached. This gas detection device is installed at a position immediately after the exhaust port of the fumigation chamber and immediately before the removal device. Commercially available formalin usually contains about 10-15% methyl alcohol to keep formaldehyde stable. Therefore, the fumigation gas supplied into the processing chamber by the fumigation gas supply device also contains methyl alcohol gas. Therefore, this gas detection device needs to detect the concentration of formaldehyde in a manner that does not cause malfunctions due to the presence of substances other than formaldehyde. In addition, in order to detect high-concentration gas when fumigation gas is supplied and low-concentration gas when removing formaldehyde, two detection methods are adopted depending on the purpose. That is, a light wave interference method for detecting high concentration formaldehyde and a constant potential electrolysis method for detecting low concentration formaldehyde are used together. While the fumigation gas is being supplied, the formaldehyde concentration is detected using a light wave interference method, and while the gas in the fumigation chamber is passing through a removal device to remove formaldehyde, it is detected using a constant potential electrolysis method.

The removal device constituting the fumigation treatment equipment of the present invention is a device for achieving the above-mentioned fumigation gas removal method, and is preferably filled with an oxidizing absorbent and/or an adsorbent such as activated carbon. There is. After the fumigation process is completed, the gas in the fumigation process chamber enters the removal device, where formaldehyde is almost completely removed, and then enters the fumigation process chamber again for circulation. Although this removal device is operated indoors at room temperature, it is necessary to provide a cooling coil in case the temperature inside the device increases due to heat of reaction and heat of adsorption during operation.

The fumigation treatment equipment of the present invention as described above can also be operated under automatic control by connecting the fumigation gas supply device, gas detection device, removal device, and blower with a motor damper. In this case, the gas detection device is structured to automatically switch to a light wave interference method when fumigating gas is supplied and to a constant potential electrolysis method when the removal device is activated.

[0018]

[Examples] The present invention will be explained in detail with reference to Examples below. Figure 1
This is an embodiment of the fumigation treatment equipment of the present invention.

In this equipment, the fumigation gas supply device includes a gas cylinder 1 containing nitrogen gas, a chemical liquid tank 2 containing formalin, a flow meter 3 having a needle valve 3a, a vaporization mixer 4, a drain separator 5, a blower 6, and dampers 9 and 10, and is connected to a fumigation chamber 15 through a connection valve 16. Nitrogen gas may be supplied from the damper 18 by connecting an existing nitrogen line. When the dampers 9 and 10 and the connection valve 16 are opened, fumigation gas is introduced into the processing chamber 15 through the gas inlet 15a.

The gas detection device 7 is installed via a connection valve 17 immediately after the gas outlet 15b of the fumigation chamber 15. When the connection valve 17 and the dampers 7a and 13 are opened, the gas in the fumigation chamber 15 is caused to pass through the gas detection device 7 by the blower 6, so that the formaldehyde concentration of the gas in the chamber 15 can be detected. This gas detection device 7 is a detector that uses both a light wave interference method to detect high concentration formaldehyde and a constant potential electrolysis method to detect low concentration formaldehyde. Can be switched to crab.

The removal device 8 is installed immediately after the gas detection device 7 via a damper 14, and inside it contains an oxidation absorbent Purelite (trade name) containing potassium permanganate as a main component and activated carbon. It is filled with. Additionally, this removal device is provided with a cooling coil. The removing device 8 is connected to the blower 6 through a damper 12, and when the removing device is in operation, the dampers 11, 12, and 14 are opened while the dampers 9, 10, and 13 are closed. As a result, the gas from which formaldehyde has been removed by the removal device 8 enters the fumigation chamber 15 through the gas introduction port 15a.

The fumigation method using this fumigation equipment will be described below. Open connection valves 16 and 17 and dampers 9, 10, and 13, and turn blower 6
After starting up, the heater of the vaporization mixer 4 is turned on. The gas detection device 7 is of a light wave interference type, and is set and operated to detect the fumigation treatment concentration (for example, 5000 ppm). While adjusting the needle valve 3a of the flowmeter 3 so that the flow rate of formalin reaches a required set amount, formalin in the chemical solution tank 2 is pressurized with nitrogen in the gas cylinder 1 and sent to the vaporization mixer 4. Formalin is vaporized in this vaporization mixer 4 to generate formaldehyde. In this vaporization mixer 4, the heating heater is the vaporization part 4a.
It has an explosion-proof structure with temperature controller 4 installed on the outside.
b is provided. Air is supplied into this vaporization mixer 4 by a blower 6, and formaldehyde gas and the like inside the container are sent into the drain separator 5. In the drain separator 5, unvaporized formalin is separated and discharged, and only the gas enters the fumigation chamber 1 through the gas inlet 15a.
Supplied within 5 days. The introduced fumigation gas generates an air current within the fumigation treatment chamber 15, causing forced convection of the air in the room. During this time, the formaldehyde concentration in the fumigation room gas is monitored by the gas detection device 7. When the gas detection device detects the set concentration, the gas cylinder 1 is closed, the heater of the vaporization mixer 4 is turned off, and the blower 6 is stopped. Thereafter, the dampers 9, 10, and 13 are closed, and fumigation treatment is performed for a certain period of time.

[0023] After the fumigation process is completed, the dampers 11 and 12
, and 14 to start the blower 6. In addition, the detection method of the gas detection device 7 is switched to a constant potential electrolysis method,
Formaldehyde removal completion concentration (e.g. 1 ppm)
Set. Thereby, the gas in the fumigation chamber 15 enters the removal device 8 while its formaldehyde concentration is detected by the gas detection device 7. The gas from which formaldehyde has been removed by the removal device 8 passes through the dampers 12 and 11 and enters the fumigation chamber 15 again through the gas inlet 15a. The gas in the processing chamber 15 is circulated as described above, and when the gas detection device 7 detects the set concentration, the blower 6 is stopped. Finally, dampers 11 and 12,
and close 14. When fumigating another room next time, connection valves 16 and 17 are closed and removed.

The fumigation treatment equipment of this embodiment can also be operated under automatic control by connecting the fumigation gas supply device, gas detection device, removal device, and blower with a motor damper. In this case, the gas detection device is structured to automatically switch to a light wave interference type detector when the fumigation gas is supplied, and to a constant potential electrolysis type detector when the removal device is activated.

Further, an experiment was conducted to examine the performance of the removal device constituting the fumigation treatment equipment of this example as follows. That is, an oxidizing absorbent and activated carbon were filled into a removal device under each condition, formaldehyde gas having a concentration of 5000 ppm was passed through this device, and the outlet concentration was measured. The oxidation absorber is Purelite E2 manufactured by Nihon Kagaku Kogyo Co., Ltd.
As the activated carbon, crushed activated carbon 4GCX manufactured by Tsurumicol was used. Table 1 shows these filling conditions and the results of removal performance. In Table 1, the SV value means the processing air volume per hour relative to the total volume of filler. Moreover, the removal efficiency means the ratio of the value obtained by subtracting the outlet concentration after treatment from the initial concentration (5000 ppm) to the initial concentration.

[0026]

[Table 1] From the results in Table 1, the fumigation gas removal method of the present invention is fully compatible with fumigation treatment using high concentration formaldehyde gas such as in bio-clean rooms by using an oxidizing agent and an adsorbent in combination. I understand that.

[0027]

As explained above, according to the fumigation gas removal method of the present invention, the gas in the processing chamber after the fumigation treatment is passed through the removal device, and the gas is converted into a gas containing almost no chemical components and can be reprocessed. Introduce it indoors and circulate it. As a result, the concentration of the chemical gas in the processing chamber is diluted to a level that is harmless to the human body, so no harmful gas is discharged to the outside, and there is no fear of environmental pollution.

Furthermore, when fumigation treatment is performed using the fumigation treatment equipment of the present invention, the complexity of conventional fumigation treatment work is improved and the safety of workers is also ensured. This effect is
By operating the fumigation treatment equipment of the present invention unmanned by automatic control, it becomes larger.

Furthermore, when fumigation treatment is performed using the fumigation treatment equipment of the present invention, the fumigation gas is supplied into the processing chamber along with the airflow from the blower, so an airflow is also generated within the processing chamber. Fumigation gas is distributed uniformly to every corner, achieving highly reliable fumigation treatment effects.

In addition, when fumigation treatment is performed using the fumigation treatment equipment of the present invention, the relative humidity in the treatment chamber can be adjusted by adjusting the dilution concentration of formalin, so that the fumigation treatment can be carried out in an effective humidity atmosphere. It is also possible to maximize the fumigation effect.

On the other hand, the fumigation treatment equipment of the present invention is one in which a fumigation gas supply device, a fumigation gas concentration detection device, and a fumigation gas removal device are installed centrally, and equipment management is simplified. Therefore, it is possible to reduce costs by connecting multiple bioclean rooms via valves and increasing the frequency of equipment use for efficient use.

[Brief explanation of drawings]

FIG. 1 is a process diagram showing an embodiment of fumigation treatment equipment of the present invention.

[Explanation of symbols]

1 Gas cylinder 2 Chemical tank 3 Flowmeter 4 Vaporization mixer 4a Vaporization part 4b Temperature controller 5 Drain separator 6 Blower 7 Gas detection device 7a Damper 8 Removal device 9-14 Damper 15 Fumigation treatment room 15a Gas inlet 15b Gas exhaust port 16 Connection valve 17 Connection valve 18 Damper 19 Damper

Claims (4)

[Claims] Claim 1: After the fumigation treatment is completed, the gas in the treatment chamber is passed through a removal device for removing fumigation gas components, and the gas that has passed through the removal device is reintroduced into the fumigation treatment chamber and circulated. A fumigation gas removal method characterized by: 2. The fumigation gas removal method according to claim 1, wherein the removal device removes fumigation gas components from the gas in the processing chamber using an oxidizing agent and/or an adsorbent. 3. A fumigation gas supply device that supplies formaldehyde gas obtained by heating and vaporizing formalin into a fumigation treatment chamber, a gas detection device that detects the formaldehyde concentration in the gas in the fumigation treatment chamber, and after the fumigation treatment is completed. The fumigation system consists of a removal device for removing formaldehyde from the gas in the fumigation treatment chamber, and the gas in the treatment chamber after the fumigation treatment passes through the removal device and then enters the fumigation treatment chamber again for circulation. Processing equipment. 4. The fumigation treatment equipment according to claim 3, wherein the removal device removes formaldehyde from the gas in the fumigation treatment chamber using an oxidizing agent and/or an adsorbent.