JP2003275513A - Method for manufacturing air filter medium and air filter unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for producing a filter medium, as a filter medium for an air filter for dust removal or gas removal used in a clean room or the like, in which gaseous substances generated from the filter medium are reduced. And reduce the ingress of polluting gases into clean rooms. In addition, the burden on removing the pollutant gas from the chemical filter installed in a clean room or the like is reduced, the life is extended, and the operation and maintenance cost of the filter system is reduced. SOLUTION: An air filter material or an air filter unit intermediate is placed in an atmosphere at a temperature lower than the lowest melting point or decomposition temperature among the materials constituting the material or the intermediate and at a pressure of 0.08 MPa or less. The exposure reduces the amount of gaseous substances generated from the material or the intermediate.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a filter material for an air filter for removing dust contained in the outside air flowing into the clean room or fine dust generated in the clean room in a clean room such as a semiconductor or liquid crystal production facility. Alternatively, a filter material for an air filter, which is preferably used as a chemical filter for removing a gaseous substance contained in the outside air flowing into the clean room or a gaseous substance generated in the clean room, and which hardly generates a gaseous substance. It relates to a manufacturing method. The present invention also relates to a method for manufacturing an air filter unit in which these filters are mounted on a filter frame and the generation of gaseous substances is small.

[0002]

2. Description of the Related Art In a semiconductor or liquid crystal production facility, or in a clean room used in connection with semiconductor or liquid crystal peripheral technology, high cleanliness is required for the air or atmosphere in the production facility or the clean room. However, not only dust and organic gaseous pollutants and inorganic gaseous pollutants are contained in these air and atmosphere,
Since dust, organic gaseous pollutants and inorganic gaseous pollutants are generated from clean room components and workers, a filter system for removing such dust and gaseous pollutants is illustrated in Fig. 1. It is installed to do. The outside air passes through a pre-filter 2 for removing coarse dust of the external conditioner 1, a medium-performance filter 3, an air washer 4, a HEPA filter (high-performance filter) 6 in this order, and then a HEPA or ULPA filter 8 of a circulation system. Passing through, dust in the air is removed. Further, the gaseous pollutants that flow into the clean room are removed by the chemical filter 7 installed in the circulation system as needed. In particular, when a large amount of gaseous pollutants is contained in the outside air, the chemical filter 5 is further installed between the HEPA filter 6 and the medium performance filter 3 of the external conditioner 1.

[0003] The gaseous pollutants include organic gaseous pollutants and inorganic gaseous pollutants. For example, when the organic gaseous pollutants adhere to the surface of a silicon wafer, which is a semiconductor substrate, , The dielectric breakdown voltage of the insulating oxide film formed on the surface of the silicon wafer is lowered, and the particles floating in the air are easily electrostatically adsorbed, which easily causes dielectric breakdown, which adversely affects the manufacturing of semiconductors and liquid crystals. Exert. In order to prevent the adsorption of these organic gaseous pollutants on the wafer surface, the concentration of the organic substances in the clean room atmosphere must be controlled at the lowest possible level. Such control concentration can be obtained as follows. That is, the 1999 version of SIA (Semicond)
uctor Industry Associate
n) According to the roadmap, the organic material control level on the wafer surface in the year 2000 is 6.6 × 10 ¹³ Cat.
It is said to be oms / cm ² . This is 14.4 μg / m ^{2 in} terms of toluene. When the estimated value of the control level in the clean room air is calculated by the following calculation formula 1 from the value of the control level on the wafer surface and the generally known adhesion probability, the total organic substance is 41.7.
The control concentration is μg / m ³ . Calculation formula 1: N = As / (v · t · γ) N; Contaminant concentration in air (control concentration in air) (μg
/ M ³ ) As; Contaminant concentration on wafer surface (control level on wafer surface) (μg / m ² ) v; Clean room air flow rate (0.4 m / sec) t; Wafer exposure time in air (86400 sec) ) Γ: Adhesion probability (adhesion probability of aromatic hydrocarbons 1 × 10
^-5 )

[0004] Examples of such a chemical filter that adsorbs and removes organic gaseous pollutants and inorganic gaseous pollutants include adsorbents such as activated carbon, activated carbon fibers, zeolite, ion exchange resins, and other chemical adsorbents. Is being used,
These adsorbents are used alone, or adsorbents are carried on a base material such as a net-like material or a non-woven fabric. The chemical filter is installed in the circulation system in the filter system and, if necessary, also installed in the external air conditioner.

[0005] However, these gaseous pollutants are not only in the outside air, but also the filter material itself for air filters that removes fine dust,
It has been found that the chemical filter itself, which removes gaseous pollutants, is also generating. Of these, HEPA or ULPA placed downstream of the chemical filter
Filters are frequently used in clean rooms, and the use area of the filter media is very large. Therefore, prevention of gas generated from HEPA or ULPA filters has been a particular problem. Also,
For the medium performance filter for removing fine dust, which is mainly arranged in the external conditioner upstream of the HEPA filter, and the pre-filter arranged further upstream of the medium performance filter, refer to H
Compared to EPA or ULPA filters, the filter media has a smaller area used, and when it is placed upstream of the chemical filter, the gas generated from the prefilter is removed by the chemical filter. It is considered that the direct influence of the generated organic gaseous substances on the clean room is small. However, there are problems such as shortening the life of the chemical filter, and prevention of the generated gas is still an issue. Similarly, the gas generated from the chemical filter itself may be removed by the chemical filter itself.
Depending on the type of generated gas, it may not be removed or may be generated from the support of the chemical filter, and there are problems such as shortening the life of the chemical filter itself or other chemical filters, and the prevention of generated gas is also an issue. It has been said that.

[0006]

DISCLOSURE OF THE INVENTION The present invention is to solve the above-mentioned problems of the prior art, and as a filter material for air filters for dust removal and gas removal used in a clean room, etc. Without sacrificing performance
Moreover, by providing a manufacturing method that can efficiently perform the reduction treatment of gaseous substances in a short time, it is possible to reduce the ingress of pollutant gas into a clean room, etc., and to meet the control concentration for pollutant gas in a clean room etc. It is an issue. Another object of the present invention is to reduce the burden on a chemical filter installed in a clean room or the like for removing pollutant gas to extend the life of the chemical filter and contribute to the reduction of the operation and maintenance cost of the filter system.

[0007]

Means for Solving the Problems According to the invention of claim 1, the means for solving the above-mentioned problems is to use an air filter material having the lowest melting point or decomposition temperature among the materials constituting the air filter material. Lower temperature and 0.08M
According to the method for producing a filter medium for an air filter, the amount of a gaseous substance generated from the air filter material is reduced by exposing the air filter to an atmosphere having a pressure of Pa or less.

[0008] In the invention of claim 2, the atmospheric pressure is 0.03MP.
It is a or less, It is according to the manufacturing method of the filter medium for air filters of Claim 1 characterized by the above-mentioned.

[0009] According to the invention of claim 3, the filter medium for an air filter obtained by the manufacturing method according to claim 1 or 2 is attached to a filter frame to form an air filter unit. It depends on the method.

[0010] In the invention of claim 4, the air filter material is attached to the filter frame to form an air filter unit intermediate body,
By exposing the air filter unit intermediate body to a pressure lower than the lowest melting point or decomposition temperature of the materials forming the air filter unit intermediate body and 0.08 MPa or less, the air filter unit intermediate body According to a method for manufacturing an air filter unit, which is characterized in that the amount of a gaseous substance generated from the air is reduced.

[0011] In the invention of claim 5, the atmospheric pressure is 0.03MP.
According to the method for manufacturing an air filter unit according to claim 4, which is a or less.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of a filter medium for an air filter and a method for manufacturing an air filter unit according to the present invention will be described in detail below.

[0013] A method for producing a filter medium for an air filter according to the present invention comprises a method for producing a material for an air filter at a temperature lower than a lowest melting point or a decomposition temperature of materials constituting the material for an air filter and 0.08 MPa or less. A method for producing a filter medium for an air filter, which comprises exposing to an atmosphere of atmospheric pressure to reduce the amount of a gaseous substance generated from the air filter material.

[0014] The air filter medium is an air filter medium for dust removal and gas removal. Among them, there are air filter media for removing dust, such as air filter media for removing coarse dust, those having medium performance filtering performance, and HEPA or ULPA filters. Has an average particle collection efficiency of 50 by the mass method.
The performance is about 99%. A medium-performance filter has a collection efficiency of 20% to 99% when evaluated by a colorimetric method.
It is of the performance of. The HEPA filter is 0.
When the collection efficiency of 3 μm DOP particles was evaluated by a counting method, it was 9
It has a performance of 9.97% or more. Further, the ULPA filter has a performance of 99.9997% or more when the collection efficiency of 0.15 μm DOP particles is evaluated by a counting method. Further, the filter medium for air filters for gas removal includes organic gaseous pollutants and chemical filters and deodorizing filters that adsorb and remove inorganic gaseous pollutants, such as activated carbon, activated carbon fiber, zeolite, ion exchange. resin,
In addition, it utilizes the adsorption effect of adsorbents such as chemical adsorbents and the like, and the catalytic action of catalysts. These adsorbents and catalysts can be used alone or as a base material such as net-like materials and nonwoven fabrics. It is carried. The chemical filter is installed in the circulation system in the filter system and, if necessary, in the external air conditioner.

[0015] Among the air filter materials, the air filter material for dust removal is a porous material having air permeability, and specific examples thereof include a fiber structure, a membrane structure, and a sponge-like structure. You can Among them, the fiber structure includes woven fabrics, knitted fabrics, non-woven fabrics, papers and the like made from fibers such as synthetic fibers, semi-synthetic fibers, inorganic fibers and natural fibers. Among them, the non-woven fabric is a preferred structure as a material for an air filter because the fibers are three-dimensionally arranged, the ability to retain dust is excellent, and the pressure loss during ventilation is small. The non-woven fabric can be produced by any of the known dry method, wet method, melt spinning method, melt blow method, flash spinning method, and any other fiber web forming method. A method such as a heat fusion method, a hydroentangling method, or a needle punch method can be adopted. For example, in order to obtain a medium-performance or high-performance filter material for an air filter, for example, there is a method of adopting a melt blow method or a flash spinning method, or a method of forming ultrafine fibers or fibrillated fibers into a sheet by a wet method. In addition, for example, easily splittable fibers are formed into a sheet by the above-mentioned known fiber web forming method, and then the fibers in the sheet are thermally divided, or the fibers are mechanically stressed by water flow or needle punching. There is a method of dividing, or a method of chemically melting and extracting the fiber with a chemical such as alkali and dividing the fiber.

[0016] The breathable porous material may be a membrane structure, and as such a membrane structure, a membrane of polyethylene, polypropylene, a membrane of polysulfone, polyether sulfone, polyphenylene sulfone, or the like is used. is there.
Further, such a membrane structure may be formed on the support by using the above-mentioned non-woven fabric structure as a support for reinforcement.

[0017] Of the air filter materials, the air filter material for gas removal includes, for example, (1) an air-permeable sheet-like material made of ion exchange fibers or activated carbon fibers, or (2) particulate ions. Sheet-like material that has accumulated exchange resin, activated carbon, zeolite, and other chemical adsorbents, or (3) particle-shaped ion exchange resin, activated carbon, zeolite, and other chemical adsorbents, etc., which are bonded together with a heat-fusible resin A sheet-like material, or (4) a support on which a particulate ion exchange resin, activated carbon, zeolite, or other chemical adsorbent is supported, or (5) a support on which a fibrous ion exchange resin or activated carbon is supported. There are things like

[0018] Examples of the sheet (1) include non-woven fabrics, woven fabrics, and porous materials such as filter papers. Among them, non-woven fabrics are preferable because they have high air permeability. As the support (4) for supporting the ion exchange resin or the like, any sheet-like material having air permeability can be used. Examples of such sheet-like material include non-woven fabric, woven fabric, membrane, filter paper, sponge. And the like. Among them, a porous body and the like can be mentioned. Among them, a nonwoven fabric is preferable because it has high air permeability. Further, if the sheet-like material as the support is a polymeric material, it can be preferably used because it has high followability to pleating and the like in filter processing and is excellent in durability.

[0019] The air filter material for dust removal and the air filter material for gas removal are produced in a manufacturing process or the like, and in a solid material constituting the air filter material, organic or inorganic gaseous substances are included. It contains organic and inorganic substances that cause the generation of substances. For example, when the material for the air filter is an organic or inorganic fiber structure, for example, 0.01 to 0.5% by weight of the organic or inorganic oil agent with respect to the mass of the fiber is used when the raw material fibers are made into fiber. Or the use of an adhesive containing a low molecular weight organic substance or inorganic substance before forming a fiber web from the raw material fibers to form a material for an air filter causes the generation of gaseous substances. Will contain organic and inorganic substances.

[0020] As the cause of the generation of the gaseous substance, for example, when the raw material of the material for the air filter is an organic substance, an organic additive is added when the organic substance is synthesized or processed, Since the organic solvent may remain, it may be mentioned that a volatile organic substance is contained. Alternatively, when the organic substance is synthesized or processed, for example, a part of the organic substance is decomposed to generate a volatile organic substance. Further, for example, ultrafine fibers are used as a fiber raw material for a medium-performance filter having a high collection efficiency for fine dust, a HEPA or ULPA filter, and such fibers have a large amount of an additive for ultrafineness,
It tends to contain a large amount of organic decomposition products. Also, when adhesive fibers are used for processing the air filter material, a large amount of organic components having a low melting point are used, and there is a tendency that a large amount of organic decomposition products are included due to heating during bonding. When such a volatile organic substance is contained in the air filter material, when used as an air filter for a clean room, for example, a volatile organic substance as a gaseous substance in the treated air from which dust and the like have been removed. Since substances are included, the control standard value of total organic substances in the atmosphere in the clean room cannot be satisfied.

[0021] In the manufacturing method of the present invention, the air filter material is used at a temperature lower than the lowest melting point or decomposition temperature of the solid materials forming the air filter material and at an atmospheric pressure of 0.08 MPa or less. A filter medium for an air filter, which is exposed to a reduced pressure atmosphere, preferably to a reduced pressure atmosphere of 0.03 MPa or less, and more preferably to a reduced pressure atmosphere of 0.01 MPa or less. Can be obtained. It should be noted that the lowest melting point or a temperature lower than the decomposition temperature of the materials constituting the air filter material means that when the air filter material is composed of several materials, the material has only the melting point. The melting point, if the material has a melting point and a decomposition temperature, the melting point and the decomposition temperature, and if the material only has a decomposition temperature, the Is the lowest temperature.

To expose the air filter material to the atmosphere, the temperature is preferably 0 ° C. or higher. In addition, for example, when there is a problem that the air filter material is deteriorated or contracted by heating, the temperature is preferably not higher than the temperature at which the material is deteriorated or contracted, and more preferably, for example, 20 to 120 ° C. 20-90 degreeC is more preferable. Also, 2
If it is 0 to 60 ° C., there is almost no problem such as deterioration or shrinkage, and therefore it is more preferable. Further, the exposure time required for the reduction treatment is preferably 0.5 minutes to 10 hours, and 5 minutes to
5 hours is more preferred.

[0023] As a specific method of exposing the air filter material to an atmosphere having a temperature lower than the lowest melting point or decomposition temperature of the materials forming the air filter material and an atmospheric pressure of 0.08 MPa or less, Although there is no particular limitation as long as the air filter material can be exposed to the atmosphere, for example, there is a method using a vacuum dryer. Further, for example, a material for an air filter is put in a pressure resistant container together with a support, and the gas in the pressure resistant container is discharged by a vacuum pump through an exhaust pipe attached to the pressure resistant container to maintain the pressure inside the pressure resistant container at a predetermined pressure. After that, there is a method of heating the entire pressure resistant container with a heater attached to the outer wall of the pressure resistant container.

[0024] By exposing to the atmosphere described above, the generation of gaseous substances can be greatly reduced as compared with the case of exposing to an atmosphere in a normal pressure state of about atmospheric pressure that is not in a reduced pressure state. Further, in order to reduce the generation of the gaseous substance to the same level as in the normal pressure state, the temperature in the atmosphere can be made lower than the temperature in the normal pressure state. Explaining this advantageous effect by way of example, for example, under normal pressure conditions, reduction treatment must be performed at a high temperature exceeding 90 ° C., and if it exceeds 90 ° C., the problem of causing deterioration or shrinkage of the air filter material will occur. If there is, in the reduced pressure state by the manufacturing method of the present invention,
Since it may be possible to perform the reduction treatment without exceeding 90 ° C., it is possible to avoid the problem that the air filter material is deteriorated or contracted. In addition, it is possible to prevent the air filter material from being thermally deformed or melted. Further, due to the deformation, it is possible to prevent problems such as an increase in pressure loss to shorten the life of the filter and a decrease in the opening of the filter to deteriorate the filtration performance.

[0025] As described above, in the manufacturing method of the present invention, by exposing the air filter material to the atmosphere, the amount of the total organic substances generated from the air filter material is at least related to the organic gaseous substance. Reduction processing can be performed. As a result, according to the method for producing a filter medium for an air filter of the present invention, preferably, the amount of total organic substances (toluene equivalent weight) generated from the filter medium for an air filter is calculated at 23 ° C. by the generated gas estimation method, and When the amount of the total organic substance generated per unit time of the surface density of the air filter medium of 100 g / m ² is calculated to be 1.0 (pg / m ² · hr) or more and 5 (μg / m ²・
hr) or less. Further, more preferably, the amount of the total organic substance is 1.0 (pg / m ² · hr) or more 2
It can be (μg / m ² · hr) or less. Also,
Compared with the reduction treatment in the normal pressure state, the total amount of organic substances can be reduced to 1.9 times or less when heated at 50 ° C. or higher, for example.

[0026] The areal density of the filter material for an air filter of the present invention is, for example, 50 to 3 when the filter material for an air filter is for dust removal and the constituent material of the filter material for an air filter is organic.
A surface density of 00 g / m ² is preferable, and 100 to 200 g /
m ² is more preferred. Further, the thickness of the filter material for an air filter is preferably 5 to 50 mm, more preferably 10 to 30 mm when processed into a bag shape. In the case of pleating, the thickness is preferably 0.1 to 5 mm, more preferably 0.5 to 3 mm, most preferably 0.8 to 2 mm.

[0027] In the present invention, the organic gaseous pollutants are quantified by a dynamic headspace method, an accelerated test is performed in a heated state, the amount of generated gas is quantified, and then the value is measured by a generated gas estimation method at room temperature. The value converted to the hour value is used. In order to explain the effect of the present invention,
Although organic gaseous pollutants are quantified, the dynamic headspace method is also effective for quantifying inorganic gaseous pollutants.

Next, the dynamic headspace method will be described. FIG. 2 is an explanatory diagram of an evolved gas trap (MSTD-258M manufactured by GL Sciences Inc.) used in this method. First, the material to be measured is cut into a circle having a diameter of 7 cm to prepare a sample 14. The sample 14 is placed on the central gas outlet 13 in the chamber 10. Next, clean helium gas 11 is introduced into the chamber at a flow rate of 120 ml.
At a predetermined temperature (60 ° C
Or heat at 80 ° C.). Helium gas 11 is sample 1
4. When contacting the solid adsorbent 12 (component: 2,6-diphenylene) at a collection rate of 100 ml / min, since the pollutant generated from the sample 14 is mixed into the helium gas when contacting oxide). Then, the substance collected on the solid adsorbent 12 is analyzed by a gas chromatograph mass spectrometer. (Shimadzu Corporation QP-505
(0 is used) The heating temperature is measured under two conditions of 60 ° C. and 80 ° C.

[0029] Next, the evolved gas estimation method is a method of performing an accelerated test of the evolved gas at a high temperature and estimating the result at room temperature using an empirical formula. Explained. Since the amount of gas generated at room temperature of 23 ° C in an actual clean room is extremely small, it is difficult to actually measure it in actual measurement because it requires measurement for a long time. Therefore, the dynamic headspace method described above was used for testing. The conditions at a high temperature of 60 ° C. and 80 ° C. are set, and the results at room temperature of 23 ° C. are estimated from the results of qualitatively and quantitatively measuring the amount of organic substances generated from the sample.
According to Takeda et al. Of Sumika Chemical Analysis Service Co., Ltd., regarding the relationship between the test temperature and the generated gas, the following formula is established as an empirical rule. (Listed in Proceedings of the 17th 1999 Contamination Control Research Conference) ln (M / A · h) =-C1 / T + C2 M; Toluene-equivalent gas amount (μg) A; Measurement sample area (m ² ) H; time required for collection (h) T; test temperature (absolute temperature K) C1 and C2; constant

[0030] In addition, the filter material for an air filter of the present invention may be the same as or different from the above-described filter material for an air filter, and a plurality of layers may be laminated. Further, the above-mentioned filter material for an air filter and another sheet material having air permeability may be laminated. Such air-permeable sheet-like materials include, for example, woven fabrics, knitted fabrics, nets, non-woven fabrics, filter papers, etc., but those which do not generate much gaseous substances are preferable.

The method of manufacturing the air filter unit of the present invention is
A method for manufacturing an air filter unit, comprising mounting the filter material for an air filter obtained by the method for manufacturing a filter material for an air filter of the present invention on a filter frame to form an air filter unit. Alternatively, an air filter material is attached to a filter frame to form an air filter unit intermediate, and the air filter unit intermediate is used at a temperature lower than the lowest melting point or decomposition temperature of the materials constituting the air filter unit intermediate. In addition, the method for producing an air filter unit is characterized in that the amount of a gaseous substance generated from the air filter unit intermediate is reduced by exposing the air filter unit to an atmosphere having an atmospheric pressure of 0.08 MPa or less.

[0032] As a method of mounting the air filter material or the air filter material on the filter frame, for example, a method of cutting the air filter material or the air filter material into a flat plate and then mounting it on the filter frame, or A method of bending many filter materials for air filters or air filter materials into pleats and then mounting them on the filter frame,
Alternatively, there is a method in which a filter material for an air filter or a material for an air filter is molded into a bag shape and attached to a filter frame. In this way, for example, in the case of pleats, the area of the filter medium for air filters can be increased up to about 100 times per frontage area of the unit, and when processed into a bag shape, the area of the filter medium for air filters can be increased up to about 30 times. You can Further, as the frame used for the air filter unit, it is preferable to use a synthetic resin plate that hardly generates a gaseous substance or a metal such as aluminum that hardly generates the gaseous substance.

[0033] In the manufacturing method of the present invention, the air filter material is attached to a filter frame to form an air filter unit intermediate, and the air filter unit intermediate is made of a solid material forming the air filter unit intermediate. At a temperature lower than the lowest melting point or a temperature lower than the decomposition temperature, and exposed to an atmosphere of a reduced pressure of 0.08 MPa or less, preferably an atmosphere of a reduced pressure of 0.03 MPa or less, More preferably, the air filter unit can be obtained by exposing it to a reduced pressure atmosphere having an atmospheric pressure of 0.01 MPa or less. The lowest melting point or the temperature lower than the decomposition temperature of the materials forming the air filter unit intermediate means that when the air filter unit intermediate is composed of several materials, the material has only the melting point. The melting point, if the material has a melting point and a decomposition temperature, the melting point and the decomposition temperature, if the material has only the decomposition temperature, the Refers to the lowest temperature of.

[0034] To expose the air filter unit intermediate body to the atmosphere, the temperature is preferably 0 ° C or higher. Further, for example, when there is a problem that the air filter unit intermediate body is deteriorated or contracted by heating, the temperature is preferably not higher than the temperature at which the intermediate body is deteriorated or contracted, and more preferably 20 to 120 ° C., for example. 20-90 degreeC is more preferable. Further, if the temperature is 20 to 60 ° C., there is almost no problem such as deterioration and shrinkage, and therefore it is more preferable. The exposure time required for the reduction treatment is preferably 0.5 minutes to 10 hours, more preferably 5 minutes to 5 hours.

[0035] By exposing to the atmosphere, it is possible to greatly reduce the generation of the gaseous substance, as compared with the case of exposing to the atmosphere in the atmospheric pressure state where the pressure is not reduced. Further, in order to reduce the generation of the gaseous substance to the same level as in the normal pressure state, the temperature in the atmosphere can be made lower than the temperature in the normal pressure state. This advantageous effect will be described by way of example. For example, under normal pressure conditions, reduction treatment must be performed at a high temperature exceeding 90 ° C., and if it exceeds 90 ° C., the filter frame of the air filter unit intermediate body may deteriorate. When there is a problem of thermal deformation, melting, deterioration or shrinkage of the air filter material, it is possible to carry out reduction treatment without exceeding 90 ° C. in the reduced pressure state by the manufacturing method of the present invention. Therefore, the filter frame of the intermediate body of the air filter unit may be deteriorated,
It is possible to prevent thermal deformation and melting. Further, it is possible to avoid the problem that the air filter material attached to the intermediate body of the air filter unit is deteriorated or contracted. In addition, it is possible to prevent the air filter material from being thermally deformed or melted. Further, due to the deformation of the pleat shape or the like, it is possible to prevent problems such as an increase in pressure loss to shorten the life of the filter and a decrease in the opening of the filter to deteriorate the filtration performance.

[0036] A specific method of exposing the air filter unit intermediate to an atmosphere having a temperature lower than the lowest melting point or decomposition temperature of the materials forming the air filter unit intermediate and having an atmospheric pressure of 0.08 MPa or less. There is no particular limitation as long as the air filter unit intermediate can be exposed to the atmosphere, but there is, for example, a method using a vacuum dryer. Further, for example, after putting the air filter unit intermediate body in the pressure resistant container, exhausting the gas in the pressure resistant container from the exhaust pipe attached to the pressure resistant container by the vacuum pump, and maintaining the pressure in the pressure resistant container at a predetermined pressure, There is a method of heating the entire pressure resistant container with a heater attached to the outer wall of the pressure resistant container.

[0037] As described above, in the manufacturing method of the present invention, by exposing the air filter unit intermediate to the atmosphere, the amount of the total organic substances generated from the air filter unit intermediate with respect to at least the organic gaseous substance. Can be reduced. As a result, according to the method for manufacturing an air filter unit of the present invention, the filter material for an air filter obtained by the method for manufacturing an air filter medium of the present invention is provided with a suitable use area depending on the required filtering performance for dust. By using it, the amount of total organic substances (toluene equivalent weight) generated from the air filter medium can be reduced.

[0038] The filter medium for an air filter obtained by the method for manufacturing a filter medium for an air filter according to the present invention is, as illustrated in Fig. 1, an outside air flowing into the clean room 9 in a clean room 9 such as a semiconductor or liquid crystal production facility. A HEPA filter (high-performance filter) 6 for removing dust contained therein, a HEPA or ULPA filter 8 installed in a clean room 9, and a chemical filter for removing gaseous pollutants in the preceding stage of the HEPA filter 6 and the outside air. 5 or a medium-performance air filter 3 installed in front of the chemical filter 5 or a pre-filter 2 installed in front of the middle-performance air filter 3 as a filter material for an air filter with less generation of gaseous substances. You can Further, in the air filter unit obtained by the method for manufacturing an air filter unit of the present invention, the filter material for the air filter is HE
Since it is used as a PA or ULPA filter or a medium-performance filter, it is pleated into a zigzag shape to increase the ventilation area and then attached to the filter frame, or processed into a bag shape to increase the ventilation area and then the filter frame. It can be used as a form of an air filter unit attached to the. Further, since it is used as a pre-filter for removing coarse dust, it can be used in the form of an air filter unit mounted in a filter frame in a flat plate shape.

[0039] Hereinafter, examples of the present invention will be described, but these are merely preferred examples for facilitating the understanding of the invention, and the present invention is not limited to the contents of these examples.

(Example 1) From 100% of the heat-adhesive fiber, which is a composite fiber having a fineness of 17 decitex and a fiber length of 51 mm, which comprises a polyester having a melting point of 260 ° C. as a core component and a modified polyester having a melting point of 130 ° C. as a sheath component. After the fibers were opened, a polypropylene melt-blown web was mixed during the formation while being sent by an air stream to form a mixed web by a combination of the melt-blowing method and the air-laying method.
The mixing ratio of this mixed web is 87% by weight of heat-bondable fiber,
The melt-blown fiber was 13% by weight. Next, this mixed web is heat-bonded for 3 minutes in a dryer at 145 ° C. to melt the modified polyester of the sheath component, and fiber-bonded at the fiber intersections of the mixed web to obtain a thickness of 12 m.
m was made into a fiber structure, and subsequently slits were provided 1
The thickness was adjusted to 1 mm by passing it between heating rolls at 45 ° C. Then, it was air-cooled as it was to obtain an air filter material having an areal density of 155 g / m ² and a thickness of 1 mm. Next, the material for an air filter is put into a vacuum dryer that has been heated to 80 ° C. in advance, and the internal pressure of the vacuum dryer is set to 0.001 MPa, so that the air is depressurized to an atmosphere of 0.001 MPa at 80 ° C. By exposing for 10 minutes, a filter material for an air filter having an areal density of 155 g / m ² and a thickness of 1 mm, in which generation of a gaseous substance was reduced, was produced. The amount of total organic substances (toluene equivalent weight) generated from this filter medium for air filters is calculated at 23 ° C. by the generated gas estimation method, and then generated from the surface density of the filter medium for air filters of 100 g / m ² . When the amount of the total organic substances in a unit time is calculated, it is 0.06.
It was 5 (μg / m ² · hr). Next, pleats were folded using this filter material for air filters of 15 m ² , and the outer dimensions were 610 cm × 610 cm and the depth was 290 c.
The air filter unit was manufactured by mounting it on an aluminum filter frame of m. This air filter unit is
According to the test method according to HRAE 52.1-1992, the average particle collection efficiency by the colorimetric method is 83% under the test condition of the wind speed of 56 m ³ / min, which satisfies the performance as the medium performance filter. It was suitable as a medium-performance filter to be attached to the external conditioner of the filter system for clean rooms.

[0041] Next, the effect of using the air filter unit as the medium-performance filter obtained in Example 1 in a clean room will be described. For example, if the air filter unit is installed in an external air conditioner having a chemical filter and the wind velocity passing through the front of the unit at that time is set to 2.5 m / sec, the amount of total organic substances generated from the filter material for the air filter is set. When the (toluene equivalent weight) is calculated at 23 ° C. by the generated gas estimation method, the amount of the total organic substance generated per unit area of the front area of the air filter unit is 0.065 μg / m ² ·
hr × (155 g / m ² ÷ 100 g / m ² ) × 15 m ²
÷ (0.61m × 0.61m) ÷ 2.5m / sec =
4.5 × ^{10 -4} μg / ^{m 3,} and the fully satisfactory to 41.7μg / ^{m 3} of the management reference value described above. Further, when the air filter unit according to the first embodiment is installed in front of the chemical filter, the organic substances generated from the filter material for the air filter are removed by the chemical filter, so that the pollutant concentration in the air in the clean room is Although it is substantially 0 μg / m ³ , the amount of gas generated from the filter material for an air filter according to Example 1 is extremely small, and the load on the chemical filter can be significantly reduced, and the life of the chemical filter can be greatly extended. .

(Examples 2 to 6) In Example 1, instead of exposing the material for an air filter to a reduced pressure atmosphere of 80 ° C. and a pressure of 0.001 MPa for 10 minutes, in Example 2, 0 ° C. at 0 ° C. 0.001 MPa, and in Example 3, at 80 ° C.
01 MPa, 0.01 MPa at 50 ° C. in Example 4, 0.05 MPa at 80 ° C. in Example 5, and 50 MPa in Example 6.
In the same manner as in Example 1 except that the substrate was exposed to a reduced pressure atmosphere of 0.05 MPa at 0 ° C. for 10 minutes.
An areal density of 155 g / m ² with reduced generation of gaseous substances,
A filter material for an air filter having a thickness of 1 mm was produced. The amount of total organic substances (toluene equivalent weight) generated from this air filter medium was calculated at 23 ° C. by the generated gas estimation method, and then the surface density of the air filter medium was 100 g / m 2.
^When the amount of the total organic substance generated per ² per unit time is calculated, it is 0.58 (μg / m 2 in Example 2).
² · hr), and in Example 3, 0.97 (μg / m ² · h)
r), 1.8 (μg / m ² · hr) in Example 4, 1.9 (μg / m ² · hr) in Example 5, 3.0 (μg / m ² · hr) in Example 6 Therefore, each was suitable as a filter material for an air filter of a medium performance filter to be attached to an external conditioner of a filter system for a clean room.

(Comparative Example 1) [0043] A filter material for an air filter was produced in the same manner as in Example 1 except that the material for the air filter was not subjected to the reduction treatment. When the amount of total organic substances (toluene equivalent weight) generated from the filter material for an air filter was calculated in the same manner as in Example 1, it was 8.1 (μg / m ² · h).
r), which is not suitable as a filter material for an air filter of a medium-performance filter attached to an external conditioner of a filter system for a clean room, because a large amount of organic gaseous substances are generated.

(Comparative Examples 2-3) In Example 1, in the air filter
Pressure reducing material at 80 ° C and a pressure of 0.001 MPa.
In Comparative Example 2, instead of being exposed to the normal atmosphere for 10 minutes
0.1 MPa at 100 ° C., 0.1 at 50 ° C. in Comparative Example 3
Exposed for 10 minutes in an atmosphere of atmospheric pressure of MPa.
In the same manner as in Example 1 except that the generation of gaseous substances was
Reduced areal density of 155 g / m^Two, 1mm thick airfoil
A filter material for filters was produced. From this air filter media
Generated amount of total organic substances (toluene equivalent weight)
Calculation at 23 ° C by
Area density of filter media for filters 100 g / m^TwoOccurs from around
Calculate the amount of the total organic substance per unit time
And in Comparative Example 2, 3.1 (μg / m^Two・ Hr), comparative example
3 was 5.7 (μg / m ^Two・ Hr),
Installed in the outside room of the lean room filter system
It can be used as a filter material for air filters of medium performance filters.
Although it was possible to obtain the above-mentioned filter materials for air filters of Comparative Examples 2 to 3,
The amount of the total organic substances is the filter material for the air filter of Examples 1 to 6.
Was larger than the amount of the total organic substance.

(Example 7) Similar to Example 1, the areal density 1
A material for an air filter having a thickness of 55 g / m ² and a thickness of 1 mm was used. Next, this air filter material of 15 m ² was pleated and mounted on an aluminum filter frame having an outer dimension of 610 cm × 610 cm and a depth of 290 cm to obtain an air filter unit intermediate. Next, this air filter unit intermediate is placed in a vacuum dryer that has been heated to 50 ° C. in advance, and the internal pressure of the vacuum dryer is set to 0.05 MPa.
By setting the above, an air filter unit was produced in which the generation of a gaseous substance was reduced by exposing it to a reduced pressure atmosphere of 50 MPa and an atmospheric pressure of 0.05 MPa for 10 minutes. The amount of total organic substances (toluene equivalent weight) generated from the filter material for the air filter attached to this air filter unit is calculated at 23 ° C. by the generated gas estimation method, and then the unit time generated from the air filter unit is calculated. The calculated amount of the total organic substance in Example 2 was 70.5 (μg / hr). Further, the pleated shape of the filter material for the air filter was not changed and the pressure loss of the unit was not changed by the reduction treatment of the gaseous substance. Further, according to the test method according to ASHRAE 52.1-1992, this air filter unit has a particle collection average efficiency of 83% by a colorimetric method under a test condition of a wind speed of 56 m ³ / min,
It satisfied the performance as a medium-performance filter, and was suitable as a medium-performance filter to be attached to the external conditioner of the filter system for a clean room.

(Comparative Example 4) An air filter unit was produced in the same manner as in Example 7 except that the reduction treatment was not performed on the air filter unit intermediate body. The amount of total organic substances (toluene equivalent weight) generated from the filter material for the air filter attached to this air filter unit is calculated at 23 ° C. by the generated gas estimation method, and then the unit time generated from the air filter unit is calculated. When the amount of the total organic substance in was calculated to be 187.5 (μg / hr),
It was not suitable as a medium-performance filter to be attached to the external conditioner of a clean room filter system because it generated a lot of organic gaseous substances.

(Comparative Example 5) In Example 7, instead of exposing the air filter unit intermediate body to a reduced pressure atmosphere of 50 MPa at an atmospheric pressure of 0.05 MPa for 10 minutes, Comparative Example 5 at 100 ° C. 0. An air filter unit with reduced generation of gaseous substances was produced in the same manner as in Example 7, except that the air filter unit was exposed to an atmospheric pressure atmosphere of 1 MPa for 10 minutes. The amount of total organic substances (toluene equivalent weight) generated from the filter material for the air filter attached to this air filter unit is calculated at 23 ° C. by the generated gas estimation method, and then the unit time generated from the air filter unit is calculated. When the amount of the total organic substance in
(Μg / hr). However, due to the reduction treatment of the gaseous substances, the pleat shape of the filter material for the air filter was disturbed, and the pressure loss as a unit increased. Therefore, it was unsuitable as a medium-performance filter to be attached to the external conditioner of the filter system for clean rooms.

The results of Examples 1 to 7 and Comparative Examples 1 to 5 are shown in Table 1 below.

[Table 1]

[0049] As described above, in Examples 1 to 6, the filter medium for an air filter produced by the reduction treatment in the reduced pressure atmosphere according to the present invention was compared with Comparative Example 1 in which the reduction treatment by the reduced pressure and the heating was not performed. Then, the total amount of organic substances generated (toluene equivalent weight) is 2.7 to 1/125.
It was extremely small and was suitable as a filter medium for air filters of medium performance filters. Further, even when compared with Comparative Examples 2 and 3 in which the reduction treatment under reduced pressure was not performed, the amount of total organic substances generated (toluene-equivalent weight) was from 1/48 to 1.9.
It is extremely small, one-third. Further, in Example 7, the air filter unit produced by the reduction treatment in the reduced-pressure atmosphere according to the present invention was compared with Comparative Example 4 in which the reduction treatment by the reduced pressure and the heating was not performed, so that the total amount of organic substances generated was reduced. The amount (toluene-equivalent weight) was extremely low at 2.7 times, which was suitable as a medium-performance filter. In addition, the normal pressure state was set instead of the reduced pressure state, and
In Comparative Example 5 in which the heating treatment was performed at a higher temperature than in Example 7, the pleated shape of the filter medium for the air filter was disturbed and the pressure loss as the unit was increased, so that the medium-performance filter was used. Was unsuitable as

[0050]

EFFECTS OF THE INVENTION By the method of manufacturing a filter medium for an air filter and the method of manufacturing an air filter unit according to the present invention,
Provided is a manufacturing method for a filter medium for an air filter or an air filter unit used in a clean room or the like, which can efficiently perform a reduction treatment of a gaseous substance in a short time without impairing the performance of the filter medium for an air filter. can do. Further, the filter medium for the air filter and the air filter unit according to the manufacturing method of the present invention can reduce the invasion of the pollutant gas into the clean room or the like, and can satisfy the control concentration of the pollutant gas in the clean room or the like. In addition, it is possible to reduce the burden on the chemical filter installed in a clean room or the like regarding the removal of pollutant gas, extend the life, and contribute to the reduction of the operation and maintenance cost of the filter system.

[Brief description of drawings]

[Figure 1] Filter system for clean rooms

FIG. 2 is an explanatory diagram of a generated gas collector used in the dynamic headspace method.

[Explanation of symbols]

1 External conditioner 2 pre-filter 3 Medium performance filter 4 Air washers 5 Chemical filter 6 HEPA filter 7 Chemical filter 8 HEPA or ULPA filter 9 clean room 10 chambers 11 Helium gas 12 Solid adsorbent 13 Gas outlet 14 samples

Claims (5)

[Claims] 1. An air filter material is exposed to an atmosphere having a pressure lower than or equal to 0.08 MPa at a temperature lower than the lowest melting point or decomposition temperature of the materials forming the air filter material, A method of manufacturing a filter medium for an air filter, which comprises reducing the amount of a gaseous substance generated from a material for an air filter. 2. The method for producing a filter medium for an air filter according to claim 1, wherein the atmospheric pressure is 0.03 MPa or less. 3. A method for manufacturing an air filter unit, comprising mounting the filter material for an air filter obtained by the method according to claim 1 or 2 on a filter frame to form an air filter unit. 4. An air filter material is attached to a filter frame to form an air filter unit intermediate body, and the air filter unit intermediate body has the lowest melting point or decomposition temperature among the materials constituting the air filter unit intermediate body. A method for manufacturing an air filter unit, which comprises subjecting the air filter unit intermediate to a reduction treatment by exposing it to an atmosphere having a lower temperature and an atmospheric pressure of 0.08 MPa or less. 5. The method for manufacturing an air filter unit according to claim 4, wherein the atmospheric pressure is 0.03 MPa or less.