JP2014023990A - Sheet for dust collection filter, manufacturing method thereof and dust collection filter including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sheet for a dust collection filter composed of woven cloth of mutually fusing both of warp and weft at a crossing point by being used as the warp and the weft, and capable of easily removing once-collected dust-dirt.SOLUTION: The sheet for the dust collection filter includes the woven cloth 1 of fusing the warp 11 and the weft 12 at the crossing point, and in the sheet for the dust collection filter, the warp 11 and the weft 12 are core-sheath type composite fiber whose sheath part has a melting point lower than a core part, and a wire diameter A and a wire diameter B in an unfused part of the respective warp and weft and a thickness C of the woven cloth, satisfy the following formula of C/(A+B)<1.00, and a separation distance a1 and a center distance a2 of the adjacent warp, a separation distance b1 and a center distance b2 of the adjacent weft, satisfy the following formula. (a1×b1)/(a2×b2)>0.60.

Description

  The present invention relates to a dust collection filter sheet, a method for producing the same, and a dust collection filter containing the same.

  The dust collecting filter is a dust in the air or in the solution in a device having a function of circulating the air or the solution such as an air conditioner, an air cleaner, a heat exchanger, a ventilation fan and a vacuum cleaner, and a washing machine. It is used for the purpose of collecting.

  For example, the air or solution circulating in the operating state of the various devices described above contains various kinds of dusts of different types and sizes. When air or a solution is circulated in a state containing such dust, the performance as a device is degraded. In order to prevent or mitigate such a phenomenon, various dust collection filters are used. For example, in an air conditioner, when air containing dust is introduced into a heat exchanger, the dust adheres to the inside of the heat exchanger, the air flow becomes worse, and the heat exchange performance decreases. In order to prevent this, in a general air conditioner, a dust collection filter is provided at the air intake port of the heat exchanger.

  As such a dust collection filter, a filter that has a dust collection filter sheet and collects dust by allowing air or a solution containing dust to pass through the sheet is widely used.

  Specifically, as a sheet for a dust collection filter, for example, a core-sheath type composite fiber having a sheath having a melting point lower than that of the core is used as the warp and the weft. A dust collection filter sheet made of a woven fabric fused at a crossing point has been reported (Patent Document 1). The dust collection filter sheet having such a configuration has an advantage that the yarn does not shift even if it is bent or pulled because the intersection of the warp and the weft is fused.

JP 2011-195993 A

  The present invention is a dust collection filter sheet comprising a woven fabric in which a sheath-core conjugate fiber having a melting point lower than that of a core portion is used as warp and weft, and both are fused together at an intersection, It is an object of the present invention to provide a dust collection filter sheet that can easily remove collected dust.

The inventors of the present invention have made extensive studies to solve the above problems, and have found that the shape of the fusion part of the warp and the weft is important. As the degree of fusion of warps and wefts progresses in this fusion part, the height of the fusion part in the direction orthogonal to the sheet main surface decreases, while the area occupied on the sheet increases. The present inventors made it easier to collect dust once collected by suppressing the height of the fusion part in the direction perpendicular to the sheet main surface and at the same time reducing the area occupied by the fusion part on the sheet. Newly found that can be removed. The present invention has been completed by further various studies based on this new knowledge, and is as follows.
Item 1
A dust collecting filter sheet comprising a woven fabric in which warp and weft are fused at the intersection,
Both the warp and the weft are core-sheath type composite fibers in which the sheath part has a lower melting point than the core part,
The wire diameter A and the wire diameter B in the non-fused part of each of the warp and the weft, and the thickness C of the woven fabric satisfy the following formula:
C / (A + B) <1.00
And,
A dust collection filter sheet, wherein a separation distance a1 and a centerline distance a2 of adjacent warps, and a separation distance b1 and a centerline distance b2 of adjacent wefts satisfy the following expressions:
(A1 × b1) / (a2 × b2)> 0.60
Item 2
Item 2. The dust collection filter sheet according to Item 1, wherein the shape of the opening is rectangular or substantially rectangular.
Item 3
Item 3. The dust collection filter sheet according to Item 1 or 2, further comprising one or more layers containing an inorganic substance on a main surface.
Item 4
The inorganic material is at least one inorganic material selected from the group consisting of stainless steel, monel, titanium, silver, nickel, copper, aluminum, tungsten, nickel chromium alloy, permalloy, AZO, brass, silicon, silica, titanium oxide, and carbon. Item 4. The dust collection filter sheet according to any one of Items 1 to 3.
Item 5
Item 5. The dust collection filter sheet according to any one of Items 1 to 4, wherein the dust collection filter is a dust collection filter mounted on an air conditioner, an air cleaner, a heat exchanger, a ventilation fan, a vacuum cleaner, or a washing machine. .
Item 6
Item 5. A dust collection filter comprising the dust collection filter sheet according to any one of Items 1 to 4.
Item 7
Item 7. The dust collection filter according to Item 6, which is a dust collection filter mounted on an air conditioner, an air purifier, a heat exchanger, a ventilation fan, a vacuum cleaner, or a washing machine.
Item 8
A dust collecting filter sheet comprising a woven fabric in which warp and weft are fused at the intersection,
The warp yarn and the weft yarn are core-sheath type composite fibers in which the sheath part has a lower melting point than the core part,
The wire diameter A and the wire diameter B in the non-fused part of each of the warp and the weft, and the thickness C of the woven fabric satisfy the following formula:
C / (A + B) <1.00
And,
The dust collection filter sheet (a1 × b1) / characterized in that the separation distance a1 and the centerline distance a2 between the adjacent warps and the separation distance b1 and the centerline distance b2 between the adjacent wefts satisfy the following formula: (A2 × b2)> 0.60
A method of manufacturing
A method comprising a step of heat-sealing warp and weft, which are core-sheath type composite fibers having a melting point lower than that of the core, at the crossing point.

  By utilizing the present invention, it is possible to provide a dust collection filter having good dust collection performance and capable of easily removing dust once collected.

It is a schematic diagram (plan view) showing a woven fabric in which a warp and a weft are fused at a crossing point to form a fusion part (for convenience of explanation, only three openings are displayed in the center of the figure). In the vicinity of the left and center openings, a fusion part having a different fusion state from the periphery of the right opening is formed. It is a schematic diagram (plan view) showing a woven fabric in which a fusion part having an appropriate shape is formed by appropriately fusing warp yarns and weft yarns at intersections, and the opening is rectangular. FIG. 5 is a schematic diagram (plan view) showing a woven fabric in which a warp and a weft are excessively fused at a crossing point to form an inappropriately shaped weld and an opening is elliptical (explanation) For the sake of convenience, only the shape of the opening existing in the center of the figure is an ellipse). FIG. 2 is a schematic diagram (cross-sectional view) showing a woven fabric in which a fusion part having an appropriate shape is formed by appropriately fusing warps and wefts at crossing points (the lower figure is in a separate space, respectively) A broken line shows a state in which warp yarns and weft yarns in a non-fused state are superimposed on a dust collection filter sheet of the present invention in a further space so that the cross-sectional center points of the respective yarns overlap each other. ). It is a schematic diagram (cross-sectional view) showing a woven fabric in which warp and weft are not fused at the intersection. It is a schematic diagram (cross-sectional view) showing a woven fabric in which a fusion part having an inappropriate shape is formed by insufficiently fusing warps and wefts at intersections. 2 is an example of an optical microscope observation image of the dust collection filter sheet of the present invention obtained in Example 1. FIG. 2 is an example of an optical microscope observation image of the dust collection filter sheet of the present invention obtained in Example 2. FIG. 4 is an example of an optical microscope observation image of the dust collection filter sheet of the present invention obtained in Example 3. FIG. 2 is an electron micrograph of a cross-sectional portion of a crossing point of warp and weft in the dust collection filter sheet of the present invention obtained in Example 1. FIG. It is an example of the result of having performed the brush process after making starch powder adhere to the sheet | seat for dust collection filters of this invention obtained by the comparative example 1, and investigating the residual degree of starch powder after that.

1. Dust collection filter sheet The dust collection filter sheet of the present invention comprises:
A dust collecting filter sheet comprising a woven fabric in which warp and weft are fused at the intersection,
The warp yarn and the weft yarn are core-sheath type composite fibers in which the sheath part has a lower melting point than the core part,
The wire diameter A and the wire diameter B in the non-fused part of each of the warp and the weft, and the thickness C of the woven fabric satisfy the following formula:
C / (A + B) <1.00
And,
The dust collection filter sheet (a1 × b1) / characterized in that the separation distance a1 and the centerline distance a2 between the adjacent warps and the separation distance b1 and the centerline distance b2 between the adjacent wefts satisfy the following formula: (A2 × b2)> 0.60
It is.

  In the present invention, the dust collection filter is not particularly limited as long as it is a filter used for collecting dust in the air or in a solution, for example, an air conditioner, an air cleaner, a heat exchanger, Examples thereof include a dust collection filter used in a ventilation fan, a vacuum cleaner, a washing machine (lint filter), and the like.

  In the present invention, the dust collection filter sheet means a member having a function of collecting dust in the air or in a solution.

  The dust collection filter sheet of the present invention contains a woven fabric in which warp and weft are fused at the intersection. Although it is not particularly limited as long as the effect of the present invention is exhibited, examples of the woven fabric include plain woven fabrics, twill weave fabrics, satin weave fabric fabrics, and the like. .

In the dust collecting filter sheet of the present invention, the wire diameter A and wire diameter B and the thickness C of the woven fabric satisfy the following formulas at the non-fused portions of the warp and weft yarns.
C / (A + B) <1.00 (1.1.1)
In the present invention, the wire diameter A and the wire diameter B in the non-fused portion of each of the warp and the weft are actually measured values. Specifically, the measurement is performed as follows.

  In the case of denier display, the yarn wire diameter displayed in the catalog is likely to have an error due to the fiber density. In order to avoid such an error, in the present invention, the diameter A and the line B of the warp and the weft are obtained by enlarging and observing to the extent that the mesh unit can be confirmed using an optical microscope. . In the above, as the optical microscope observation, a BX51 optical microscope manufactured by OLYMPUS, or an equivalent product thereof is used. Starting from a magnification at which the basic mesh unit cannot be confirmed, observation is performed by sequentially increasing the magnification, and when the basic mesh unit is determined, the magnification is fixed and the following observation is performed. Ten different points are observed, and the diameters of the warp and the weft are measured based on the observed images. Among these measured values, the average value of 6 points excluding the upper 2 points and the lower 2 points is defined as the wire diameter in the present invention. In the optical microscope observation, the cloth is cut into 5 cm × 5 cm, observed without applying tension, and the wire diameter is measured at the position farthest from the fused portion.

  In the present invention, the thickness C of the woven fabric is specifically measured as follows. Two quartz plates of 3 cm × 3 cm and a thickness of about 0.3 mm are prepared. For each 1 cm square area centered on a corner of a 2 cm × 2 cm area excluding about 5 mm from the edge of each quartz plate (arranged so that the four sides of the area are parallel to the four sides of the quartz plate facing each other) The thickness is measured with a thickness measuring device (DIGIMICRO MF501 + MFC-101 manufactured by Nikon Corporation or equivalent), and this is defined as the thickness in each region. Next, the sample cut into 4 cm × 4 cm is sandwiched between two quartz plates, and the thickness in the same region as above is measured. At this time, tension is not applied to the fabric. In the same measurement region, a value obtained by subtracting the thickness measured without sandwiching the sample from the thickness measured with the sample sandwiched is obtained. Of the nine values thus obtained, an average value of five points excluding the upper two points and the lower two points is obtained as the thickness C of the woven fabric.

The dust collection filter sheet of the present invention preferably satisfies the following formula.
C / (A + B) ≦ 0.95 (1.1.2)
The dust collection filter sheet of the present invention preferably satisfies the following expression in addition to the expression (1.1.1) or (1.1.2).
C / (A + B)> 0.50 (1.2.1)
In addition to the formula (1.1.1) or (1.1.2), the dust collection filter sheet of the present invention more preferably satisfies the following formula.
C / (A + B)> 0.60 (1.2.2)
In general, the more the two yarns are fused at the intersection of the warp and the weft, the lower the height in the direction of the fused portion orthogonal to the sheet main surface, and as a result, C / (A + B) tends to be lower. is there.

  When the height of the fused part in the direction orthogonal to the sheet main surface is lower, the dust collecting filter sheet of the present invention can more easily remove dust once collected.

In the dust collection filter sheet of the present invention, the separation distance a1 and the centerline distance a2 of the adjacent warp yarns, and the separation distance b1 and the centerline distance b2 of the adjacent weft yarns satisfy the following expressions.
(A1 × b1) / (a2 × b2)> 0.60 (2.1.1)
The separation distance a1 between adjacent warps refers to the distance between two adjacent warps as shown in FIG.

  The centerline distance a2 between adjacent warp yarns refers to the distance between the centerlines of two warp yarns adjacent to each other as shown in FIG.

  The separation distance b1 between adjacent wefts refers to the distance between two adjacent wefts as shown in FIG.

  The center line distance b2 between the adjacent wefts means the distance between the center lines of the two adjacent wefts as shown in FIG.

  a1 and b1, and a2 and b2 are measured as follows. The measurement is performed by observing with an optical microscope enlarged to such an extent that the mesh unit can be confirmed. In the above, as the optical microscope observation, a BX51 optical microscope manufactured by OLYMPUS, or an equivalent product thereof is used. Starting from a magnification at which the basic mesh unit cannot be confirmed, observation is performed by sequentially increasing the magnification, and when the basic mesh unit can be determined, observation is performed with the magnification fixed. Arbitrary arbitrary 10 points are observed and measured based on their observation images. Among these measured values, an average value of 6 points excluding the upper 2 points and the lower 2 points is obtained. In the optical microscope observation, the cloth is cut into 5 cm × 5 cm, observed without applying tension, and the distance between the yarns and the distance between the center lines are measured at the position farthest from the fused portion.

  a1 × b1 represents an index of the size of the area of the opening, and a2 × b2 represents a unit area. Therefore, the above equation is an index of the area of the opening per unit area.

  Usually, the larger a1 × b1 is, the larger the area of the opening portion tends to be. In particular, when the shape of the opening is rectangular (FIG. 2), a1 × b1 represents the area of the opening. When the shape of the opening is substantially rectangular, a1 × b1 substantially represents the area of the opening. In the present specification, a substantially rectangular shape is a generally rectangular shape, but is a shape having roundness at four corners, and means a shape that is not circular or elliptical. In the left, the roundness at the four corners is due to the fact that the warp and the weft are fused at the intersection.

  Usually, the more the two yarns are fused at the intersection of the warp and weft yarns, the closer the shape of the opening is to a circle or ellipse, or the circle or ellipse itself (FIG. 3), resulting in per unit area The area ratio of the opening portion tends to be smaller. When the shape of the opening is a circle or an ellipse, the area of the opening is represented by π × a1 × b1 × 1/4. Further, as the shape of the opening becomes closer to a circle or an ellipse, the area of the opening becomes a value closer to a1 × b1 to π × a1 × b1 × 1/4. Therefore, the area of the opening tends to be smaller as the two yarns are further fused at the intersection of the warp and the weft and the shape of the opening is closer to a circle or ellipse from a rectangle (FIG. 1).

The dust collection filter sheet of the present invention preferably satisfies the following formula.
(A1 × b1) / (a2 × b2)> 0.65 (2.1.2)
The dust collection filter sheet of the present invention preferably satisfies the following expression in addition to the expression (2.1.1) or (2.1.2).
(A1 × b1) / (a2 × b2) <0.90 (2.2.1)
In addition to the formula (2.1.1) or (2.1.2), the dust collection filter sheet of the present invention more preferably satisfies the following formula.
(A1 × b1) / (a2 × b2) <0.85 (2.2.2)
When the ratio of the area of the opening portion per unit area is larger, the dust collection filter sheet of the present invention can more easily remove dust once collected. Specifically, when the ratio of the area of the opening portion per unit area is small, for example, when trying to remove dust adhering to the sheet using a brush or the like, the dust tends to flow around to the back side of the sheet However, when the ratio of the area of the opening portion per unit area is larger, such a problem is less likely to occur.

  The warp and weft are core-sheath type composite fibers in which the sheath part has a lower melting point than the core part. Therefore, the woven fabric used in the present invention can be obtained by heat-sealing warp and weft at the intersection. Specifically, the woven fabric in which warp and weft are interlaced is placed at a temperature higher than the melting point of the sheath and lower than the melting point of the core, thereby dissolving only the sheath while leaving the core. be able to. Thereafter, the woven fabric is returned to a temperature lower than the melting point of the sheath, thereby obtaining a woven fabric in which the warp and the weft are fused at the intersection. More specifically, heat fusion can be performed as follows. As a method for heat-sealing, hot air or a heat roll can be used.

  The combination of the sheath and the core is not particularly limited as long as the effect of the present invention is achieved. Examples of the combination of the sheath and the core include a low melting point polyester (melting point 130 ° C.) as the sheath and a polyethylene terephthalate (PET) (melting point 270 ° C.) as the core. ), Polyethylene as the sheath (melting point 110 ° C.), polypropylene as the core (melting point 160 ° C.), polyethylene as the sheath (melting point 110 ° C.), PET as the core (melting point 270 ° C.), and the like.

  The dust collection filter sheet of the present invention is not particularly limited, but the opening ratio is preferably 60 to 90%, more preferably 70 to 85%.

  By comprehensively adjusting the wire diameter of each warp and weft, the ratio of the sheath portion in the core-sheath type composite fiber, the number of meshes (number of meshes within 1 inch), the conditions for fusion of the warp and weft, etc. A dust collection filter sheet can be obtained. The tendency when each of the above various elements is adjusted individually is as follows. When the ratio of the sheath part in the core-sheath composite fiber increases, C / (A + B) after fusion tends to decrease. There is a tendency for the aperture ratio to be increased by reducing the wire diameters of the warp and weft. Increasing the number of meshes tends to reduce the opening area of the unit mesh. Of the fusing conditions, the heat melting time tends to be shortened by increasing the heating temperature. Among the conditions for fusing, increasing the heat melting time tends to change the shape of the opening from a rectangle to an ellipse. When the heat melting time is lengthened, the melting of the sheath portion of the warp yarn and the weft yarn proceeds further, and when viewed from the direction orthogonal to the sheet main surface, the melted sheath portion has each intersection point located at the four corners of the opening. This is because it spreads from the center to the surrounding area.

  The dust collection filter sheet of the present invention may further have one or more layers (inorganic layers) containing an inorganic substance on the main surface. Having an inorganic layer improves at least one of handleability, texture, and fraying resistance.

  In the present invention, the handling property specifically means that wrinkles are not easily generated when the dust collection filter sheet is fixed to a frame made of plastic or metal.

  In the present invention, the texture specifically means design and means that the same metallic luster as that of the metal sheet is exhibited. The texture is evaluated by measuring the gloss using a gloss meter.

  In the present invention, the fraying resistance specifically means that the fiber is less likely to fluff at the end after cutting the sheet, or that the fiber at the end is less likely to peel from the sheet along the cutting direction. Fraying resistance is evaluated as follows. Evaluate whether or not the fiber near the cutting part is peeled off from the sheet when cutting the sheet, or whether or not the eye is displaced by pulling the fiber at the end along the cutting direction in the cutting direction. This is done by evaluating the number of fibers.

  The inorganic substance contained in the inorganic layer may be a non-conductive substance or a conductive substance. Although it does not specifically limit as a nonelectroconductive substance contained in an inorganic substance layer, For example, a silicon | silicone, a silica, a titanium oxide, carbon etc. are mentioned.

  When the inorganic substance contained in the inorganic layer is a conductive substance, conductivity can be imparted to the dust collection filter sheet of the present invention. When the dust collection filter sheet of the present invention has conductivity, it is advantageous in the following points. The dust collection filter sheet of the present invention having conductivity can be charged by passing a gas containing ions or the like, and dust can be electrostatically adsorbed by being charged in this way. Can be easily provided. Furthermore, the dust collection filter sheet of the present invention having electrical conductivity can easily remove the static electricity once applied. By utilizing this, for example, the dust electrostatically adsorbed to the filter as described above can be used. Dust can be easily removed by removing static electricity from the filter.

  The conductive material is not particularly limited, and examples thereof include stainless steel, monel, titanium, silver, nickel, copper, aluminum, tungsten, nickel chromium alloy, permalloy, AZO, and brass. Monel is an alloy made of nickel and copper, preferably an alloy made of 63% or more nickel and about 30% copper. Permalloy is an alloy of nickel, copper, molybdenum and iron. AZO is aluminum zinc oxide.

  In the dust collection filter sheet of the present invention, warps and wefts are appropriately fused so that convex portions with a gentle inclination when viewed from the cross-sectional direction are formed at the intersection of both yarns (FIG. 4). In the lower part of FIG. 4, warp yarns and weft yarns in a non-fused state, which are present in separate spaces, are placed on the dust collection filter sheet of the present invention in a separate space, and the center of the cross section of each yarn. A state where the dots are overlapped so that the points overlap each other is indicated by a broken line.

  On the other hand, when the warp and the weft are not fused, even if the other configurations are the same, a convex portion with a constriction is formed at the intersection when viewed from a certain cross-sectional direction (see FIG. 5). Alternatively, when the warp and weft are not properly fused as described above, even if the other configurations are the same, a convex portion with a steep slope is formed at the crossing point when viewed from a certain cross-sectional direction. (FIG. 6). Because of these differences, when the inorganic layer is formed on the main surface, the continuous layer is more formed when the warp and weft are moderately fused than when not moderately fused. Easy to be. Alternatively, when the warp and the weft are appropriately fused, a continuous layer is more easily maintained in the use environment than when the warp and weft are not properly fused. Therefore, when the warp and weft are moderately fused, it is easier to obtain a more continuous inorganic layer than when the warp and weft are not properly fused, or a more continuous inorganic layer in the use environment. Is easier to maintain. When the inorganic layer is continuous, the dust collection filter sheet of the present invention has at least one characteristic selected from the above handling properties, texture and fraying resistance, and when the inorganic material is a conductive substance. In addition, it is excellent in terms of conductivity.

  The dust collection filter sheet of the present invention may have two or more inorganic layers on the main surface. In this case, for example, a configuration having a stainless steel layer or the like adjacent to the main surface and further having a monel layer adjacent to the stainless steel layer or the like can be given. As described above, the dust collection filter sheet of the present invention having a stainless steel layer and a monel layer has a monel layer in addition to at least one characteristic selected from handling properties, texture and fraying resistance, and conductivity. It has excellent antibacterial properties.

  As another example of the dust collection filter sheet of the present invention having two or more inorganic layers on the main surface, for example, it has a layer containing a highly corrosive metal such as silver or copper adjacent to the main surface. Furthermore, the structure which has the layer containing the metal which has corrosion resistance, such as a titanium layer, a nickel layer, or a Monel layer adjacent to the metal layer is mentioned. Silver, copper, and the like are known to have good conductivity, but are easily oxidized by oxygen in the atmosphere. The dust collecting filter sheet of the present invention having such a structure is protected by these highly corrosive metals in addition to at least one characteristic selected from handleability, texture and fraying resistance, and conductivity. Therefore, it has an excellent characteristic that it can be used for a long time. Although not particularly limited, examples of the combination of a highly corrosive metal layer and a metal layer having corrosion resistance include a silver layer and a titanium layer, a copper layer and a nickel layer, and a copper layer and a monel layer.

  The dust collection filter sheet of the present invention may have an inorganic layer on the surface (back surface) opposite to the main surface in addition to the main surface.

The amount of inorganic material contained in the inorganic layer is not particularly limited as long as the effects of the present invention are achieved, usually a ^{3μg / cm 2 ~30μg / cm 2} . When the amount of the inorganic substance contained in the inorganic layer is 3 μg / cm ² or more, the inorganic substance is also attached to the fine depression near the fusion point between the warp and the weft. Further, preferably in terms of productivity was ^{4μg / cm 2 ~20μg / cm 2} , more preferably ^{5μg / cm 2 ~15μg / cm 2} . In the present invention, the amount of the inorganic substance is determined from a metal spectrum of the same type as the sputter target used when preparing the dust collecting filter sheet, using a fluorescent X-ray spectrometer (RIX1000 manufactured by Rigaku Corporation) or an equivalent product thereof. It is calculated as a total value of the amount of metal per 1 cm ² obtained.

  The method for forming the inorganic layer is not particularly limited, and examples thereof include a vapor deposition method. Although not particularly limited, examples of the vapor deposition method include a sputtering method, a vacuum evaporation method, an ion plating method, and a plasma CVD method. Of these methods, the sputtering method is preferable in that an inorganic layer having superior durability can be obtained.

  Although it does not specifically limit as sputtering method, For example, a direct-current magnetron sputtering method, a high frequency magnetron sputtering method, an ion beam sputtering method etc. are mentioned.

  A method for forming the inorganic layer using a sputtering method is not particularly limited, and examples thereof include a batch method and a roll-to-roll method. Although not particularly limited, the roll-to-roll method is more preferable in terms of higher productivity and lower manufacturing costs.

  When the inorganic layer is formed by a sputtering method, the inorganic material is preferably an inorganic material having a high so-called sputtering rate. Examples of inorganic materials having a high sputtering rate include stainless steel, monel, titanium, silver, nickel, copper, aluminum, tungsten, nickel chromium alloy, permalloy, AZO and brass as conductive materials, and silicon, silica as nonconductive materials. , Titanium oxide, carbon and the like.

2. Dust collection filter The dust collection filter of the present invention has the above 1. It is a dust collection filter containing the sheet | seat for dust collection filters of this invention demonstrated in.

  Although the dust collection filter of this invention is not specifically limited, For example, the structure etc. which have the sheet | seat for dust collection filters of this invention, and the flame | frame which supports and fixes it are mentioned.

  Although it does not specifically limit as a flame | frame, Usually, what consists of resin materials is used. Although it does not specifically limit as a resin material, Usually, polyethylene, a polypropylene, a melamine resin, PET resin, etc. are mentioned.

  The shape and size of the dust collection filter of the present invention are appropriately set according to the application.

3. Method for Producing Dust Collection Filter Sheet The method for producing the dust collection filter sheet of the present invention comprises:
A dust collecting filter sheet comprising a woven fabric in which warp and weft are fused at the intersection,
The warp yarn and the weft yarn are core-sheath type composite fibers in which the sheath part has a lower melting point than the core part,
The wire diameter A and the wire diameter B in the non-fused part of each of the warp and the weft, and the thickness C of the woven fabric satisfy the following formula:
C / (A + B) <1.00
And,
The dust collection filter sheet (a1 × b1) / characterized in that the separation distance a1 and the centerline distance a2 between the adjacent warps and the separation distance b1 and the centerline distance b2 between the adjacent wefts satisfy the following formula: (A2 × b2)> 0.60
A method of manufacturing
(1) A method comprising a step of heat-sealing warp and weft, which are core-sheath composite fibers having a melting point lower than that of the core, at the crossing point.

Moreover, in the method for producing the dust collection filter sheet of the present invention, when the dust collection filter sheet of the present invention further contains an inorganic layer, in addition to the step (1),
(2) A step of disposing one or more layers containing an inorganic substance on the main surface of the sheet obtained in the step (1).

  In the above, details of each step are described in 1. above. As described in.

Hereinafter, the present invention will be described in more detail with reference to examples. However, the present invention is not limited to these examples.

Example 1
A plain woven fabric of multi-fused yarn (core portion: made of PET, sheath portion: made of low melting point polyester, fiber diameter: 88 μm) of weft 48 mesh and warp 37 mesh was used as a base material. Using stainless steel as a target material, a surface of one side of the base material was coated with 5.85 μg / cm ² of stainless steel by a DC magnetron sputtering method to prepare a dust collection filter sheet. Specifically, after the inside of the chamber was evacuated, Ar gas was introduced and the pressure in the chamber was set to 0.2 Pa, and sputtering was performed. The sputtering treatment time and sputtering power were adjusted so that the thickness of the coating layer was approximately 30 nm.

Example 2
A plain woven fabric of weft 75 mesh and warp 65 mesh mono-fused yarn (core: 17 decitex made of PET, sheath: made of low melting polyester, fiber diameter 40 μm) was used as the base material. Others were the same as in Example 1. The amount of stainless steel attached to the substrate was 5.58 μg / cm ² .

Example 3
A plain woven fabric of 90 mesh weft and 80 mesh warp (core: 17 decitex made of PET, sheath: made of low melting polyester, fiber diameter 53 μm) was used as a base material. Others were the same as in Example 1. The amount of stainless steel attached to the substrate was 6.61 μg / cm ² .

Comparative Example 1
A plain weave fabric of 30-mesh non-fused yarn (PET regular yarn) was used as the base material for both the weft and the warp. Others were the same as in Example 1. The amount of stainless steel attached to the substrate was 7.00 μg / cm ² .

Comparative Example 2
A plain weave fabric of 60-mesh non-fused yarn (PET regular yarn) was used as the base material for both the weft and the warp. Others were the same as in Example 1. The amount of stainless steel attached to the substrate was 6.37 μg / cm ² .

Comparative Example 3
A plain weave fabric of 80-mesh non-fused yarn (PET regular yarn) was used as the base material for both the weft and the warp. Others were the same as in Example 1. The amount of stainless steel attached to the substrate was 5.79 μg / cm ² .

Test Results For Examples 1 to 3 and Comparative Examples 1 to 3, the warp yarn diameter A and woven fabric thickness C, adjacent warp separation distance a1 and centerline distance a2, and adjacent weft separation distance b1 Table 1 shows the results of measuring the distance b2 between the center lines and the results of calculating the function C / (A + B) and the function (a1 × b1) / (a2 × b2) based on them. In addition, since the same thing as the warp is used as the weft in the left description, the wire diameter B of the weft is the same as the wire diameter A. In addition, the wire diameter A and wire diameter B of the warp and the weft are not values in a state where the warp and the weft are present alone, but values in a state where the warp and the weft are incorporated in the dust collecting filter sheet.

  In the above, the wire diameter A and wire diameter B of the warp and weft, the separation distance a1 and the centerline distance a2 of the adjacent warp, and the separation distance b1 and the centerline distance b2 of the adjacent weft are the images of optical microscope observation I asked for it. For observation with an optical microscope, a BX51 optical microscope manufactured by OLYMPUS was used, and the observation was performed while enlarging the image so that the unit of the mesh could be confirmed. Specifically, starting from a magnification at which the basic mesh unit could not be confirmed, observation was performed by sequentially increasing the magnification, and when the basic mesh unit could be identified, the magnification was fixed and observed. In the optical microscope observation, the cloth is cut into 5cm x 5cm, observed without applying tension, and the wire diameter, separation distance and center line distance of each yarn are measured at the position farthest from the fused part. did. As an example of an optical microscope observation image, observation photographs (all at the same magnification) of the dust collection filter sheets obtained in Examples 1 to 3 are shown in FIGS.

  In the above, the wire diameter A and wire diameter B of the warp and weft, the separation distance a1 and the centerline distance a2 of the adjacent warp, and the separation distance b1 and the centerline distance b2 of the adjacent weft are as follows. Asked. Arbitrary arbitrary 10 points | pieces were observed and each was measured based on those observation images. Among these measured values, an average value of 6 points excluding the upper 2 points and the lower 2 points was obtained.

  In the above, the thickness C of the woven fabric was measured as follows. Two quartz plates having a size of 3 cm × 3 cm and a thickness of about 0.3 mm were prepared. For each 1 cm square area centered on a corner of a 2 cm × 2 cm area excluding about 5 mm from the edge of each quartz plate (arranged so that the four sides of the area are parallel to the four sides of the quartz plate facing each other) The thickness was measured with a thickness measuring machine (DIGIMICRO MF501 + MFC-101 manufactured by Nikon Corporation), and this was taken as the thickness in each region. Next, the sample cut into 4 cm × 4 cm was sandwiched between two quartz plates, and the thicknesses in the same region as above were measured. At this time, no tension was applied to the fabric. In the same measurement region, values obtained by subtracting the thickness measured without sandwiching the sample from the thickness measured with the sample sandwiched were obtained. Of the nine values thus obtained, an average value of five points excluding the upper two points and the lower two points was obtained as the thickness C of the woven fabric.

  In addition, for the dust collection filter sheet obtained in the example, a state in which the warp and the weft are fused is formed by a focused ion beam at a crossing point, and an electron micrograph of the cross section is observed. Confirmed by As an example, an electron micrograph obtained for the dust collection filter sheet obtained in Example 1 is shown in FIG. At the crossing point, the boundary line between the warp and the weft disappeared, and it was confirmed that both were completely fused.

Furthermore, a test was conducted as to how easily dust once collected could be removed. Specifically, about 0.02 g / cm ^{2 of} starch powder is attached to each dust collecting filter sheet, and then the attached starch powder is removed using a blower, and then a brush (brush size 30 mm width, 30 mm length) Using accessory, sold by Cainz Co., Ltd.), it was observed with an optical microscope after three reciprocating brushes in the direction parallel to one of warp or weft. As an example, the result of testing the dust collecting filter sheet of Comparative Example 1 is shown in FIG. In order to show the three-dimensional positional relationship more clearly, this photograph is an observation image from an angle of about 45 ° with respect to the main surface of the sheet (a downward slope from the right side to the left side of the photograph). At the point where warp yarn and weft yarn cross so that the yarn perpendicular to the direction of travel of the brush is on the front side (for example, the point indicated by the arrow in the figure), potato starch is accumulated and removed depending on the brush. You can see that it is not clear. This is due to the fact that there is a partial area that cannot be accessed by the brush due to the occurrence of a step in the part, and that the step at the intersection is a barrier and particles smaller than the step are difficult to remove. Seem.

  On the other hand, in the dust collection filter sheets of Examples 1 to 3, since there is no large step at the intersection of the warp and the weft, the area where the brush cannot be accessed is narrower or disappears, The amount of potato starch remaining after the treatment is further reduced. The results of this test are also shown in Table 1. In the table, “◯” represents that the degree of starch residue remaining after the brush treatment was low, and “X” represents that the starch residue remained high after the brush treatment.

1 Woven Fabric 11 Warp Thread 111 Warp Thread Center Line 12 Weft Thread 13 Fusion Portion 14 Opening Portion

Claims (8)

A dust collecting filter sheet comprising a woven fabric in which warp and weft are fused at the intersection,
The warp yarn and the weft yarn are core-sheath type composite fibers in which the sheath part has a lower melting point than the core part,
The wire diameter A and the wire diameter B in the non-fused part of each of the warp and the weft, and the thickness C of the woven fabric satisfy the following formula:
C / (A + B) <1.00
And,
A dust collection filter sheet, wherein a separation distance a1 and a centerline distance a2 of adjacent warps, and a separation distance b1 and a centerline distance b2 of adjacent wefts satisfy the following expressions:
(A1 × b1) / (a2 × b2)> 0.60 The dust filter sheet according to claim 1, wherein the shape of the opening is rectangular or substantially rectangular. Furthermore, the sheet | seat for dust collection filters of Claim 1 or 2 which has one or more layers containing an inorganic substance in a main surface. The inorganic material is at least one inorganic material selected from the group consisting of stainless steel, monel, titanium, silver, nickel, copper, aluminum, tungsten, nickel chromium alloy, permalloy, AZO, brass, silicon, silica, titanium oxide, and carbon. The sheet | seat for dust collection filters in any one of Claims 1-3 which is. The dust collection filter according to any one of claims 1 to 4, wherein the dust collection filter is a dust collection filter mounted on an air conditioner, an air cleaner, a heat exchanger, a ventilation fan, a vacuum cleaner, or a washing machine. Sheet. The dust collection filter containing the sheet | seat for dust collection filters in any one of Claims 1-4. The dust collection filter according to claim 6, which is a dust collection filter mounted on an air conditioner, an air purifier, a heat exchanger, a ventilation fan, a vacuum cleaner or a washing machine. A dust collecting filter sheet comprising a woven fabric in which warp and weft are fused at the intersection,
The warp yarn and the weft yarn are core-sheath type composite fibers in which the sheath part has a lower melting point than the core part,
The wire diameter A and the wire diameter B in the non-fused part of each of the warp and the weft, and the thickness C of the woven fabric satisfy the following formula:
C / (A + B) <1.00
And,
The dust collection filter sheet (a1 × b1) / characterized in that the separation distance a1 and the centerline distance a2 between the adjacent warps and the separation distance b1 and the centerline distance b2 between the adjacent wefts satisfy the following formula: (A2 × b2)> 0.60
A method of manufacturing
A method comprising a step of heat-sealing warp and weft, which are core-sheath type composite fibers having a melting point lower than that of the core, at the crossing point.

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