JP2018126721A - filter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a filter in which aggregation (bridge) of powder hardly occurs and a time until a differential pressure rise is caused is long, that is, a filtration life is long.SOLUTION: A filter includes a substrate layer, a filtration layer and a skin layer. Therein, the substrate layer is such a layer that non-woven fabric is wound multiply and is thermally compressed, a void ratio is 0.61 to 0.84, a compression ratio when the load of 0.5 MPa is applied is 0.18 or less, the filtration layer is a layer made by winding a laminated body made by laminating the non-woven fabric in which fibers are oriented in the thickness direction, and net multiply, interlayer in the filtration layer is not adhered, the skin layer is a layer including non-woven fabric, and an average fiber diameter of the non-woven fabric constituting the skin layer is 2 times or more, preferably 2 to 20 times of the average fiber diameter of the non-woven fabric constituting the filtration layer. The fiber constituting non-woven fabric of the substrate layer consists of heat-fusible conjugated fibers including a high melting point component and a low melting point component having a melting point difference of 10°C or more.SELECTED DRAWING: None

Description

  The present invention relates to a filter for filtering a slurry or a gel fluid containing a solid content.

  For filters for filtering slurries and gel-like fluids containing solids, use a multilayer structure to ensure the required filtration accuracy and to increase the usable time and cumulative flow rate (filter life) of the filter. It has been known.

  Patent Document 1 discloses that, in the filtration of viscous fluid, the filtration accuracy changes due to the differential pressure or the problem that the filter life is shortened is solved, and a soft gel-like solid is removed even if a pulse pressure or a high differential pressure occurs. A filter that can be captured is proposed. The invention of Patent Document 1 includes a first main filtration layer having a porosity of 50 to 80% by pressure bonding in the main filtration layer of the filter, and a second main filtration having a porosity of 80% or more that has not been pressure-bonded. The second main filtration nonwoven fabric is configured such that the porosity is 1.2 times or more that of the first main filtration nonwoven fabric.

  Moreover, in order to shorten the drying time after filtration and to reduce the volume of condensed volatilized liquid, it is preferable that the solid content concentration of the fluid passed through the filter is high. However, when the solid content concentration is increased, the interaction between the powder particles that are the solid content is increased and the viscosity is increased, and thus the fluidity of the fluid tends to decrease. In such a fluid, there is a known problem that when the particles of the powder pass through the filter, the powder is agglomerated (bridged) and the apparent particle size increases, thereby clogging the filter. The occurrence of bridging not only shortens the filtration life of the filter but also leads to a decrease in the yield of the product after filtration. Therefore, a filter that can suppress the occurrence of bridging has been studied.

  Patent document 2 pays attention to the filtration layer in the multilayer filter, and densifies the fiber density in the thickness direction of the nonwoven fabric constituting the filtration layer, that is, an appropriate gap between the nonwoven fabric layers laminated in the filtration layer. Has been proposed to disperse the powder contained in the fluid and suppress the formation of bridges. The invention of Patent Document 2 intends to provide a filter that suppresses the occurrence of bridges and is excellent in filtration accuracy by also controlling the pore diameter of other layers by a specific configuration.

JP 2010-137121 A JP 2015-97979 A

  However, there is a need for a filter that can filter a fluid having a higher concentration or viscosity and that has a longer filtration life. That is, an object of the present invention is to provide a filter for filtering a fluid containing a solid content, which has a high filtration accuracy even for a fluid having a high concentration or high viscosity and has a long filtration life.

  In order to suppress the occurrence of bridging in a filter having three layers of a base material layer, a filtration layer, and a skin layer, the inventor has proceeded with studies to solve the above-described problems. It has been found that the configuration of the base material layer, which is a layer on the downstream side of the layer, greatly affects. And, by setting the porosity and compression ratio of the base material layer within a specific range, a filter having a long filtration life and excellent filtration accuracy can be obtained even when filtering a high-concentration or high-viscosity fluid. And found the present invention.

That is, the present invention has the following configuration.
[1] A filter having a base material layer, a filtration layer, and a skin layer,
The base material layer is a layer in which a nonwoven fabric is wound in multiple layers and thermocompression bonded, and the compression ratio when the porosity is 0.61 to 0.84 and a load of 0.5 MPa is applied. 0.18 or less,
The filtration layer is a layer in which a laminate in which fibers are oriented in the thickness direction and a laminate of laminated nets is wound in multiple layers, and the layers in the filtration layer are not bonded,
The said skin layer is a layer containing a nonwoven fabric, Comprising: The average fiber diameter of the nonwoven fabric which comprises a skin layer is a filter which is 2 times or more of the average fiber diameter of the nonwoven fabric which comprises the said filtration layer.
[2] The filter according to [1], wherein the fibers constituting the nonwoven fabric of the base material layer include a heat-fusible conjugate fiber having a melting point difference of 10 ° C. or higher between the high melting point component and the low melting point component.
[3] The filter according to [1] or [2], wherein an average fiber diameter of fibers constituting the nonwoven fabric of the skin layer is 2 to 20 times an average fiber diameter of fibers constituting the filtration layer.
[4] The filter according to any one of [1] to [3], wherein the nonwoven fabric of the base material layer and the nonwoven fabric of the skin layer are the same nonwoven fabric.
[5] A cylindrical filter having the filter according to any one of [1] to [4].

  ADVANTAGE OF THE INVENTION According to this invention, it is excellent in the filtration precision also with respect to the fluid which contains a slurry and solid content which are highly concentrated, and it is hard to generate | occur | produce agglomeration (bridge) of powder, and provides a filter with a long filtration life. be able to.

  The filter of the present invention is a filter having a base material layer, a filtration layer, and a skin layer, and the base material layer is a layer in which a nonwoven fabric is wound in multiple layers and thermocompression-bonded, and the porosity is Is 0.61 to 0.84, and the compression ratio when a load of 0.5 MPa is applied is 0.18 or less, and the filtration layer includes a nonwoven fabric and a net in which fibers are also oriented in the thickness direction. The laminated body is a layer in which multiple layers are wound, and the nonwoven fabric layer is divided into several layers by the net in the filtration layer, and the skin layer is a layer containing the nonwoven fabric, The average fiber diameter of the nonwoven fabric which comprises a layer has the structure that it is 2 times or more of the average fiber diameter of the nonwoven fabric which comprises the said filtration layer.

  The filter of the present invention can have various shapes such as a flat shape and a cylindrical shape. In particular, the cylindrical type is preferable because the pressure resistance is high and the filter container can be easily designed when used as a so-called cartridge filter in which only the filter medium portion is replaced.

<Filtration layer>
The filter layer of the filter of the present invention is present between the base material layer and the skin layer, and a laminated body in which a nonwoven fabric in which fibers are oriented in the thickness direction and a net are laminated is wound in multiple layers. Here, “nonwoven fabric in which fibers are also oriented in the thickness direction” means that the fiber orientation is distributed in both the thickness direction of the nonwoven fabric (flow direction of the fluid to be filtered) and the surface direction (vertical direction of the fluid to be filtered). It typically means a nonwoven fabric in which the constituent fibers have a curvature. A nonwoven fabric in which fibers are also oriented in the thickness direction has characteristics of high porosity, elasticity, and bulkiness. For this reason, the pressure loss of the fluid is reduced, and even a fluid having a high concentration and viscosity can be filtered without staying. In addition, by laminating such a nonwoven fabric and a net, an appropriate gap is formed between the filtration layer nonwoven fabrics having a substantial filtration function. Therefore, the fluidity of the fluid in the filtration layer or the solid content in the fluid is improved, and the formation of the bridge is suppressed. In addition, by providing a gap between the nonwoven fabrics in the filtration layer, narrowing and clogging of pores due to the multilayered nonwoven fabric can be avoided, so that the filtration accuracy is excellent. Furthermore, since the nonwoven fabric layer constituting the filtration layer is divided into several layers by the net, the fibers in the nonwoven fabric can move slightly within the filtration layer, and the fluidity of the fluid and solids in the fluid Is further improved, and the shape of the filtration layer is retained by the net, so that the filtration performance is stably exhibited.

  The curvature of the constituent fiber is preferably in the range of 50 to 500 times the diameter of the constituent fiber. When this value is 500 times or less, the orientation of the fibers in the thickness direction becomes sufficient, and the above-mentioned effect is easily obtained. When this value is 50 times or more, the fiber orientation in the circumferential direction of the filter becomes sufficient.

  In general, a high-gap and bulky nonwoven fabric is often easily crushed by compression in the thickness direction, but the nonwoven fabric used in the filtration layer of the present invention has strength in the thickness direction by orienting the fibers also in the thickness direction. Can be obtained.

  In order to maintain stable performance, such a nonwoven fabric preferably has fibers fused and / or bonded at the intersection of the fibers in the nonwoven fabric. From this, a heat-fusible conjugate fiber can be preferably used as the fiber constituting the nonwoven fabric. The kind of heat-fusible conjugate fiber is not particularly limited, and a known conjugate fiber can be used. As the heat-fusible conjugate fiber, a conjugate fiber composed of two or more components having a difference in melting point can be used, and specifically, a conjugate fiber composed of a high melting point component and a low melting point component can be exemplified. Examples of the high melting point component of the composite fiber include thermoplastic resins such as polypropylene (PP), polyethylene terephthalate (PET), polybutylene terephthalate, polytrimethylene terephthalate, nylon 6, nylon 6,6, and poly-L-lactic acid. The low melting point component of the composite fiber includes polyethylene (PE) such as low density polyethylene, linear low density polyethylene, and high density polyethylene, polyethylene terephthalate copolymer, poly-DL-lactic acid, propylene copolymer, polypropylene, etc. These thermoplastic resins can be exemplified. The difference in melting point between the high-melting component and the low-melting component of the heat-fusible composite fiber is not particularly limited, but is preferably 10 ° C. or more, and 30 ° C. or more in order to widen the processing temperature range of heat-sealing. It is more preferable that The composite form is not particularly limited, and composite forms such as a concentric sheath core type, an eccentric sheath core type, a parallel type, a sea island type, and a radial type can be employed. Also, the cross-sectional shape of the heat-fusible conjugate fiber is not particularly limited. For example, the cross-sectional shape may be any shape such as a circle, an ellipse, a triangle, a square, a U-shape, a boomerang type, an eight-leaf shape, a hollow shape, Also good. Examples of the composite fiber include PE / PP composite fiber and PE / PET composite fiber. Further, special fibers such as fluorine fibers and glass fibers may be blended depending on the characteristics and purpose of the filtrate.

  The fiber diameter of the fiber constituting the nonwoven fabric in which the fibers are also oriented in the thickness direction used for the filtration layer of the filter of the present invention is preferably in the range of 0.1 to 200 μm, and the fiber in the range of 1 to 100 μm. The diameter is more preferable, and the fiber diameter is most preferably in the range of 15 to 60 μm. By setting the fiber diameter in the range of 0.1 to 200 μm, the obtained nonwoven fabric is excellent in bulkiness and elasticity. If fibers having a small fiber diameter are used, the collection efficiency is improved, but the filtration life (life) tends to be shortened. Therefore, the balance between the filtration life and the filtration accuracy is particularly good by setting the fiber diameter in the range of 15 to 60 μm.

  The narrower the fiber diameter distribution of the fibers constituting the nonwoven fabric in which the fibers are oriented in the thickness direction, the better. Specifically, the value of “standard deviation of fiber diameter ÷ average value” is preferably 0.3 or less, preferably 0.1 or less, and more preferably 0.08 or less. The narrower the fiber diameter distribution, the better the filter.

The basis weight of the nonwoven fabric in which the fibers are also oriented in the thickness direction is defined to some extent in relation to the fiber material, fiber diameter, and particle collection efficiency. For example, a fabric having a weight of 5 to 40 g / m ² should be used. More preferably, it is a thing of 10-30 g / m < ² >. A basis weight of 5 to 40 g / m ² is preferable because the selection range for adjusting the thickness and average pore diameter of the filtration layer is widened.

  As a method of orienting the fibers of the nonwoven fabric also in the thickness direction, for example, using a composite fiber as a fiber constituting the nonwoven fabric, in particular, a fiber having a fiber cross-section that is asymmetrical, specifically, an eccentric sheath-core composite fiber, Side-by-side conjugate fibers can be used. As the two components of the composite fiber, those having greatly different heat shrinkage rates are used, so that the fiber is crimped in the heating process due to the so-called bimetallic effect, so that part of the fiber is also oriented in the thickness direction.

  As another method of orienting the fibers of the nonwoven fabric also in the thickness direction, short fibers having mechanical crimps are used as the fibers constituting the nonwoven fabric, and the fibers are entangled with a card machine to form a web. There is a method in which a non-woven fabric is obtained by heat treatment. Due to mechanical crimping of the fiber and entanglement by the card machine, a part of the fiber comes to be oriented in the thickness direction.

  Both the long fibers and the short fibers can be used as the fibers constituting the nonwoven fabric in which the fibers are also oriented in the thickness direction, but short fibers are desirable in order to exhibit the above-described effects.

  Examples of the method for fusing the intersections of the fibers in the nonwoven fabric include a method of heating the fibers with hot air and a method of heating the fibers with a far infrared heater. In order to make the degree of thermal fusion uniform in the nonwoven fabric, a method of heating the fiber with hot air is desirable.

  Further, the net used for the filtration layer is inserted between the nonwoven fabrics in which the fibers are also oriented in the thickness direction to create a gap, and the shape of the filtration layer is maintained, and the pressure resistance is maintained and improved. Therefore, the net is preferably a monofilament having a fiber diameter in the range of 50 to 300 μm, and more preferably a monofilament having a fiber diameter in the range of 60 to 280 μm. Furthermore, the mesh of the net is preferably in the range of 1 to 5 mm, and more preferably in the range of 1 to 4 mm. By using a net in this range, the filter efficiency is not affected, and the strength of the filter is ensured, so that a filter with a longer filtration life can be obtained.

  The monofilament constituting the net is preferably made of a thermoplastic resin, and single component fibers, composite fibers, and mixed fibers can be used. The thermoplastic resin that can be used for the monofilament is not particularly limited as long as it is a melt-spinnable thermoplastic resin, and a single thermoplastic resin or a mixture of two or more kinds of thermoplastic resins may be used. When the monofilament is a composite fiber, for example, a combination of thermoplastic resins as exemplified in the heat-fusible composite fiber can be used. When the monofilament is a heat-fusible conjugate fiber, a low-melting point thermoplastic resin covers at least a part of the fiber surface out of the resin constituting the conjugate fiber, and this low-melting point thermoplastic resin makes the heat-fusible property A net formed by heat-sealing composite fibers can also be used. When a heat-fusible conjugate fiber is used for the monofilament, the intersection of the nets adheres and the strength of the net is increased, so that the strength of the formed filter is further increased and the effect of using the net is easily obtained. Examples of the thermoplastic resin include PE, PP, PET, nylon 6, nylon 6,6, nylon 6,12, and the like, and PP or nylon is particularly preferable.

  The filtration layer of the filter of the present invention is formed by multiplely winding a laminate in which a nonwoven fabric in which fibers are oriented in the thickness direction and the net are laminated. The stacking order of the nonwoven fabric and the net is not particularly limited, but it is preferable to wind the nonwoven fabric and the net one by one, that is, the nonwoven fabric and the net alternately. The filtration layer formed in this way has a structure in which a coarse net is sandwiched between nonwoven fabrics. The number of windings can be appropriately set according to the target filter size and filtration performance, and is not particularly limited. For example, the filtration layer can be wound to have a thickness of about 5 to 30 mm.

  Further, if necessary, in addition to the nonwoven fabric and the net in which the fibers are oriented in the thickness direction, a further nonwoven fabric and a net may be laminated in the filtration layer. For example, in addition to the above nonwoven fabric and net, the same nonwoven fabric as the base material layer or a melt blown nonwoven fabric having a coarser mesh than the above nonwoven fabric is inserted to wind a three-layered laminate, The collection efficiency can be improved. When using a melt blown nonwoven fabric, the same melt blown nonwoven fabric as used for the base material layer and the skin layer can be preferably used.

<Base material layer>
The base material layer is a layer corresponding to the inner side of the cylinder of the cylindrical filter and the downstream side of the fluid to be filtered, and has a function of ensuring the strength of the filter. The base material layer of the filter of the present invention is a layer in which a nonwoven fabric is wound in multiple layers and thermocompression bonded, and has a feature that the compression ratio when a load of 0.5 MPa is applied is 0.18 or less. . The compression ratio is an index indicating the ease of deformation with respect to a continuous external load. If the compression ratio is 0.18 or less when a load of 0.5 MPa is applied, the deformation at the time of using the filter is scarce. It is preferable because it is not. The specific measurement and calculation method of the compression ratio will be described in detail in Examples.

  Moreover, the base material layer of the filter of this invention has the characteristics that the porosity is the range of 0.61-0.84. Conventionally, the base material layer located on the downstream side of the filtration layer is considered to reinforce the filtration layer, and if the layer has a larger pore diameter than the filtration layer, it is considered that the filtration life is not affected. It was. However, in the present invention, it is found that the base material layer has a great influence on the filtration life, the strength is ensured by setting the compression ratio of the base material layer to 0.18 or less, and the porosity is 0.61 to 0.84. It was confirmed that a filter having a long filtration life could be obtained if the range was satisfied. Although not being bound by a specific theory, by setting the compression ratio and the porosity to the above ranges, the fluid that has passed through the filtration layer does not stay in the base material layer, and in the base material layer. It is thought that the occurrence of bridging is suppressed. If the porosity is 0.61 or more, the liquid permeability is sufficient, and if the porosity is 0.84 or less, there is no possibility that the base material layer is deformed when using a high temperature or a chemical solution.

  In order to maintain stable performance, the base material layer preferably uses a nonwoven fabric in which fibers are fused and / or bonded at the intersection of the fibers. From this, a heat-fusible fiber can be preferably used as the fiber constituting the nonwoven fabric of the base material layer. The kind of heat-fusible fiber is not specifically limited, A well-known fiber can be used. As specific heat-fusible fibers, the same materials as those exemplified in the description of the heat-fusible fibers used for the filtration layer can be used, and heat-fusible properties including a high melting point component and a low melting point component. A composite fiber, a mixed fiber of a high-melting component fiber and a low-melting component fiber is preferable. In this case, the difference in melting point between the high melting point component and the low melting point component is not particularly limited, but is preferably 10 ° C. or more, and preferably 30 ° C. or more in order to widen the processing temperature range of heat fusion. More preferred. For example, a sheath-core type composite fiber having polypropylene as a core component and polyethylene as a sheath component, or a mixed fiber of polypropylene fiber and propylene copolymer fiber can be preferably used.

As a nonwoven fabric used for the base material layer of this invention, a melt blown nonwoven fabric, a through air nonwoven fabric, etc. can be used, and it does not restrict | limit in particular. When using a meltblown nonwoven fabric, the kind of fiber which comprises a meltblown nonwoven fabric, and its manufacturing method are not specifically limited, A well-known fiber and manufacturing method can be used. For example, a melt blown nonwoven fabric is obtained by melt-extruding a thermoplastic resin, spinning from a melt blown spinneret, blow spinning as a fiber stream with a high-temperature and high-speed gas, and collecting the fibers as a web with a collection device. It can be manufactured by heat-treating and fusing the fibers together. As the high-temperature and high-speed gas used in melt blow spinning, an inert gas such as air or nitrogen gas is usually used. The temperature of the gas is generally 200 to 500 ° C., and the pressure is generally in the range of 0.1 to 6.5 kgf / cm ² .

  The average fiber diameter of the nonwoven fabric constituting the base material layer is preferably 2 times or more, more preferably 3 times or more the average fiber diameter of the nonwoven fabric constituting the filtration layer. When this value is twice or more, the particles flowing out through the filtration layer can be prevented from being collected by the base material layer.

  Although the material of the nonwoven fabric which comprises a base material layer is not restrict | limited in particular, Since chemical resistance becomes comparable as a filtration layer by using the material contained in the nonwoven fabric which comprises a filtration layer, it is preferable.

Basis weight of the nonwoven fabric constituting the substrate layer is made of fibers, in relation to the fiber diameter, although to some extent defined, for example, can be used a basis weight of ^{5~50g / m 2, 30~45g / m} 2 It is more preferable to use the basis weight. A basis weight in this range is preferable from the viewpoint of adjusting the outer diameter of the base material layer and adjusting the strength design of the base material layer.

  The number of turns and the thickness of the base material layer are set according to the size of the target filter and the desired strength, and are not particularly limited. For example, the thickness of the base material layer can be about 5 to 50 mm. The nonwoven fabric of the base material layer is bonded between the layers simultaneously by winding or after being wound by thermocompression bonding.

<Skin layer>
The skin layer is the layer located on the outermost side of the filter (upstream side of the filtrate), and in particular blocks and prevents large particle aggregates and contaminants from entering the filtration layer, protecting the filtration layer, This layer is mainly intended to maintain the filter form. The skin layer is a layer containing a nonwoven fabric, and is preferably a layer made of a nonwoven fabric.

  The nonwoven fabric used for the skin layer is not particularly limited, but the average fiber diameter is preferably at least twice the average fiber diameter of the nonwoven fabric constituting the filtration layer, more preferably 2 to 20 times, Preferably it is 3 to 10 times. When this value is twice or more, excessive clogging of the skin layer can be prevented. Moreover, when this value is 20 times or less, the skin layer can have the effect of prefiltration of the filtration layer. Moreover, it is also preferable that it is the same nonwoven fabric as the nonwoven fabric used for a base material layer as a nonwoven fabric used for a skin layer. Note that the same non-woven fabric means non-woven fabrics that are considered to be substantially the same non-woven fabric having the same fiber material (composition), fiber diameter, non-woven fabric configuration, basis weight, and the like. By using the same non-woven fabric for the base material layer and the skin layer, a filter with more stable product quality can be obtained, which is advantageous in the cost of the manufacturing process.

  The number of turns and thickness of the skin layer are not particularly limited, but if the number of turns or thickness increases, there may be a problem that a bridge forms in the skin layer before the filtrate reaches the filtration layer. A layer is preferred. For example, the melt blown nonwoven fabric is preferably wound 1 to 5 times, preferably 1 to 2 times, and thermocompression-bonded.

  Any of the fibers constituting the substrate layer, the filtration layer, and the skin layer nonwoven fabric of the filter of the present invention may contain a functional agent as long as the effects of the present invention are not hindered. Deodorants, antistatic agents, smoothing agents, hydrophilic agents, water repellents, antioxidants, weathering agents and the like can be exemplified. Further, the surface of the fiber may be treated with a fiber finishing agent, whereby functions such as hydrophilicity, water repellency, antistatic, surface smoothness, and abrasion resistance can be imparted.

<Filter manufacturing method>
The filter of this invention can be manufactured by winding the nonwoven fabric for base materials layers, winding the nonwoven fabric for filtration layers, and a net | network on it, and also winding the nonwoven fabric for skin layers on it. Specifically, for example, a melt blown nonwoven fabric, which is a nonwoven fabric for a base material layer, is first wound around a cylindrical iron rod while being thermocompression bonded to form a base material layer that becomes a core. Subsequently, a through-air non-woven fabric and a net, which are non-woven fabrics for the filtration layer, are sequentially inserted and rolled up without heating to form a filtration layer. Finally, the melt blown nonwoven fabric can be wound 1-2 times and thermocompression bonded to form a skin layer.

  The temperature for forming the base material layer in the above production method may be any temperature at which the non-woven fabric for the base material layer is melted and pressure-bonded at the winding portion (cylindrical iron bar). The speed of the production line is not particularly limited, but when forming the filtration layer, the tension applied to the nonwoven fabric is preferably 10 N or less, and it is preferable to wind up without applying tension.

  The filter manufactured as described above is suitably used as a cylindrical filter by cutting into an appropriate size and attaching end caps to both ends. Moreover, said manufacturing method is only an outline | summary and well-known processes, such as heat processing, cooling, chemical | medical agent processing, a shaping | molding, and washing | cleaning, can be implemented as needed other than said process. In use, the gel-like fluid containing slurry and solid content is set so as to pass from the outside (skin layer side) of the cylindrical filter to the inside (base material layer side) through the filtration tank.

The following examples are for illustrative purposes only. The scope of the present invention is not limited to this example.
The measurement methods and definitions of the physical property values shown in the examples are as follows.

1) Fabric weight of nonwoven fabric The weight of a nonwoven fabric cut to 250 mm x 250 mm was measured to determine the weight per unit area (g / m ² ), which was used as the fabric weight.
2) Layer porosity The outer diameter, inner diameter, length, and weight of the layer were measured, and the porosity was determined using the following equation.
(Apparent volume of layer) = π {(Outer diameter of layer) ² − (Inner diameter of layer) ² } × (Layer length) / 4
(True volume of layer) = (weight of layer) / (specific gravity of raw material of layer)
(Layer porosity (%)) = {1− (true volume of layer / apparent volume of layer)} × 100
3) Compression ratio The base material layer was cut into 20 mm x 20 mm, the original thickness was measured, and then the thickness of the small piece when a 0.5 MPa load was applied to the small piece was measured. The compression ratio was calculated using the measured thickness and the following formula.
Compression ratio = (initial thickness-thickness when a load is applied) ÷ (initial thickness)
4) Collection efficiency (filtration accuracy)
The collection efficiency was measured as the initial collection performance according to the following test powder and method. Seven kinds of test powders described in JIS Z 8901 test powder were used. A test fluid obtained by adding JIS 7 seed powder into water at a rate of 0.2 g / min was passed through the filter at a flow rate of 30 L / min, and the number of particles before and after the filter was measured. The number of particles was measured using a particle sensor (manufactured by KS-63 Lion) and a particle counter (manufactured by KL-11 Lion). The collection efficiency was determined by the following definition formula.
Collection efficiency (%) = (1−number of particles having a particle diameter of 30 μm after passing through the filter / number of particles having a diameter of 30 μm before passing through the filter) × 100
5) Filtration life According to the following powder and method, the change in differential pressure before and after the filter with respect to the cumulative amount of powder added was measured. Seven kinds of test powders described in JIS Z 8901 test powder were used. A test fluid to which the test powder was added at a rate of 0.2 g / min in water with a circulating water amount of 30 L / min was passed through the filter, and the change in pressure difference before and after the filter with respect to the cumulative powder addition amount was followed. The time when the pressure difference became twice the initial pressure difference was defined as the filtration life, and the amount of powder added at that time was recorded. Further, the filter appearance at the time when the pressure difference became twice the initial pressure difference was visually observed.

[Example 1]
As the nonwoven fabric for the base material layer, a propylene copolymer / polypropylene concentric sheath / core composite meltblown nonwoven fabric having a basis weight of 50 g / m ² and an average fiber diameter of 190 μm was used. As the nonwoven fabric for the filtration layer, a through-air nonwoven fabric made of an eccentric sheath / core composite fiber (average fiber diameter 30 μm) of polypropylene / polyethylene with a basis weight of 30 g / m ² was used. As the net, a net made of polypropylene monofilament (average fiber diameter 250 μm) and having a mesh of 2.0 mm was used. The core (iron bar) was heated to 150 ° C. in advance, and the melt blown nonwoven fabric used for the base material layer was adhered to the core and wound. Furthermore, while continuing heating at 150 ° C., 6 m was wound up to form a base material layer. Subsequently, the same nonwoven fabric as that for the base material layer, the nonwoven fabric for the filtration layer, and the net were wound up 2 m to form a filtration layer. Subsequently, 1 m of the same non-woven fabric as the base material layer was wound up to form a skin layer, and a cylindrical filter was manufactured.

[Example 2]
As the nonwoven fabric for the filtration layer, a through-air nonwoven fabric made of an eccentric sheath / core composite fiber (average fiber diameter 22 μm) of polypropylene / polyethylene with a basis weight of 30 g / m ² was used. Otherwise, a cylindrical filter was produced in the same manner as in Example 1.

[Example 3]
As the nonwoven fabric for the base material layer, a propylene copolymer / polypropylene concentric sheath / core composite meltblown nonwoven fabric having a basis weight of 50 g / m ² and an average fiber diameter of 150 μm was used. Otherwise, a cylindrical filter was produced in the same manner as in Example 1.

[Example 4]
As the nonwoven fabric for the substrate layer, a propylene copolymer / polypropylene concentric sheath / core composite meltblown nonwoven fabric having a basis weight of 50 g / m ² and an average fiber diameter of 120 μm was used. Otherwise, a cylindrical filter was produced in the same manner as in Example 1.

[Comparative Example 1]
As the nonwoven fabric for the base material layer, a polypropylene single component melt blown nonwoven fabric having a basis weight of 50 g / m ² and an average fiber diameter of 190 μm was used. Otherwise, a cylindrical filter was produced in the same manner as in Example 1.

[Comparative Example 2]
As the nonwoven fabric for the base material layer, a polypropylene single component melt blown nonwoven fabric having a basis weight of 50 g / m ² and an average fiber diameter of 190 μm was used. And the winding temperature at the time of forming a base material layer was changed from 150 degreeC to 165 degreeC. Otherwise, a cylindrical filter was produced in the same manner as in Example 1.

About Examples 1-4 and Comparative Examples 1 and 2, a summary is shown in Table 1 about the material of a cylindrical filter, a physical-property value, and performance.

  As shown in Table 1, all of the cylindrical filters of Examples 1 to 4 had a large cumulative powder addition amount until the filter differential pressure reached twice the initial value, that is, the filtration life was long. Moreover, all the cylindrical filters of Examples 1 to 4 were able to collect 60% or more of particles having a particle diameter of 30 μm, and had necessary filtration accuracy. Since the cylindrical filter of the example has a high porosity of the base material layer and the compression ratio is low, compression of the base material layer does not occur during filtration, and a longer filtration life is obtained than the cylindrical filter of the comparative example. The collection efficiency with a particle size of 30 μm was also higher than that of Comparative Example 1. On the other hand, Comparative Example 2 with a low compression ratio but a low porosity had a shorter filtration life than the Examples. In addition, apparent shrinkage was observed in the appearance of the cylindrical filter of Comparative Example 2 when the pressure difference was twice the initial pressure difference, and this filter was suitable for filtration of high-concentration or high-viscosity fluid. Not shown. Such shrinkage was not observed in the appearance of the filters of Examples 1 to 4.

  Since the filter of the present invention suppresses the occurrence of powder aggregation (bridge), the filtration life is long and the filtration accuracy is excellent. The filter of the present invention removes aggregates and contaminants from suspensions, slurries, and gel fluids containing fine particles (powder) having a low concentration to a high concentration (10 ppm to 70%), and has a particle size of a certain value or less. It is suitably used as a filtration filter used for obtaining fine particles.

Claims (5)

A filter having a base material layer, a filtration layer, and a skin layer,
The base material layer is a layer in which a nonwoven fabric is wound in multiple layers and thermocompression bonded, and the compression ratio when the porosity is 0.61 to 0.84 and a load of 0.5 MPa is applied. 0.18 or less,
The filtration layer is a layer in which a laminate in which fibers are oriented in the thickness direction and a laminate of a net is laminated, and the layers in the filtration layer are not bonded,
The said skin layer is a layer containing a nonwoven fabric, Comprising: The average fiber diameter of the nonwoven fabric which comprises a skin layer is a filter which is 2 times or more of the average fiber diameter of the nonwoven fabric which comprises the said filtration layer. The filter according to claim 1, wherein the fibers constituting the nonwoven fabric of the base material layer include a heat-fusible conjugate fiber having a melting point difference of 10 ° C. or more between a high melting point component and a low melting point component. The filter according to claim 1 or 2, wherein an average fiber diameter of fibers constituting the nonwoven fabric of the skin layer is 2 to 20 times an average fiber diameter of fibers constituting the filtration layer. The filter according to any one of claims 1 to 3, wherein the nonwoven fabric of the base material layer and the nonwoven fabric of the skin layer are the same nonwoven fabric. The cylindrical filter which has a filter of any one of Claims 1-4.