JP4839978B2 - Oil filter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an oil filter which enables a securement of a filtration area in dimensions similar to the conventional one, and can be made thin-shaped. <P>SOLUTION: The oil filter 1A is provided with a pair of case members 11, 12 forming a filter chamber 16 by abutting the sides mutually, and a filter element portion 13 provided on the case members to partition the inside of the filter chamber. The filter element portion comprises a filter element 131, in which the length of a direction passage from a dusty portion 16a to a clean portion 16b inside the filter chamber is longer than the height of the filter chamber. Such the oil filter is easy to be made thin-shaped while securing the filtration area in dimensions similar to the conventional one. <P>COPYRIGHT: (C)2008,JPO&amp;INPIT

Description

  The present invention relates to an oil filter for an automatic transmission, and more particularly, to an oil filter that can be made thin while ensuring a filtration area as large as a conventional filter.

Conventionally, as an oil filter for an automatic transmission or the like, as illustrated in FIG. 11, a pair of case members 110 and 120 that are abutted with each other to form a filtration chamber 16 and a filter that partitions the inside of the filtration chamber 16. An element provided with an element 130 is known. Such a conventional oil filter, for example, by folding the filter element 130 and providing the top and bottom of each fold in a direction perpendicular to the surface of the case member, increasing the filtration area, The filtration flow rate is increased.
Such an oil filter for an automatic transmission is desired to be thinner in order to further reduce the space required for mounting.
For example, the oil filter of Patent Document 1 can be sufficiently installed at a place where there is not enough room by disposing the oil inlet and outlet on the same surface.

JP 2000-300196 A

However, since the oil flow of Patent Document 1 is greatly different from the conventional oil filter in the flow of oil around the filter, it is necessary to greatly change the design of the arrangement and the like of related equipment. Further, since it is necessary to secure an oil flow passage between each case member and the filter element, it is difficult to make the device thinner. In particular, when the top and bottom of each fold are provided so as to be oriented in a direction perpendicular to the surface of the case member, it is necessary to form a fold and to secure a flow path. Therefore, it is difficult to reduce the height and reduce the thickness.
In addition, as shown in FIG. 12, if the support member such as the rib 17 is not disposed at the intermediate portion of the filter element 130, the fixing interval is wide, so that the center portion is likely to be misaligned and difficult to deviate. It was necessary to add a support member.

  This invention is made | formed in view of the said present condition, and it aims at providing the oil filter which can be made thin, ensuring the filtration area to the magnitude | size similar to the past.

The present invention is as follows.
1. And the case member of flat shape having an inlet and an outlet, and is disposed so as to partition the clean part of the Dusty portion and flow outlet side of the flow inlet side filter chamber in the plane direction of the case member inside the flat shape A filter element portion that filters oil flowing from the dusty portion to the clean portion, the filter element portion including a filter element, and the filter element is disposed along a cross-section in the thickness direction of the case member. And the length in the direction from the dusty part toward the clean part is longer than the length in the thickness direction of the case member, and the filter element has a direction from the dusty part toward the clean part. An oil filter characterized by being a fold-fold sheet formed by being repeatedly bent in a parallel direction .
2. A flat case member having an inlet and an outlet, and a flat filtration chamber inside the case member arranged in a plane direction to be divided into a dusty part on the inlet side and a clean part on the outlet side; A filter element portion that filters oil flowing from the dusty portion to the clean portion, the filter element portion including a filter element, and the filter element is disposed along a cross-section in the thickness direction of the case member. And the length in the direction from the dusty part toward the clean part is longer than the length in the thickness direction of the case member, and the filter element has a direction from the dusty part toward the clean part. An oil filter characterized by being a honeycomb filter having both ends opened in a parallel direction .
3. Both ends of the fold in the width direction are fixed . Oil filter as described.
4). The filter element is sandwiched by the case member. To 3. The oil filter as described in any one of.
5). The filter element portion further includes a filter element support member, the filter element is provided on the filter element support member, and the filter element support member is disposed on the case member. To 3. The oil filter as described in any one of.
6). The filter element portion is sandwiched between the abutted side surfaces of the case member, one of the case members has laser transparency, the other of the case members has laser absorption, An element welded portion by laser light is formed on the outer surface side of the contact portion between the other butted end surface and the filter element portion. To 5. The oil filter as described in any one of.

According to the oil filter of the present invention, since the filter element portion having a long length in the direction from the dusty portion to the clean portion is provided, the filtration area is the same size as the conventional one even with the same piping structure as the conventional one. It is possible to reduce the thickness while securing the thickness.
In addition, the oil filter is low in height, and even if it is flat, it can be made thin because it does not hinder the flow of oil flowing inside. Furthermore, when the height for supporting and fixing the filter element portion is lower than the conventional one, it is possible to prevent the folds from coming into close contact without adding a support member such as the rib 17 to the filter element 130 illustrated in FIG. .

Furthermore, when a fold-folded sheet that has been folded in a direction different from the conventional one is used for the filter element, there is no hindrance to the flow of oil flowing through the filtration chamber even if the height of the oil filter is low, Even if the filtration chamber is flat, it can be made thin. Further, when the height of the filter element is made lower than before, the filter element can suppress the close contact of the folds without adding a support member such as the rib 17 to the filter element 130 illustrated in FIG. It can be set as an oil filter provided with.
Furthermore, when the honeycomb filter is used for the filter element, even if the height of the oil filter is low, the flow of the oil flowing through the filtration chamber is not hindered, and the thickness can be reduced.
Moreover, when using the filter element support member for arrange | positioning in a case member, joining of a case member and a filter element part can be performed easily.

Further, when one case member is made to be laser-transmitting and the other case member is made to be laser-absorbing, the case member can be easily laser-welded and can be firmly joined. The oil filter that is laser welded by using a case member having laser transparency and laser absorption property is in a state where the edge of the filter element is in contact with the butt end of the other case member. The laser light can be irradiated from the side toward the outer surface of the butt end portion and the outer surface of the filter element. As a result, an element welded portion by laser light is formed on the outer surface side of the contact portion between the butted end of the other case member and the filter element, and the other case member and the filter element are formed by this element welded portion. Is firmly welded.
Therefore, even if an excessive internal pressure is applied to the filtration chamber when the filter is used, the filter element is prevented from being damaged or the fixed element being detached (the filter element comes out from between two opposing case members). it can. In addition, the welded part for the element is located sufficiently away from the filtration chamber, and even if foreign matter such as weld burrs is generated near the welded part for the element due to the output of the laser beam, the foreign matter is in the other case. Intrusion into the filtration chamber through the contact surfaces of the member and the filter element can be suppressed.

Hereinafter, for example, the oil filter of the present invention will be described in detail with reference to FIGS.
The oil filter of the present invention includes flat case members 11 and 12 and a filter element portion 13 as illustrated in FIGS.

  The size of the “case member” is not particularly limited. The shape of the case member is not particularly limited as long as it is a flat shape and includes a filtration chamber composed of a dusty portion and a clean portion. Usually, for example, as illustrated in FIGS. 2 and 6, the case members 11 and 12 having frame-shaped butted ends 111 and 121 are joined, and the butted ends 111 and 121 are joined in a butted state so that the oil is A case member that forms a flat-shaped filtration chamber 16 that is circulated and filtered can be cited. Moreover, one side surface illustrated in FIGS. 1 to 4 is opened as an end for matching, and a rectangular parallelepiped whose side in the height direction is shorter than the other sides, the ceiling surface or the bottom surface illustrated in FIG. For example, a dish-shaped rectangular parallelepiped that is opened as an end portion and whose length in the height direction is shorter than the other sides, and a bowl shape can be given.

The material of each case member is not particularly limited, and can be made of, for example, a synthetic resin material containing a dye and / or a pigment. Examples of the synthetic resin material include amorphous resins such as polystyrene (PS), low density polyethylene (LDPE) and polycarbonate (PC), polypropylene (PP), polybutylene terephthalate (PBT), polyethylene terephthalate (PET), Examples thereof include crystalline resins such as polyamide (PA) and polyacetal (POM).
In addition, when matching is performed by laser welding, it is preferably an amorphous resin and the case member contains a dye from the viewpoint of laser transmittance.

For example, the butted ends 111 and 121 of the case members 11 and 12 may be directly butted together as illustrated in FIG. 7, for example, or the filter element 13 and the like may be butted together as illustrated in FIG. Abutting may be performed between the end portions 111 and 121. Moreover, the method of fixing in the abutted state is not particularly limited, and examples thereof include mechanical fixing methods such as fixing by fitting and fixing by a locking claw. Furthermore, the fixation by the adhesive and the fixing by the thermal welding of the butt end portion can also be mentioned. Moreover, in heat welding, arbitrary heat sources, such as a heater and a laser, can be used.
Laser welding is usually performed by continuously and uniformly irradiating along the circumference of the butt end. In addition, for example, a welding portion by laser light can be formed at the contact portion of each case member with the butt end portion. The welding width, depth, shape and the like of the welded portion are not particularly limited. Moreover, a laser absorptivity can be improved by using a dye, a pigment, or the like in the welded portion.

  Moreover, the case members 11 and 12 are provided with an oil outlet 14 and an inlet 15 of an arbitrary shape as illustrated in FIGS. In addition, the position which provides an inflow port and an outflow port is not specifically limited, It can provide in arbitrary positions. Moreover, an inflow port and an outflow port may be provided in each case member, and an inflow port and an outflow port may be provided in one case member.

The “filter element part” partitions the filtration chamber into the “dusty part” and the “clean part”, and performs filtration of oil flowing from the dusty part to the clean part. The filtration chamber is provided with an inlet in the dusty part and an outlet in the clean part.
Furthermore, the filter element unit includes at least a filter element. Further, for example, as illustrated in FIG. 5, a filter element support member 135 can be further provided. Further, as illustrated in FIGS. 2 and 5, for example, the shape of the filter element member is such that the length L of the filter element 131 in a direction parallel to the direction 2 from the dusty portion 16 a toward the clean portion 16 b is the height of the filter element 131. It should be longer than H. In this way, the flat filter element that is long in the direction from the dusty part 16a to the clean part 16b can increase the number of places where oil passes through the filter element even if the height of the filtration chamber is low. A flow rate can be obtained and the thickness can be reduced. For this reason, a flat shape with a low height is particularly suitable for the present filter element. In particular, the height of the filter element can be 3 to 40 mm, preferably 5 to 30 mm, particularly preferably 8 to 25 mm.

The “filter element” is a portion of a filter medium that filters oil, and the size and material of the filter element are not particularly limited as long as the filter element can be provided in the filter chamber.
The shape of the filter element is not particularly limited and can be arbitrarily selected. For example, a folded shape illustrated in FIGS. 2 and 6, a honeycomb shape illustrated in FIG. 7, a sponge shape illustrated in FIG. Can be mentioned. Furthermore, as illustrated in the filter element 132 in FIG. 6 and the filter element 134 in FIG. 10, the filter element can be provided in substantially the entire filtration chamber 16 except for the outlet 14 and the inlet 15 and their periphery. In this way, the filter area can be increased and the thickness can be reduced by providing the filter element in substantially the entire other filtration chamber 16 except for the outlet 14 and the inlet 15 and their surroundings that obstruct the flow. it can.
Further, the filter element is disposed along the thickness direction cross section of the case member. The “thickness direction of the case member” refers to the height direction of the side surface having the smallest thickness in the flat case member. Further, the “thickness direction cross section” represents a cross section located at the boundary surface between the dusty portion and the clean portion of the filtration chamber.
The fold-like filter element is formed by repeatedly bending the fold-fold direction in a direction substantially parallel to the direction from the dusty portion 16a toward the clean portion 16b. That is, for example, as illustrated in FIG. 2 and FIG. 5, the crease line 136 at the top of the fold fold is closer to one side in the direction parallel to the direction 2 from the dusty portion 16 a to the clean portion 16 b, and The crease line 137 is formed so as to be bent toward the other side in the parallel direction.
On the other hand, the conventional filter element is arranged such that the fold line 136 at the top of the fold and the fold line 137 at the valley are directed in the height direction of the case members 110 and 120 as shown in FIG. For this reason, the conventional filter element tends to have a long crease line. For example, the filter element 130 illustrated in FIG. 12 is not deformed by flowing oil unless the support member such as the rib 17 is in the middle of the crease line. As a result, the pressure loss increases due to close contact with the folds. On the other hand, as illustrated in FIG. 5, for example, the oil filter has a fold line 136 that is the height of the filtration chamber 16 and can be made shorter than the fold line of the conventional filter element. Even if there is no member, it is possible to suppress the close contact of the folds and suppress the increase in pressure loss.

The material of the filter element is not particularly limited, and examples thereof include resin, paper, and metal. Furthermore, the filter element can be in the form of a nonwoven fabric, a woven fabric, or the like. The filter element may have, for example, laser transparency or laser absorption.
When the filter element is directly arranged on the case member, the arrangement method is not particularly limited, and any means can be used. As an example of this, it is possible to include fixing by sandwiching each case member, joining to each case member using vibration welding and laser welding, and bonding using an adhesive.
Further, both end portions in the width direction of the folds of the filter element having the fold shape, that is, both end portions in the thickness direction of the case member can be fixed to the filter element support member or the case member. This fixing method is not particularly limited as in the case where the filter element is directly disposed on the case member, and examples thereof include clamping, vibration welding, laser welding, and adhesion.

The “filter element support member” is a support member for locking the filter element to each case member.
The shape, size, material, and the like of the filter element support member are not particularly limited as long as they can satisfy the above functions. For example, the filter element support member 135 may be a frame that is provided around the filter element 131 as illustrated in FIGS. 1, 2, and 5. Moreover, the filter element support member 135 can be provided with a groove 138 for fitting with the butted ends 111 and 121 of the case members 11 and 12, as illustrated in FIG.
The joining method of the filter element support member and each case member can be arbitrarily selected. For example, vibration welding or laser welding can be performed after fitting. Furthermore, a means for providing the filter element on the filter element support member can be arbitrarily selected. For example, after insert molding, vibration welding, laser welding, or the like can be exemplified.

The manufacturing method of the oil filter is not particularly limited. For example, in the state where the edge of the filter element is sandwiched between the respective butted ends of the case member, the case member is pressurized in the butting direction, and the pressurized state Then, a method of fixing by forming the element welded portion by irradiating the laser beam can be mentioned. As a result, the laser light is irradiated in a pressurized state of the filter element, so that the internal density of the filter element can be increased and the bonding strength between the filter element and the other case member can be improved.
This oil filter is usually used for filtering oil for automatic transmissions, but is not limited to this, and can be used for filtering oil such as engine oil and hydraulic equipment. It can also be used for filtration of fluids such as fuel.

Hereinafter, the oil filter of the present invention will be specifically described by way of examples. In the first to fourth embodiments, the same reference numerals are assigned to substantially the same components, and detailed descriptions thereof are omitted.
The oil filter 1A according to the first embodiment is an oil filter for an automatic transmission used in a vehicle, and includes case members 11 and 12 and a filter element portion 13 as shown in FIGS. Moreover, when the case member 11, the filter element part 13, and the case member 12 are abutted in this order, a filtration chamber 16 is formed, and oil flows in the order of the case member 11, the filter element part 13, and the case member 12.

The case members 11 and 12 are made of synthetic resin and are flat rectangular parallelepipeds having one end face opened. Also, an oil outlet 14 and an inlet 15 are provided. The filter element unit 13 includes a filter element 131 and a filter element support member 135.
The filter element 131 is a fold-shaped filter paper. Further, the filter element 131 is formed by bending so that the crease line 136 at the top of the fold fold is closer to one side in the parallel direction and the crease line 137 at the fold fold is closer to the other side in the parallel direction. . Further, the length L of the filter element 131 in the fold-folded length direction is longer than the height H of the filter element 131 in the fold-width direction.
The filter element support member 135 is a support member that supports the filter element 131 so as to surround the filter element 131, and the butted ends 111 and 121 of the case members 11 and 12 are fitted to the periphery of the opening from which the filter element 131 is exposed. A groove portion 138 is formed. Further, the filter element support member 135 and the filter element 131 have both end portions in the width direction of all the folds of the filter element 131 fixed by insert molding.

In such an oil filter 1A, the oil that has entered the filtration chamber 16 from the inlet 15 passes through the case member 12, and then is filtered by the filter element 131 of the filter element portion 13, and then passes through the case member 11. It flows out from the outlet 14.
Moreover, since it is not necessary to provide a gap for circulating oil above and below the filter element as in an oil filter provided with a fold-fold filter element sheet illustrated in FIG. 11, for example, the height in the filtration chamber is less than 20 mm. It is easy to do, and even if it is a flat oil filter of less than 20 mm, it does not interfere with oil circulation and can be made thin.

The oil filter 1B of the second embodiment is an oil filter for an automatic transmission in which a filter element is provided in substantially the entire filtration chamber. As shown in FIG. 6, case members 11 and 12, a filter element portion 13B, .
One case member 11 is made of a synthetic resin material containing a dye and has laser transparency. The other case member 12 is made of a synthetic resin material containing a pigment such as carbon black and has laser absorption.
Further, the filter element portion 13B is configured only by the folded filter element 132, and is fixed so that the end portion of the filter element 132 is sandwiched between the butted end portions 111 and 121 of the case members 11 and 12. Yes. Moreover, the filter element 132 is provided in the size of the substantially whole filtration chamber except the outflow port 14, the inflow port 15, and its periphery. For this reason, the shape of the filter element 132 is such that the length of folding in the middle is shortened so that the outlet 14 and the inlet 15 and their periphery can be removed. The vicinity of the inflow port 15 has a constricted shape.
The filter element 11 is made of nonwoven fabric and has laser transparency.

Such an oil filter 1B is manufactured by joining the case members 11 and 12 and the filter element portion 13B by laser welding the butted portions of the case members 11 and 12.
Specifically, each case member 11 is subjected to an external force with the edge of the filter element 132 sandwiched between the butted end 111 of one case member 11 and the butted end 121 of the other case member 12. , 12 are pressed in the butting direction. At this time, the edge of the filter element 132 is in a low density state. In this pressurized state, laser light is irradiated from the side toward the outer surface of the filter element 132 and the outer surface on the front end side of the butted end portion 121 of the other case member 12.
The front end side outer surface portion of the butt end portion 121 of the other case member 12 having laser absorption is melted by the laser light irradiation. Since the melted portion has a predetermined melt depth in the laser light irradiation direction (a direction orthogonal to the butting direction), a part of the melted portion of the filter element 132 is in contact with the melted portion and the filter element 132. Intrusion into the constituent fibers, or heat generated in the melting portion is transmitted to the filter element 132, and the constituent fibers of the filter element 132 are partially melted. Thereafter, the laser beam irradiation is stopped and the melted portion is cooled, whereby the welding of the other case member 12 and the filter element 132 is completed.
The oil filter 1B obtained by irradiating the laser beam has a filter element welded portion 139 formed by the laser beam on the outer surface side of the contact portion between the butted end 121 of the other case member 12 and the filter element 132. Yes.

  Such an oil filter 1B can be provided with the filter element 132 that occupies a larger volume and has a larger filtration area even in the filtration chamber of the same size as the filter element 131 of the first embodiment. It can be made thin while maintaining the necessary filtration flow rate. Moreover, since there is no filter element support member, a smaller oil filter can be produced. Furthermore, since the case members 11 and 12 and the filter element 132 are joined by laser welding, it is possible to weld more firmly.

The oil filter 1C of the third embodiment is an oil filter for an automatic transmission in which a filter element that is a honeycomb filter is provided in a filtration chamber. As shown in FIG. 7, case members 11 and 12 and a filter element portion 13C. And comprising.
As in the second embodiment, the case member 11 and the case member 12 are made of a synthetic resin material in which one case member 11 contains a dye, and the other case member 12 contains a pigment such as carbon black. Made of synthetic resin material.
Further, the filter element portion 13C is formed from a filter element 133 that is a honeycomb filter in which filter paper sheets having a corrugated cross section and flat filter paper sheets are alternately laminated, and openings formed on end faces are alternately sealed. Become. Further, the filter element 133 is disposed in a filtration chamber 16 formed by abutting the case members 11 and 12, and is fixed by fitting into a groove provided in the case members 11 and 12. Further, the filter element 133 and its opening are arranged so that one is located on the case member 11 side and the other is located on the case member 12 side. Further, the length of the filter element 133 in the direction from the dusty portion 16a to the clean portion 16b is longer than the height of the filter element 133, like the filter elements 131 and 132 of the first and second embodiments.
Such an oil filter 1C is manufactured by joining the case members 11 and 12 and the filter element portion 13C by laser welding the butted portions of the case members 11 and 12, as in the second embodiment.

  The oil filter 1C is a filter element 133 that is a honeycomb filter that occupies a larger volume and has a larger filtration area even in a flat filtration chamber, like the oil filters 1A and 1B of the first and second embodiments. Therefore, it is possible to reduce the thickness while maintaining a necessary filtration flow rate. Moreover, since it does not have a filter element support member like Example 2, a smaller oil filter can be produced. Furthermore, since the case members 11 and 12 and the filter element 133 are joined by laser welding, it is possible to weld more firmly.

The oil filter 1D of the fourth embodiment is an oil filter for an automatic transmission in which a porous filter element is provided in a filtration chamber. As shown in FIG. 8, case members 11 and 12 and a filter element portion 13D. And comprising.
As in the second and third embodiments, the case member 11 and the case member 12 are made of a synthetic resin material in which one case member 11 contains a dye, and the other case member 12 contains a pigment such as carbon black. Made of synthetic resin material.
The filter element portion 13D includes a filter element 134 made of a porous body. The filter element 134 is disposed in the filtration chamber 16 formed by abutting the case members 11 and 12, and is fixed by being fitted into a groove provided in the case members 11 and 12. Further, the length L of the filter element 134 is longer than the height of the filter element 134 as in the case of the filter elements 131, 132, and 133 of the first to third embodiments.
Such an oil filter 1D is manufactured by joining the case members 11 and 12 and the filter element portion 13D by laser welding the butted portions of the case members 11 and 12, as in the second and third embodiments. The

  The oil filter 1D includes a sponge-like filter element 134 that occupies a larger volume and has a larger filtration area even in a flat filtration chamber, like the oil filters 1A to 1C of the first to third embodiments. Therefore, it is possible to reduce the thickness while maintaining a necessary filtration flow rate. Moreover, since it does not have a filter element support member like Example 2 and 3, a smaller-sized oil filter can be produced. Furthermore, since the case members 11 and 12 and the filter element 134 are joined by laser welding, it is possible to weld more firmly.

In the present invention, the present invention is not limited to the above embodiment, and various modifications can be made within the scope of the present invention depending on the purpose and application. That is, the shape of the case member is a case member 11 that is a rectangular parallelepiped in which one side surface illustrated in FIGS. 1 to 4 is opened as an end for abutting and the length of the side in the height direction is shorter than the other sides. It is not limited to 12. As an example of this, as shown in FIG. 9, case members 11 </ b> A and 12 </ b> A that are dish-shaped rectangular parallelepipeds whose top surface or bottom surface opens as an end for matching and whose length in the height direction is shorter than the other sides. be able to.
Further, for example, in the oil filter 1D according to the fourth embodiment, as shown in FIG. 10, the filter element 134A having a cross-sectional shape of a parallelogram may be used so as to protrude to a position located on the bottom surface of the outlet 14 and the inlet 15. Good.

  It is used as a filter for filtering contaminated fluid, especially oil. In particular, it is suitably used as an oil filter for a vehicle automatic transmission.

It is a model perspective view for demonstrating the external appearance of the oil filter which concerns on the present Example 1. FIG. In the oil filter which concerns on the present Example 1, it is the model perspective cross section cut | disconnected in the horizontal direction for demonstrating the arrangement | positioning state of a filter element. It is a model perspective view for demonstrating the external appearance of one case member which comprises the oil filter which concerns on Example 1. FIG. FIG. 4 is a schematic perspective view for explaining the appearance of the other case member that constitutes the oil filter according to the first embodiment. It is the model perspective view which permeate | transmitted one part for demonstrating the external appearance of the filter element part which comprises the oil filter which concerns on Example 1, and the arrangement | positioning state of a filter element. It is the schematic cross section cut | disconnected in the horizontal direction for demonstrating the oil filter which arrange | positioned the filter element to the substantially whole inside of the filtration chamber based on the present Example 2. FIG. It is the model perspective sectional view cut | disconnected in the horizontal direction for demonstrating the oil filter which arrange | positioned the filter element using the honeycomb filter based on the present Example 3. FIG. It is the schematic cross section cut | disconnected in the horizontal direction for demonstrating the oil filter which arrange | positioned the filter element using the sponge filter based on the present Example 4. FIG. It is a disassembled schematic perspective view for demonstrating an oil filter provided with a dish-shaped case member based on another present Example. It is a schematic cross section for demonstrating the oil filter provided with the filter element which protrudes to the inflow port and outflow port side based on another this Example. It is a schematic cross section for demonstrating the conventional oil filter. It is a schematic cross section for demonstrating the filter element used for the conventional oil filter.

Explanation of symbols

1A, 1B, 1C, 1D; oil filter, 11, 12; case member, 111, 121; butt end,
13; Filter element part, 130, 131, 132, 133, 134; Filter element, 135; Filter element support member, 136, 137; Crease line, 138; Groove part, 139; Welded part, 14; Outlet, 15; Inlet, 16; filtration chamber, 16a; dusty part, 16b; clean part, 17; rib.

Claims (6)

And the case member of flat shape having an inlet and an outlet, and is disposed so as to partition the clean part of the Dusty portion and flow outlet side of the flow inlet side filter chamber in the plane direction of the case member inside the flat shape A filter element part for filtering oil flowing from the dusty part to the clean part ,
The filter element portion includes a filter element,
The filter element is disposed along a cross section in the thickness direction of the case member, and the length in the direction from the dusty portion toward the clean portion is longer than the length in the thickness direction of the case member. And
The oil filter according to claim 1, wherein the filter element is a fold-folded sheet formed by being repeatedly bent in a direction parallel to a direction from the dusty portion toward the clean portion . A flat case member having an inlet and an outlet, and a flat filtration chamber inside the case member arranged in a plane direction to be divided into a dusty part on the inlet side and a clean part on the outlet side; A filter element part for filtering oil flowing from the dusty part to the clean part,
The filter element portion includes a filter element,
The filter element is disposed along a cross section in the thickness direction of the case member, and the length in the direction from the dusty portion toward the clean portion is longer than the length in the thickness direction of the case member. And
The oil filter according to claim 1, wherein the filter element is a honeycomb filter having both ends opened in a direction parallel to a direction from the dusty portion toward the clean portion . The oil filter according to claim 1, wherein both ends of the fold in the width direction are fixed .   The oil filter according to any one of claims 1 to 3, wherein the filter element is sandwiched between the case members. The filter element portion further includes a filter element support member,
The filter element is provided on the filter element support member,
The oil filter according to any one of claims 1 to 3, wherein the filter element support member is disposed on the case member. The filter element portion is sandwiched between the abutted side surfaces of the case member,
One of the case members has laser transparency, the other of the case members has laser absorption,
The oil according to any one of claims 1 to 5, wherein an element welded portion by a laser beam is formed on an outer surface side of a contact portion between the other butted end surface of the case member and the filter element portion. filter.

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