JP2013119072A - Filter device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To overcome the problem of imperfect sealing in a seal part or the problem of the assembly difficulty of a device even if a large error has occurred in the axial direction length of a filter element.SOLUTION: This filter device includes a basic configuration wherein the filter element 51 holding a filter material 53 by a pair of resinous end plates 52 (52a, 52b) is stored in a housing 101 having opened one face, and wherein an opening face 102 thereof is closed by a set plate 201. As a structure for securing sealability by sticking the filter element 51 to the set plate 201, in place of a structure to elastically deform the end plate 52a by directly pressing the end plate 52a against a recessed inner face 103 on one closed face side of the housing 101, an O-ring 57 is interposed between the recessed inner face 103 and the end face 55a of one end plate 52a in a state where the O-ring 57 is elastically deformed, and the other end plate 52b is closely pressed to the set plate 201 by its resilience.

Description

  The present invention relates to a filter device for filtering fluid such as fuel, water, oil, and air.

  In a filter device using a cylindrical filter element, a filter element is formed by holding a filter medium in a cylindrical shape with a pair of end plates. The end plate is generally formed of a metal, for example, an iron plate, and holds the filter medium in a cylindrical shape by adhering. In the filter device, the filter element thus formed is housed in a metal housing that is open on one side, and the opening is closed by a set plate. At this time, the space on the outer peripheral side and the space on the inner peripheral side of the filter element are partitioned inside the housing. Therefore, an inflow port and an outflow port are formed in the set plate, the inflow port is connected to the space on the outer peripheral side of the filter element, and the outflow port is connected to the space on the inner peripheral side. By carrying out like this, the fluid introduce | transduced from the inflow port can be filtered with the filter medium of a filter element, and can be poured out from an outflow port.

  Due to the structure of such a filter device, an opening must be formed in the end plate on the set plate side of the pair of end plates. This is for connecting the inner peripheral surface of the filter element and the outlet. On the other hand, the other end plate must be closed. This is for partitioning the outer peripheral side space and the inner peripheral side space of the filter element.

  In order to reliably separate the space on the outer peripheral side and the space on the inner peripheral side of the filter element, it is important to seal the end plate having an opening in close contact with the set plate. Therefore, conventionally, the closed end plate is urged by a spring to increase the adhesion between the end plate on the set plate side and the set plate, so that both are reliably sealed ( Patent Document 1).

Japanese Patent Laid-Open No. 11-090117 JP 2006-175432 A

  In recent years, a filter element in which a pair of end plates that hold a filter medium in a cylindrical shape is formed of a resin has been developed (see Patent Document 2). When such a filter element is discarded, the end plate can be burned together with the filter medium. For this reason, it has advantages such as easier disposal and reduced disposal costs over traditional filter elements that use metal end plates that must be removed from the filter media. have.

  In addition to this, another advantage of the filter element using the resin end plate is that it is not required to be urged by a spring when it is incorporated in the housing. Since the resin itself is elastic, if the opening of the housing is closed with a set plate by slightly crushing the filter element, the end plate can be brought into close contact with the set plate and sealed.

  FIG. 4 shows a filter device using a filter element using a resin end plate, which was prototyped by the applicant of the present application. This is not a known prior art, but is only a prototype produced by the applicant of the present application in a secret state.

  As shown in FIG. 4, the filter element 51 holds the filter medium 53 in a cylindrical shape by a pair of resin end plates 52. In such a filter element 51, one end plate 52a is in direct contact with the inner surface of the housing 101, and the other end plate 52b is in direct contact with the set plate 201. The distance between the housing 101 and the set plate 201 that supports both ends of the filter element 51 in contact with each other is a dimension A. The dimension A is set slightly smaller than the dimension B of the axial length of the filter element 51. As a result, the filter element 51 housed in the housing 101 is compressed and elastically deformed because the pair of end plates 52 are made of resin, and maintains close contact with the set plate 201. In FIG. 4, the portion that maintains this adhesion is the seal portion S.

  The applicant of this application came across the wall of difficulty in dimensional management of the filter element 51 while making a prototype of the filter element 51 shown in FIG. That is, the filter element 51 has to have a length in the axial direction of the dimension B slightly longer than the dimension A, and this is a problem that the dimension B varies greatly. If the axial length of the filter element 51 is greatly deviated from the dimension B, it causes a problem that the seal part S is poorly sealed when it is too small, and the assembly of the device is difficult when it is too large. The applicant of this application confirmed that an error occurred in the axial length of the filter element 51 as a whole by about ± 0.5 mm in the actual trial production. The degree of this error is an error amount sufficient to cause the above problem.

  The present invention has been made in view of the above points, and overcomes the problem of poor sealing at the seal portion and the difficulty of assembly of the device even if a large error occurs in the axial length of the filter element. An object of the present invention is to obtain a filter device capable of

  The present invention includes (1) a filter element that holds a filter medium in a cylindrical shape by a pair of resin end plates, and (2) one surface side is opened and another surface side is closed to an inner concave surface, and the filter element is disposed inside (3) Projectingly formed on the end surface of one of the end plates facing the inner surface of the closed one surface side of the housing and positioned on an annular locus centering on the axis of the filter element A state in which the elastic member is elastically deformed without bringing the one end plate into contact with the inner surface of the closed one surface side of the housing, the rib and an annular elastic member disposed along the outer periphery of the rib And (4) the housing in a state of being in close contact with the other end plate located on the one surface side where the housing opens. And a set plate having a first passage that communicates with a space on the outer peripheral side of the filter element and a second passage that communicates with an inner peripheral side. Settled.

  According to the present invention, an elastic member that can be elastically deformed is interposed between the inner surface on the one closed surface side of the housing and one end plate, and the pressing force of the filter element against the set plate in the seal portion is reduced by the elasticity of the elastic member. Since it is generated by the restoring force, even if an error occurs in the axial length of the filter element, this error can be prevented from affecting the sealing performance at the seal portion and the assembly of the device. Therefore, it is possible to reliably overcome the problem of poor sealing at the seal portion and the difficulty of assembling the apparatus.

The front view of the whole apparatus which shows the left half as a longitudinal section as one Embodiment. The perspective view which looked at one end plate from the bottom. The longitudinal cross-sectional front view which expanded and showed the part of the connection channel | path formed in one end plate, and made the one end plate into a cross section in the part of a notch. The front view of the whole apparatus which made the left half into a vertical cross section which the applicant of this application made as an experiment.

  An embodiment will be described with reference to FIGS. 1 to 3. The same parts as those described in FIG. 4 are denoted by the same reference numerals.

≪Filter device structure≫
As shown in FIG. 1, the filter device 11 of the present embodiment employs a filter element 51 that holds a filter medium 53 in a cylindrical shape by a pair of resin end plates 52. In the filter device 11, the filter element 51 is housed in a housing 101 having an opening on one surface, and the opening is closed with a set plate 201, whereby the filter element 51 is firmly held inside the housing 101. The detailed structure of each part will be described below.

(1) Housing The housing 101 is integrally formed of metal as a whole, and has a cylindrical shape like a cup that opens on one side. Therefore, the opening surface 102 is provided on the one surface side to be opened, and the other surface side is closed. The other side of the closed surface has a curved surface shape, and therefore the inner surface is formed in a concave shape. In the present embodiment, the concave inner surface is referred to as a concave inner surface 103. The concave inner surface 103 is formed in a curved surface shape in which the portion through which the axis of the housing 101 passes is most depressed, and all the positions are 360 degrees equally symmetrical about this position.

(2) Filter element In the filter element 51, of the pair of end plates 52, the end plate 52a is located on the concave inner surface 103 side of the housing 101, and the end plate 52b is located on the opening surface 102 side. . One end plate 52a has a disk shape without holes, and the other end plate 52b has a disk shape with holes. Here, the hole formed in the end plate 52 b is referred to as a communication hole 54.

  As shown in FIG. 2, the end plate 52 a has three ribs 56 protruding from an end surface 55 a facing the concave inner surface 103 of the housing 101. These ribs 56 are arranged on an annular locus centering on the axis of the filter element 51. As shown in FIGS. 1 and 3, an O-ring 57 as an annular elastic member is disposed along the rib 56 on the outer peripheral surface side of the rib 56. The O-ring 57 is of a conventional structure such as rubber or resin and is elastically deformed when pressed. Such an O-ring 57 is in close contact with the concave inner surface 103 of the housing 101 and plays a role in preventing the end plate 52 a from contacting the concave inner surface 103. In the present embodiment, such a structure including the rib 56 and the O-ring 57 is referred to as a support structure 58. The support structure 58 will be described in more detail later.

  As shown in FIG. 1, the end plate 52 b forms a sealing projection 59 that rises from the communication hole 54. The sealing projection 59 is formed in an annular shape along the communication hole 54. Both the communication hole 54 and the sealing projection 59 formed in the end plate 52 b are arranged on a circumference centering on the axis of the filter element 51.

(3) Set plate The set plate 201 is formed by integrally fixing two metal members. One of these two members is an outer ring plate 202 in which a flat plate member is formed in an annular shape. The outer ring plate 202 is fixed by caulking a rubber seal packing 203 similarly formed in an annular shape. The other of the two members is a base plate 204 in which a flat plate member is formed in an annular shape. The base plate 204 is fixed to the lower surface of the outer ring plate 202 by welding. The edge portion on the inner peripheral side of such a base plate 204 is bent toward the inside of the housing 101 to form an annular connection portion 205 connected to the filter element 51. The set plate 201 thus formed is fixed to the housing 101 by caulking the edge of the opening surface 102 of the housing 101 with the outer ring plate 202.

  A base plate 204 which is a part of the set plate 201 is in close contact with an end plate 52 b included in the filter element 51. That is, the sealing projection 59 formed on the end plate 52 b and the connection portion 205 of the base plate 204 are fitted, and the tip of the sealing projection 59 is in close contact with the base plate 204. This close contact portion is the seal portion S. By forming the seal portion S, the internal space of the housing 101 is separated with the filter medium 53 interposed between the outer peripheral space OS on the outer peripheral side of the filter element 51 and the inner peripheral space IS on the inner peripheral side. Therefore, the base plate 204 forms a plurality of inlets 206 (first passages) on the outer peripheral side with respect to the seal part S, and forms holes on the inner peripheral side of the seal part S with the outlet 207 (second passage). Aisle). The inflow port 206 communicates with the outer peripheral space OS, and the outflow port 207 communicates with the inner peripheral space IS.

(4) Support Structure Here, the support structure 58 provided on the end plate 52a side of the filter element 51 will be described in more detail.

  The end plate 52 a forms a communication passage 60 in the rib 56 and the O-ring 57, which connects the outer space and the inner space of the O-ring 57. As described above, the three ribs 56 are arranged on an annular locus centering on the axis of the filter element 51. Accordingly, these ribs 56 are divided into three parts by the notches 61 provided at three places, from another viewpoint. The communication passage 60 is formed using these notches 61.

  That is, as shown in FIGS. 2 and 3, the end surface 55a of the end plate 52a from which the rib 56 projects is formed with the entire inner peripheral portion IPP of the rib 56 surrounded by the three ribs 56 and the three of these three pieces. The outer peripheral portion OPP of the rib 56 connected to the rib 56 is positioned in the same plane P. On the other hand, a region excluding the outer peripheral portion OPP extending from the vicinity of the outer periphery of the end plate 52a to the three notches 61 is a step portion 62 that is formed in a concave shape and is one step lower than the plane P. . For this reason, as shown in FIG. 3, a gap is formed between the end surface 55 a of the end plate 52 a and the O-ring 57 in the stepped portion 62. The step portion 62 forming this gap reaches the inner periphery of the three ribs 56. Thereby, in the part of the notch 61, the outer peripheral side and inner peripheral side of the O-ring 57 communicate with each other, and the communication passage 60 is formed.

  Further, in the present embodiment, the inner diameter of the O-ring 57 and the outer diameter of the rib 56 are made to coincide. This means that the inner diameter of the O-ring 57 is not made smaller than the outer diameter of the rib 56, and the inner diameter of the O-ring 57 is not made larger than the outer diameter of the rib 56.

≪Filter device manufacturing method≫
(1) First Step To manufacture the filter device 11, first, the filter element 51 is installed with the end plate 52a facing upward.

(2) Second Step Next, an O-ring 57 is placed around the rib 56 formed on the end plate 52a.

(3) Third Step Next, the filter element 51 is covered with the housing 101. At this time, the O-ring 57 is in close contact with the concave inner surface 103 inside the housing 101.

(4) Fourth Step Next, the housing 101 is turned over together with the filter element 51. At this time, care is taken so that the filter element 51 does not leave the housing 101.

(5) Fifth Step Finally, the set plate 201 is fixed to the opening surface 102 of the housing 101 and the opening surface 102 is closed. The set plate 201 is fixed by caulking the edge of the opening surface 102 of the housing 101 with the outer ring plate 202 of the set plate 201 as described above. Thus, the filter device 11 is completed.

  In the completed filter device 11, the connection portion 205 of the base plate 204 fits into the sealing projection 59 formed on the end plate 52b. In this state, the O-ring 57 is compressed and elastically deformed. The elastically deformed O-ring 57 generates a restoring force. The restoring force of the O-ring 57 is a pressing force that brings the tip of the sealing projection 59 into close contact with the base plate 204. As a result, the filter element 51 comes into close contact with the set plate 201 and the seal portion S is formed.

≪Function and effect of filter device≫
(1) Action of Filter Device In such a configuration, the filter device 11 introduces a fluid to be filtered from the inlets 206 formed in the set plate 201. The fluid flowing in from the inflow port 206 is guided to the outer peripheral space OS, and then flows into the inner peripheral space IS through the filter medium 53. At this time, the fluid is filtered by the passage of the filter medium 53. The filtered fluid guided to the inner circumferential space IS flows out from the communication hole 54 formed in the end plate 52 b and the outlet 207 formed in the set plate 201. In such a filtration process, the seal portion S maintains the adhesion between the filter element 51 and the set plate 201, so that the outer peripheral space OS and the inner peripheral space IS are reliably separated.

  One of the outstanding points in the filter device 11 of the present embodiment is how to use the O-ring 57. The O-ring 57 is generally used as a seal member. In contrast, in the present embodiment, the O-ring 57 is not used as a seal member, and instead, two different functions provided in the O-ring 57 are utilized.

  The first function utilized is the elastic deformation function of the O-ring 57. In the present embodiment, this elastic deformation function is utilized to absorb the dimensional error in the axial direction of the filter element 51 that inevitably occurs.

  Another function that is utilized is a restoration function that accompanies elastic deformation of the O-ring 57. In the present embodiment, the filter element 51 is brought into close contact with the set plate 201 by using this restoration function, and the seal portion S is well formed.

(2) Basic Effect of Filter Device In FIG. 1, dimension B is the axial length of the filter element 51. As described above, with respect to the dimension B, an error of about ± 0.5 mm occurs in the entire filter element 51. In the case of the filter device shown in FIG. 4, the pair of end plates 52 (52a, 52b) are brought into direct contact with the housing 101 and the set plate 201, and the sealing performance at the seal portion S is set to the pair of end plates 52 (52a, 52b). It depends on the elastic restoring force. Therefore, the dimension B is within a specified error range with respect to the length dimension A (see FIG. 4) of the contact portion between the pair of end plates 52 (52a, 52b) between the housing 101 and the set plate 201. Must be. However, the actual error range of about ± 0.5 mm deviates from the specified error range. This problem is described in detail in the section “Problems to be Solved by the Invention”, so please refer to it.

  In the filter device 11 of the present embodiment, an elastically deformable O-ring 57 is interposed between the concave inner surface 103 inside the housing 101 and one end plate 52a, and the filter element 51 with respect to the set plate 201 in the seal portion S. Is generated by the elastic restoring force of the O-ring 57. For this reason, one end plate 52a does not need to be in contact with the concave inner surface 103 and is not in contact therewith either. Therefore, if it is said slightly or abstractly, the concept of the dimension A that should be the basis of the dimension B does not occur in the first place. More specifically, even if an error occurs in the dimension B of the axial length of the filter element 51, for example, an error of about ± 0.5 mm, the error is caused by the sealing performance in the seal portion S or the device. This will not affect the assembly of the product. Therefore, according to the present embodiment, it is possible to reliably overcome the problem of poor sealing at the seal portion S and the problem of difficulty in assembling the apparatus.

(3) Role played by the communication path In the filter device 11 of the present embodiment, the communication path 60 is provided in one end plate 52a. The communication passage 60 plays a role of connecting the outer peripheral space and the inner peripheral space of the O-ring 57 inside the outer peripheral space OS. For this reason, the fluid that has flowed into the outer peripheral space OS from the plurality of inlets 206 flows from the outer peripheral side of the O-ring 57 to the inner peripheral side through the communication passage 60 and reaches the entire outer peripheral space OS. In FIG. 3, the flow of the fluid at this time is indicated by arrows.
As a result, no air pool is formed on the inner peripheral side of the O-ring 57, so that the pressure in the outer peripheral space OS tends to become more uniform, and the damage to the rib 56 expected to occur due to the pressure difference or the O-ring 57 It is possible to reliably prevent inconveniences such as misalignment.

  In the present embodiment, the communication passage 60 that provides such an excellent effect is realized by a simple structure such as the notch 61 and the stepped portion 62. In short, when the filter element 51 is manufactured, the notch 61 and the stepped portion 62 can be easily molded by a resin pouring or injection molding procedure for molding the end plate 52a. is there. In addition, since the ribs 56 that are required to be molded with respect to the end plate 52a and the mold release direction are the same, there is no need to devise such as nesting.

(4) Special Effects Related to O-ring In the present embodiment, the inner diameter of the O-ring 57 and the outer diameter of the rib 56 are matched. Thereby, elastic deformation of the O-ring 57 due to mounting on the rib 56 can be prevented. As a result, the restoring force generated by the elastic deformation of the O-ring 57 can be converted into a pressing force that causes the filter element 51 to be in close contact with the set plate 201 more efficiently.

  However, the effect of preventing the elastic deformation of the O-ring 57 by being attached to the rib 56 is that the inner diameter of the O-ring 57 is not the same as the inner diameter of the O-ring 57 and the outer diameter of the rib 56. It can be said that the effect is generated because it is not smaller than the outer diameter of the rib 56. In this sense, the inner diameter of the O-ring 57 and the outer diameter of the rib 56 do not have to be completely coincident with each other, and the inner diameter of the O-ring 57 is set slightly larger than the outer diameter of the rib 56. There may be.

  In addition, if it is assumed that the O-ring 57 is elastically deformed by being attached to the rib 56, the inner diameter of the O-ring 57 may be set smaller than the outer diameter of the rib 56. Thus, the operational effects of the filter device 11 of the present embodiment are not completely destroyed.

  The present embodiment has been described above. Needless to say, various modifications and changes are allowed in implementation. For example, in the present embodiment, the O-ring 57 is merely employed as one mode for realizing an annular elastic member. As long as an annular elastic member can be realized, not only the O-ring 57 but also various deformations and changes such as a rubber member having a rectangular cross section are allowed.

51 Filter element 52 End plate 52a End plate (one end plate)
52b End plate (the other end plate)
53 Filter medium 55a End face 56 Rib 57 O-ring (elastic member)
58 support structure 60 communication passage 61 notch 62 step portion 101 housing 103 concave inner surface (inner surface)
201 Set plate 206 Inlet (first passage)
207 Outlet (second passage)

Claims (5)

A filter element that holds the filter medium in a cylindrical shape by a pair of resin end plates;
A housing in which one surface side is opened and another one surface side is closed into an inner concave shape, and the filter element is accommodated therein;
A rib projecting from an end face of one of the end plates facing the inner surface of the one closed surface of the housing and positioned on an annular locus centering on the axis of the filter element; and along an outer periphery of the rib A support structure for closely contacting the elastic member in an elastically deformed state without bringing the one end plate into contact with the inner surface of the closed one surface side of the housing,
A first passage and an inner peripheral side that closes the one open surface of the housing in close contact with the other end plate located on the one open surface side of the housing and communicates with a space on the outer peripheral side of the filter element; A set plate having a second passage communicating with the
A filter device comprising:   The said one end plate is provided with the connection channel | path which connects the space of the outer peripheral side of this elastic member, and the space of an inner peripheral side to the said rib and the part of the said elastic member. Filter device. The communication passage is
A notch for dividing the rib into a plurality of pieces,
In the end face of the one end plate, a stepped portion that is formed in a concave shape and reaches the notch,
The filter device according to claim 2, wherein the filter device is formed by:   5. The filter device according to claim 1, wherein an inner diameter of the elastic member is matched with an outer diameter of the rib.   The filter device according to any one of claims 1 to 5, wherein an O-ring is used as the elastic member.

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