JP4932794B2 - Filter unit - Google Patents

Description

  The present invention relates to a filter unit that removes foreign matters in a fluid and a filter device including the filter unit. For example, the present invention relates to a filter unit and a filter device that remove foreign matters in water supplied to a shower toilet.

  A device to which a fluid is supplied or a device from which a fluid is discharged is usually provided with a filter device that removes foreign matters in the fluid. As such a filter device, a cylindrical filter attached in a pipe may be used. In this cylindrical filter, the form in which the water flow direction is from the outside to the inside of the cylinder (for example, see Patent Document 1) and the form in which the water flow direction is from the inside to the outside of the cylinder (for example, Patent Document 2) See).

  Patent Document 1 includes a filter case that includes a cylindrical body having an inflow port through which a fluid flows, an outlet port through which the fluid flows out is formed on the rear end surface of the cylindrical body, and the filter case. In addition, there is a cylindrical internal passage having an open rear end surface, and a filter body for filtering impurities is formed on the peripheral surface, and the diameter is increased so as to have a stepped portion on the inner peripheral surface of the filter case. In addition, an enlarged diameter portion having an open end face is provided at the front portion of the filter case, and a removable cap that closes the enlarged diameter portion, and an annular packing made of an elastic body that faces the wall surface of the stepped portion, A filter device comprising the same is disclosed. The filter body is in intimate contact with the periphery of the outflow port, and when the cap is attached, the projecting portion protruding in the radial direction from the circumferential surface of the filter body is pressed against the wall surface of the step portion with the packing interposed therebetween, and at the same time, the filter body flows. It is designed to be pressed around the exit.

  Patent Document 2 discloses a sanitary washing apparatus that includes a strainer for performing local cleaning with water supplied from tap water or the like and removing foreign matter in the water. The shape of the strainer is a cylindrical shape and can be divided in the direction of the cylindrical axis during cleaning, and the direction of water supply to the strainer is from the inside to the outside.

JP 2001-321596 A JP 2000-129762 A

  The following analysis is given from the perspective of the present invention.

  In a filter in which the water flow direction is from the outside to the inside of the cylindrical filter as described in Patent Document 1, foreign matter such as dust adheres to the outer surface of the cylindrical body. May end up.

  On the other hand, in a filter in which the water flow direction is from the inner side to the outer side of the cylindrical filter, there is no fear of foreign matter falling off. However, in the sanitary washing device described in Patent Document 2, an open end serving as an inflow port is provided on the bottom surface on the upstream side of the cylindrical strainer, and the strainer is pulled out from the downstream side. Therefore, when the strainer is pulled out, There is a risk that a large amount of dust may spill from the open end, and water remaining in the strainer may flow out from the open end into the pipe together with the dust.

  Further, in the sanitary washing device described in Patent Document 2, since the cap and the strainer are formed separately, a cap attaching / detaching operation and a strainer attaching / detaching operation are separately required. In particular, when the strainer is installed in a narrow work space, it is desired that the strainer can be attached and detached by a single operation.

  An object of the present invention is to provide a filter unit and a filter device that prevent foreign matters from dropping or remaining in a pipe and that are excellent in handling.

According to a first aspect of the present invention, a tubular strainer having a filter for removing foreign matter in the fluid, and a cap removably attached to the strainer, filter unit Ru provided with is provided. Cap, with detachably attached to the casing, that having a least one opening leading to the inside of the strainer when attached to the strainer. One of the strainer and the cap has an annular female connector portion for connection with the other, and the other has an annular male connector portion for connection with the other. The strainer and the cap can be attached to and detached from the casing as a unit by connecting the female connector portion and the male connector portion. The male connector portion has a protruding edge portion extending in the circumferential direction on the end surface on the female connector portion side and protruding in the female connector portion direction. The female connector portion has a first groove portion for fitting with the protruding edge portion. At least one of the outer peripheral side surface and the inner peripheral side surface of the first groove portion has a tapered surface at least in part with respect to the axial direction so that the projecting edge portion contacts. The projecting edge portion and the first groove portion are closely fitted. The fluid flows into the inside of the strainer from the opening , passes through the filter, and flows out from the inside of the strainer to the outside.

  According to the preferable form of the said 1st viewpoint, a protrusion part deform | transforms along the taper surface of a 1st groove part, when a male connector and a female connector are connected.

  According to the preferable form of the first viewpoint, the projecting edge portion extends along the outer peripheral surface of the male connector portion. The first groove has a tapered surface on the inner peripheral side surface. The end surface of the male connector portion and the upper surface on the inner peripheral side surface side of the first groove portion abut.

  According to the preferable form of the first viewpoint, the male connector portion has at least one convex portion. The female connector portion has at least one concave portion or second groove portion that engages with the convex portion.

  According to the preferable form of the first viewpoint, the male connector portion has at least one convex portion. The female connector portion has at least one second groove portion that engages with the convex portion. The second groove portion has an open end for inserting and removing the convex portion into and from the second groove portion at the end of the female connector portion, communicates with the longitudinal groove extending in the axial direction and the longitudinal groove, and extends in the circumferential direction. The horizontal groove which exists, and at least one part which faces a horizontal groove have a latching part which protrudes with respect to a horizontal groove and prevents the protrusion of a convex part. The convex portion is configured such that one of the male connector and the female connector is rotated with respect to the other, and a predetermined force is applied to the latching portion by the convex portion, whereby the width of the lateral groove in which the latching portion is formed is temporarily It is inserted into and removed from the lateral groove by expanding to.

  According to a preferred form of the first aspect, the strainer has a cylindrical filter part for capturing foreign matter in the fluid, and a female connector part joined so that the filter part and the inside are electrically connected. The dimension of the filter part perpendicular to the axial direction is smaller than the dimension of the female connector part perpendicular to the axial direction, and a step in the circumferential direction of the strainer is caused by the outer surface of the female connector part and the outer surface of the filter part. The 1st step part which extends is formed.

  According to the preferable form of the first viewpoint, the opening is formed in the male connector portion. When the male connector portion and the female connector portion are connected, at least a portion is exposed from the female connector portion.

  According to the preferred form of the first aspect, the dimension of the male connector portion perpendicular to the axial direction in the portion where the opening is formed is smaller than the dimension of the female connector portion perpendicular to the axial direction.

  The present invention has at least one of the following effects.

  According to the present invention, the fluid can be circulated from the inside to the outside of the strainer, and since there is no opening on the strainer side, the filter unit can be removed without dropping the filtered foreign matter into the casing.

  According to the connection form of the strainer and the cap in the present invention, the strainer and the cap can be easily attached and detached with a simple structure, and the filter unit can be handled as a unit. Further, it is possible to prevent the strainer from being detached from the casing when the filter unit is removed.

  According to the form of the contact portion between the strainer and the cap in the present invention, it is possible to prevent leakage of fluid from the contact portion between the strainer and the cap with a simple configuration without using an O-ring or the like. Therefore, the number of parts can be reduced. Further, the size and shape of the abutting portion do not need to be formed with high accuracy, and the fabrication is easy and inexpensive.

  According to the filter device of the present invention, even when the fluid is circulated from the inside to the outside of the strainer, mixing of the fluid before filtration and the fluid after filtration, in particular, contamination of the fluid after filtration is prevented with a simple configuration. Can do.

  An embodiment of the filter unit of the present invention will be described. FIG. 1 shows a schematic perspective view of an embodiment of the filter unit of the present invention. The filter unit 1 removes foreign substances in the fluid and is detachably attached to the fluid flow path from the outside. The filter unit 1 includes a cylindrical strainer 2 that captures foreign matter in the fluid, and a cap 3 that is detachably attached to the strainer 2. FIG. 1 shows a state where the strainer 2 and the cap 3 are not connected.

  The strainer 2 includes a filter part 21 for filtering fluid and a female connector part 22 for attaching the cap 3. The filter unit 21 is a cup-shaped cylindrical body with one bottom surface serving as the first opening 21a, and a filter for capturing foreign matter on at least a part of at least one of the side surface and the other bottom surface of the cylindrical body. 21b is formed. That is, the fluid that has flowed in from the first opening 21a cannot move outside the strainer 2 unless it passes through the filter 21b. The material of the filter 21b and the size of the eyes are appropriately set according to the properties of the fluid and the foreign matter in the fluid. The outer dimension of the filter part 21 perpendicular to the axial direction (the outer diameter of the filter part 21 in FIG. 1) d1 is the inner dimension perpendicular to the axial direction of the casing (or pipe) to which the filter unit 1 is attached ( For example, it is smaller (thinner) than the inner diameter). Thereby, the filtered fluid can be distribute | circulated between the filter part 21 and a casing.

  The female connector portion 22 is a cylindrical body (annular body), and is joined to the filter portion 21 so that the inside thereof is electrically connected to the inside of the filter portion 21. In particular, the filter portion 21 and the female connector portion 22 are preferably joined coaxially (concentrically). The outer dimension (outer diameter of the female connector part 22 in FIG. 1) d2 of the female connector part 22 perpendicular to the axial direction is larger (thicker) than the outer dimension d1 of the filter part 21. As a result, a shift occurs between the side surface of the filter portion 21 and the side surface of the female connector portion 22, and a step is formed. That is, the first step 22 a is formed along the circumferential direction of the strainer 2 due to the difference between the outer dimension d 1 of the filter part 21 and the outer dimension d 2 of the female connector part 22. The first step portion 22a can be a stopper or positioning means that prevents the strainer 2 from entering the back of the casing by engaging with a step or protrusion formed on the inner surface of the casing. Moreover, mixing of the fluid before filtration and the fluid after filtration can be prevented by the contact between the first step portion 22a and the step or protrusion on the inner surface of the casing. That is, the female connector portion 22 is a stopper that prevents the pre-filtration fluid supplied to the cap 3 side from being mixed into the post-filtration fluid on the filter portion 21 side and the post-filtration fluid from being mixed into the pre-filtration fluid. Also serves as a (plug). Further, the outer dimension d2 and outer shape of the female connector part 22 are the inner dimension and inner shape of the casing into which the strainer 2 is inserted so that fluid does not flow as much as possible between the outer surface of the female connector part 22 and the inner surface of the casing. It is preferable to form so as to match.

  The cap 3 includes a cylindrical male connector portion 31 for connecting to the female connector portion 22 of the strainer 2 and a plug portion 32 for attaching the filter unit 1 to the casing. The male connector portion 31 has at least one second opening 33 that is electrically connected to the inside of the male connector portion 31. The second opening 33 is formed such that at least a part of the second opening 33 is exposed from the female connector portion 22 when the male connector portion 31 and the female connector portion 22 are connected. The pre-filtration fluid is supplied to the second opening 33, and the pre-filtration fluid flows from the second opening 33, passes through the male connector portion 31, and is guided to the inside of the filter portion 21.

  The outer dimension d3 of the male connector part 31 in the direction perpendicular to the axial direction (the outer diameter of the male connector part 31 in FIG. 1) d3 is smaller (thinner) than the outer dimension d2 of the female connector part 22, and the male connector It is formed so that at least a part of the portion 31 can be inserted into the female connector portion 22. In addition, by making the outer dimension d3 of the male connector part 31 smaller than the outer dimension d2 of the female connector part 22, when a plurality of the second openings 33 are formed in the male connector part 31, the fluid before filtration from one direction Is supplied, the pre-filtration fluid can flow in the circumferential direction between the male connector portion 31 exposed from the female connector portion 22 and the casing. Can be introduced.

  Moreover, it is preferable that the plug portion 32 is formed with a screw thread that is screwed with a screw thread of the casing so that the filter unit 1 can be screwed onto the casing (the screw thread not shown in FIG. 1). ). In addition, the cap 3 is provided with an O-ring or packing on the side of the plug 32 so that fluid does not leak from the plug 32, and the O-ring or packing is mounted. (The O-ring is not shown in FIG. 1). For example, the plug portion 32 can be formed like a water stop cock with respect to the casing.

  It is preferable that the female connector portion 22 and the male connector portion 31 include at least one connecting portion that connects the strainer 2 and the cap 3 so as to be integrally handled as the filter unit 1. By providing the connecting portion, the strainer 2 and the cap 3 can be handled integrally when the filter unit 1 is attached to and detached from the casing (or pipe). For example, when removing the filter unit 1 from the casing, it is possible to prevent the strainer 2 from being left in the casing.

  As a connection part, the form which forms a convex part in one side among the female connector part 22 and the male connector part 31, forms a recessed part thru | or a groove part in the other, and can fit a convex part and a recessed part can be employ | adopted, for example. . In the form shown in FIG. 1, a convex portion 35 is formed on the male connector portion 31 of the cap 3, and a second groove portion 23 that fits the convex portion 35 is formed on the female connector portion 22 of the strainer 2. The second groove portion 23 has an open end for inserting / removing the convex portion 35 into / from the second groove portion 23 at the end portion of the female connector portion 22, and a vertical groove 23 a (a horizontally long elliptical portion) extending in the axial direction of the strainer 2. ) And a horizontal groove 23b (vertically long oval portion) that communicates with the vertical groove 23a and extends in the direction around the axis, and is formed into an L shape or a letter shape by the vertical groove 23a and the horizontal groove 23b.

  In addition, it is preferable that the female connector portion 22 that forms the second groove portion 23 is formed with a latching portion 24a for preventing the convex portion 35 from coming off. The latching part 24a can be formed as a part of the snap fit part 24, for example. In the form shown in FIG. 1, the snap fit portion 24 is formed by a member on the end face side that forms the lateral groove 23b. In this case, the snap fit portion 24 is formed in a protruding piece shape by the vertical groove 23a and the horizontal groove 24b, and the distal end side can be displaced so as to change the width of the horizontal groove 24b. The latching part 24a is formed in at least a part facing the lateral groove 23b and protrudes from the lateral groove 23b. Preferably, the latching part 24a is formed on the end face side of the female connector part 22 in the lateral groove 23b. The width of the lateral groove 23b is less than the width of the convex portion 35 by the latching portion 24a. In this case, when a predetermined force is applied to the latching portion 24a by the convex portion 35, the snap fit portion 24 opens to the male connector portion 31 side, and when the convex portion 35 passes through the latching portion 24a, the width of the lateral groove 23b. Is temporarily extended. Thereby, the convex part 35 can be inserted / removed to / from the lateral groove 23b. After the convex part 35 passes, the width of the lateral groove 23b in the latching part 24a returns to the original width.

  In FIG. 2, the schematic perspective view of the filter unit 1 after connecting the strainer 2 and the cap 3 is shown. When connecting the strainer 2 and the cap 3, first, the male connector portion 31 and the female connector portion 22 are fitted in the axial direction by being inserted into the vertical groove 23 a from the open end. When the convex portion 35 reaches the lateral groove 23b, one is rotated around the axis with respect to the other. At this time, when the force to rotate is weak, the convex portion 35 is latched by the latching portion 24a and cannot be moved to the back of the lateral groove 23b, but when it is rotated with a predetermined force or more. When the horizontal groove 23b is pushed and expanded by the convex portion 35 and further rotated around the axis, the convex portion 35 can be introduced deeper than the latching portion 24a. Thereby, the strainer 2 and the cap 3 can be connected and handled integrally.

  When removing the strainer 2 and the cap 3, the convex portion 35 is rotated about the axis along the lateral groove 23b. If the convex part 35 is latched by the latching part 24a, a predetermined force will be applied to the latching part 24a, the snap fitting part 24 will be opened, and the convex part 35 will be extracted from the horizontal groove 23b. Then, the strainer 2 and the cap 3 are pulled apart in the axial direction so as to remove the convex portion 35 from the open end of the vertical groove 23a.

  At least the snap fit portion 24 is preferably formed of an elastic material so that the tip can be displaced when a predetermined force is applied, and is preferably formed of a resin, for example. It is preferable that the convex portion 35 and the latching portion 24a have a shape that allows the snap-fit portion 24 to be easily opened when they are engaged and force is applied. For example, it is preferable that the portion where the convex portion 35 and the latching portion 24a abut is curved. In FIG. 1, the convex part 35 is circular, and the latching part 24a is semicircular.

  Further, when the cap 3 is screwed to the casing, the rotation direction when the cap 3 is removed from the casing is opposite to the rotation direction for removing the convex portion 35 from the lateral groove 23b. The rotation direction when removing the cap 3 from the casing is preferably the direction in which the convex portion 35 is hooked on the hook portion 24a. When the direction is the same, foreign matter may be caught between the filter unit 1 and the casing, and thus the strainer 2 may come off when the filter unit 1 is removed from the casing. Therefore, in the reverse direction, when removing the filter unit 1 from the casing, even if the filter unit 1 is rotated about its axis, the convex portion 35 does not move in the direction of coming out of the lateral groove 23b. It is possible to prevent the strainer 2 from being disconnected and the strainer 2 being left in the casing.

  Thereby, for example, when the filter unit 1 is applied to a shower device of a shower toilet, the cap 3 and the strainer 2 are attached / detached only with the force of a fingertip without using a tool (and without requiring a large force). be able to.

  Next, the fluid leakage prevention configuration at the contact portion between the strainer 2 and the cap 3 will be described. In the filter unit 1, the fluid flows from the second opening 33 formed in the cap 3 and moves to the strainer 2 through the inside of the cap 3, so that the fluid does not leak from the contact portion between the cap 3 and the strainer 2. A configuration is preferable. In particular, it is preferable that fluid leakage can be prevented without using another member such as an O-ring or packing.

  Here, a configuration for preventing fluid leakage from between the cap 3 and the strainer 2 without using an O-ring or packing will be described. FIG. 3 shows a schematic partial cross-sectional view of the female connector portion 22 and the male connector portion 31 before the strainer 2 and the cap 3 are connected. 4 and 5 are schematic partial cross-sectional views of the contact portion between the strainer 2 and the cap 3. FIG. 4 shows a state before the strainer 2 and the cap 3 are connected, and FIG. 5 shows a state after the strainer 2 and the cap 3 are connected. On the end surface 31b of the cap 3 (male connector portion 31) on the side to be inserted into the strainer 2, a protruding edge portion 38 is formed that protrudes over the entire periphery of the end surface. The protruding edge portion 38 is preferably formed along the outer peripheral surface 31 a of the male connector portion 31.

  On the other hand, in the strainer 2, a first groove portion 25 for inserting the protruding edge portion 38 extends along the inner periphery of the strainer 2. At least one of the inner peripheral side surface 25 a and the outer peripheral side surface 25 b forming the first groove portion 25 has a tapered surface that is inclined with respect to the axial direction of the strainer 2. For example, in the form shown in FIGS. 3 to 5, the inner peripheral side surface 25 a is inclined in the diameter increasing direction from the female connector portion 22 toward the filter portion 21. The entire inner peripheral side surface 25a is a tapered surface, but the tapered surface may be formed on a part of the inner peripheral side surface 25a or the outer peripheral side surface 25b. The contact surface of the projecting edge portion 38 may also be tapered.

  When the male connector part 31 and the female connector part 22 are fitted together, the projecting edge part 38 and the first groove part 25 come into contact with the inclined side surface of the first groove part 25 when the male connector part 31 and the female connector part 22 are fitted. To form. In the case of the form shown in FIGS. 4 and 5, the tip of the projecting edge portion 38 is in contact with the inner peripheral side surface 25a, and preferably is in contact with the upper surface 25c side of the inner peripheral side surface 25a. In this case, when the male connector portion 31 is further inserted into the female connector portion 22 (in the white arrow direction), the projecting edge portion 38 is pushed open according to the inclination of the inner peripheral side surface 25a of the first groove portion 25 (in the black arrow direction). Since the protruding portion 38 tends to return to its original shape due to elasticity, the inner peripheral side surface 38a of the protruding edge portion 38 and the inner peripheral side surface 25a of the first groove portion 25 are in close contact (preferably in surface contact). (A region). At this time, preferably, the inner circumferential side surface 25a side upper surface 25c of the first groove portion 25 and the end surface 31b of the male connector portion 31 are in contact with each other (B region). Thereby, the cap 3 and the strainer 2 can be connected without a gap, and the fluid can be prevented from leaking out from the contact portion between the cap 3 and the strainer 2. Further, the close contact between the projecting edge portion 38 and the first groove portion 25 becomes resistance, and unnecessary rotation between the strainer 2 and the cap 3 can be prevented.

  Moreover, according to the said structure, since the thing with the high precision of the dimension and shape of the protrusion part 38 and the 1st groove part 25 is not requested | required, manufacture of the female connector part 22 and the male connector part 31 can be made easy and cheap. it can. FIG. 10 is a schematic partial cross-sectional view of the projecting edge portion and the first groove portion according to the background art. For example, as shown in FIG. 10, when the cross section of the first groove portion 65 is formed in a rectangular shape, the shape of the first groove portion 65 is used to connect the female connector portion and the male connector portion so that there is no fluid leakage. Further, the size, the shape and size of the projecting edge portion 78, the outer diameter of the male connector portion, and the like must be formed so as to accurately match the entire circumference. Therefore, in this case, the fluid cannot be connected so as not to leak unless another member such as packing is used. However, according to the configuration of the present invention shown in FIGS. 4 and 5, the size and shape of the projecting edge portion 38 and the first groove portion 25 do not need to be accurately formed as compared with the embodiment shown in FIG. The connector portion 22 and the male connector portion 31 can be easily and inexpensively manufactured, and there is no need to use a separate member such as packing when connecting.

  The size, shape, and material of the protruding portion 38 and the first groove portion 25 can be deformed along the inclination of the first groove portion 25 without being damaged, and after the connection between the strainer 2 and the cap 3 is removed, It is designed to have an elastic action so as to return to the shape. For example, it is preferable that the projecting edge portion 38 and the first groove portion 25 are made of resin.

  The inclination of the inner peripheral side surface 25a is preferably such that the angle α formed with the axis is 45 ° or less. This is because if the inclination angle exceeds 45 °, the projecting edge portion 38 is bent and the elasticity may be lost. More preferably, the inclination of the inner peripheral side surface 25a is such that the angle α formed with the axis is 20 ° to 40 °. Within this range, it is difficult for an excessive load to be applied to the projecting edge portion 38, and the first groove portion 25 is easily brought into close contact by the elastic action of the projecting edge portion 38.

  3-5, although the inclination was formed in the inner peripheral side surface 25a of the 1st groove part 25, you may form the inclination of a diameter reduction direction in the outer peripheral side surface 25b.

  In the above embodiment, the female connector portion 22 is formed on the strainer 2 and the male connector portion 31 is formed on the cap 3. However, the male connector portion is formed on the strainer 2 and the female connector portion is formed on the cap 3. It does not matter. In this case, it is preferable that the dimension perpendicular to the axial direction of the portion of the cap where the second opening is formed is smaller than the dimension perpendicular to the axial direction of the female connector portion.

  Next, an embodiment of the filter device of the present invention will be described. In FIG. 6, the schematic perspective view of one Embodiment of the filter apparatus of this invention is shown. FIG. 7 shows a schematic sectional view of an embodiment of the filter device of the present invention. FIG. 6 shows a state before the strainer 2 and the cap 3 are connected to each other and before being accommodated in the casing 4. FIG. 7 shows a state in which the filter unit 1 is housed in the casing 4. FIG. 8 is a schematic partial cross-sectional view of the filter device. The filter device 10 includes the filter unit 1 of the present invention and a casing 4 on which the filter unit is mounted. The casing 4 is preferably a part of a pipe through which fluid flows, but may be attached to the pipe as a separate body.

  The casing 4 includes a first pipe 41 into which the filter unit 1 is inserted, and a second pipe 42 that is connected to the first pipe 41 so as to be conductive and supplies a pre-filtration fluid to the second opening 33 of the filter unit 1. The first tube 41 and the second tube 42 are preferably elbow tubes.

  In the casing 4, an attachment portion 43 for mounting the filter unit 1 is formed at the end of the first pipe 41. The attachment portion 43 has a fourth opening 43a for inserting the filter unit 1. The casing 4 and the filter unit 1 are preferably screwed together. In this case, a first thread 32 a formed on the outer peripheral surface of the cap portion 32 of the cap is screwed onto the inner peripheral surface of the mounting portion 43. Two threads 43b are formed. When the cap 3 is removed from the casing 4, the rotation direction of the first thread 32 a and the second thread 43 b is the same as the rotation direction for connecting the convex portion 35 of the male connector portion 31 to the second groove portion 23. preferable.

  A third opening 44 for supplying the pre-filtration fluid into the first pipe 41 is formed in the first pipe 41 portion to which the second pipe 42 is connected. In a state where the filter unit 1 is mounted on the casing 4, the position and shape of the third opening 44 are set so that at least the filter portion 21 is not hung. That is, the fluid before filtration is prevented from being mixed into the fluid after filtration. Preferably, the position and shape of the third opening 44 are formed along a groove-shaped portion formed on the male connector portion 31 by the female connector portion 22 and the mounting portion 34. Thereby, the pre-filtration fluid can be efficiently supplied to the second opening 33 without leaking to the filtration fluid side and the casing 4.

  A second step portion 41 a extending along the inner periphery is formed on the inner surface of the first tube 41. The second step portion 41a is formed so as to engage with the first step portion 22a of the filter unit 1 over the entire circumference. Engagement between the first step portion 22a and the second step portion 41a prevents mixing of the fluid before filtration and the fluid after filtration. For example, after the filter unit 1 is inserted into the first tube 41 until the first step portion 22a and the second step portion 41a come into contact with each other, the filter unit 1 is further pushed in, for example, the filter unit 1 is inserted into the first tube 41. By further screwing into the first step portion 22a, the first step portion 22a and the second step portion 41a are pressed against each other, and mixing of the pre-filtration fluid and the filtration fluid can be prevented (particularly, contamination of the filtrate is prevented). Is possible). According to this, leakage of the fluid before filtration and the fluid after filtration can be prevented without using an O-ring or packing. Accordingly, the first step portion 22a is formed at a position where the first step portion 22a and the second step portion 41a can be pressure-contacted by mounting the filter unit 1. Further, the engagement of the first step portion 22a and the second step portion 41a can position the filter unit 1, and even if the strainer 2 is detached from the filter unit 1 and left in the first pipe 41, the strainer 2 can be prevented from entering the back of the first pipe 41.

  The filter unit 1 and the casing 4 are preferably formed mainly from resin. In particular, a portion requiring an elastic action, such as a female connector portion 22 (particularly, a snap fit portion 24, a latching portion 24a, a first step portion 22a, a first groove portion 25a), a male connector portion 31 (particularly a convex portion). 35, the projecting edge portion 38), the second step portion 41a and the like are preferably formed of resin. More preferably, the filter unit 1 is made of resin except for the filter 21b and the O-ring 36. The casing 4 is also preferably made of resin. Resin rich in elasticity is preferable, for example, polypropylene resin and polyphenylene sulfide resin can be used.

  Next, an application example of the filter device of the present invention will be described. FIG. 9 shows a schematic perspective view of the shower toilet. The filter device 10 of the present invention can be used, for example, to remove foreign substances in the water supplied to the shower device 101 of the shower toilet 100 as shown in FIG. Although not shown in FIG. 9, since the wall is close to the shower toilet 100 and the floor is also close, the filter unit 1 must be attached and detached in a very small space. Don't be. Moreover, the filter apparatus 10 may be installed in the place where it is difficult to visually recognize. In such a case, according to the present invention, since the cap and the strainer can be handled as a unit, the filter unit can be easily attached to the shower device. In particular, it is not necessary to attach the filter unit while mounting an O-ring, packing, etc. between the filter unit and the casing. For example, it is only necessary to screw the filter unit, so that the attachment is easy and very simple. Contamination of the fluid before filtration can be prevented.

  The filter unit and the filter device of the present invention have been described based on the above embodiment, but are not limited to the above embodiment, and are within the scope of the present invention and based on the basic technical idea of the present invention. It goes without saying that various modifications, changes and improvements can be included in the above embodiment. Further, various combinations, substitutions, or selections of various disclosed elements are possible within the scope of the claims of the present invention.

  Further problems, objects, and developments of the present invention will become apparent from the entire disclosure of the present invention including the claims.

  The filter unit and filter device of the present invention can be applied not only to a shower toilet but also to various devices. Moreover, the fluid to be filtered is not limited to water, and can be applied to various fluids by selecting an appropriate material.

The schematic perspective view of one Embodiment of the filter unit of this invention before connecting a strainer and a cap. The schematic perspective view of the filter unit of this invention after connecting a strainer and a cap. The schematic fragmentary sectional view of the filter unit of this invention before connecting a strainer and a cap. The schematic fragmentary sectional view of the filter unit of this invention before connecting a strainer and a cap. The schematic fragmentary sectional view of the filter unit of this invention after connecting a strainer and a cap. The schematic perspective view of one Embodiment of the filter apparatus of this invention before connecting a strainer and a cap and before accommodating in a casing. The schematic sectional drawing of the filter apparatus of this invention of the state which mounted | wore the casing with the filter unit. The schematic fragmentary sectional view of the filter apparatus of this invention of the state which mounted | wore the casing with the filter unit. The schematic perspective view of a shower toilet. FIG. 5 is a schematic partial cross-sectional view of a filter unit according to background art for comparison with FIGS. 3 and 4.

DESCRIPTION OF SYMBOLS 1 Filter unit 2 Strainer 3 Cap 4 Casing 10 Filter apparatus 21 Filter part 21a 1st opening 22 Female connector part 22a 1st step part 23 2nd groove part 23a Vertical groove 23b Lateral groove 24a Latching part 25 1st groove part 25a Inner side surface side (Tapered surface)
25b outer peripheral side surface 25c upper surface 31 male connector portion 31a outer peripheral surface 31b end surface 33 second opening 35 convex portion 38 projecting edge portion 38a inner peripheral side surface 41 first tube 41a second step portion 42 second tube

Claims (4)

A cylindrical strainer having a filter for removing foreign substances in the fluid;
A cap detachably attached to the strainer,
The cap is detachably attached to the casing and has at least one opening that communicates with the inside of the strainer when attached to the strainer .
Of the strainer and the cap, one has an annular female connector for connecting to the other, and the other has an annular male connector for connecting to the one,
The strainer and the cap can be attached to and detached from the casing as a unit by connecting the female connector portion and the male connector portion,
The male connector portion has a projecting edge portion that extends in the circumferential direction on the end surface on the female connector portion side and protrudes in the female connector portion direction,
The female connector part has a first groove part for fitting with the protruding edge part,
At least one of the outer peripheral side surface and the inner peripheral side surface of the first groove portion has a tapered surface at least partially with respect to the axial direction so that the protruding edge portion is in contact with the first groove portion,
The projecting edge portion and the first groove portion are closely fitted,
The filter unit, wherein the fluid flows into the inside of the strainer from the opening , passes through the filter, and flows out from the inside to the outside of the strainer. 2. The filter unit according to claim 1 , wherein the protruding portion is deformed along the tapered surface of the first groove when the male connector and the female connector are connected. The protruding edge portion extends along the outer peripheral surface of the male connector portion,
The first groove has the tapered surface on the inner peripheral side surface,
The filter unit according to claim 1 or 2 , wherein an end surface of the male connector portion and an upper surface on the inner peripheral side surface side of the first groove portion are in contact with each other. The male connector part has at least one convex part,
The female connector part has at least one second groove part engaging with the convex part,
The second groove portion has an open end for inserting and removing the convex portion into and from the second groove portion at an end portion of the female connector portion, and communicates with the vertical groove extending in the axial direction and the vertical groove, A lateral groove extending in the circumferential direction; and at least a portion facing the lateral groove, having a latching portion that protrudes from the lateral groove and prevents the protrusion from being removed,
The hook is formed by rotating one of the male connector and the female connector with respect to the other and applying a predetermined force to the hook by the convex. filter unit according to any one of claims 1 to 3, characterized in that it is inserted into and removed from the transverse groove by the width of the transverse grooves is temporarily extended.