JP2019188370A - Strainer device - Google Patents

Abstract

To provide a strainer device which can effectively collect foreign objects mixed into water flowing thereinto over a longer period.SOLUTION: A strainer device 10 includes: a cylindrical strainer body 12 which has a net 12B for collecting foreign objects mixed into water flowing thereinto; and a flow adjustment member 13 which is housed in the strainer body 12, has rotary vane parts 13B which receive water, and rotates when the rotary vane parts 13B receive the water. The structure causes water flow in a space that houses the strainer body 12 into swirl flow to inhibit the water flow from concentrating on a part of the net 12B of the strainer body 12 and disperse a load applied to the net 12B to a wider range. Thus, the structure can make the net 12B less likely to be damaged.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a strainer device.

  Patent Document 1 discloses a strainer device in which a strainer (strainer main body) is disposed in a casing provided so that an inlet and an outlet are orthogonal to each other. In this strainer device, the strainer is disposed at a portion where the inlet and the outlet are orthogonal to each other. In addition, the strainer is provided with a frame for holding the shape of the mesh body on the outer surface of the mesh body formed in a cylindrical shape with one end face closed. This strainer device collects foreign matter mixed in the water flowing in from the inlet at the inside of the mesh body, and the water that has passed through the mesh body flows out from the outlet.

JP 2006-35077 A

  However, in patent document 1, it is thought that the water which flowed in from the inflow port concentrates on the mesh body located on the outflow side. For this reason, in this strainer device, the load on the mesh body is concentrated on the outlet side, and the mesh body on the outlet side is likely to be damaged.

  The present invention has been made in view of the above-described conventional circumstances, and it is a problem to be solved to provide a strainer device that can satisfactorily collect foreign matters mixed in water flowing in for a longer period of time. Yes.

The strainer device of the present invention comprises:
Has a net to collect foreign matter mixed in the inflowing water, a cylindrical strainer body,
A rectifying member that is housed in the strainer body and has a rotor blade that receives the water, and that rotates when the rotor blade receives the water;
It is characterized by having.

  In this strainer device, when the rotary blade receives water by the water flowing into the strainer body, the rectifying member rotates. As a result, the flow of water in the space containing the strainer body can be swirled to prevent the water flow from concentrating on a part of the mesh of the strainer body, and the load on the mesh can be dispersed more widely. This can make the net difficult to break.

  Therefore, the strainer device of the present invention can satisfactorily collect foreign matters mixed in the water flowing in for a longer period of time.

It is sectional drawing of the strainer apparatus of Example 1, and an on-off valve. It is a perspective view of the rectification | straightening member of the strainer apparatus of Example 1, and a control member. BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram which shows the state which installed the strainer apparatus of Example 1, and the on-off valve, Comprising: (A) is the state installed by connecting the on-off valve to the water supply pipe extended upward from a floor surface, ( B) is a state in which a water supply pipe extending in the lateral direction from the wall surface is connected to the on-off valve.

  A preferred embodiment of the present invention will be described.

  The strainer device of the present invention may include a sensor that detects rotation of the rectifying member. As the amount of foreign matter collected in the strainer net increases, the flow rate of water passing through the net decreases. Then, since the amount of water received by the rotating blade portion of the rectifying member is reduced, the rotational speed of the rectifying member is also reduced. That is, this strainer device can grasp the extent to which the net has collected foreign matter based on the rotation of the rectifying member detected by the sensor.

  The strainer device of the present invention includes a housing in which a strainer body is housed, an inlet through which water flows in, an outlet through which water flows out, and a staying portion in which the water flows in are formed, and at least one of the rotor blades. The part can be arranged in the stay part. In this case, when the rotor blade receives water flowing into the strainer body, the rectifying member rotates, and the water staying in the staying portion easily flows out of the staying portion on the flow generated by the rotor blade rotating together with the rectifying member. Become. That is, this strainer device can prevent water from staying in the staying portion.

  Next, a first embodiment in which the strainer device of the present invention is embodied will be described with reference to the drawings.

<Example 1>
As shown in FIG. 1, the strainer device 10 includes a housing 11, a strainer body 12, and a rectifying member 13.

The housing 11 includes a first cylinder portion 11A, a second cylinder portion 11B, and a first lid body 11C.
11 A of 1st cylinder parts have comprised the cylindrical shape which the both ends opened. Threads are formed at both ends of the outer peripheral surface of the first cylinder portion 11A. A step portion 11D having a diameter smaller than the inner diameter of the other end portion is formed at one end portion of the first cylinder portion 11A. In addition, a strainer chamber 11E in which a strainer body 12, a rectifying member 13, and a regulating member 14 to be described later are housed is formed on the other end side of the step portion 11D of the first cylinder portion 11A.

  The second cylinder portion 11B has a cylindrical shape, one end of which is connected to the central portion of the outer peripheral surface of the first cylinder portion 11A, communicates with the strainer chamber 11E of the first cylinder portion 11A, and is connected to the first cylinder portion 11A. It extends in a cylindrical shape in the orthogonal direction. A screw thread is formed on the outer peripheral surface of the other end portion of the second cylinder portion 11B. The second cylinder portion 11B is provided with a flange portion 11J at the center portion in the central axis direction. Further, a groove portion 11L extending in the circumferential direction is formed on the other end portion side of the flange portion 11J, and an O-ring is fitted into the groove portion 11L.

The first lid 11C has a cylindrical shape. Further, a thread is formed on the inner peripheral surface of one end portion of the first lid 11C, and a first reduced diameter portion 11K having a reduced inner diameter is provided on the other end portion. One end of the first lid 11C can be fastened to a screw thread at the other end of the first cylinder 11A. A sensor 11F is provided on a part of the outer peripheral surface of the first lid 11C. The sensor 11F can detect magnetism. A signal line 11H is drawn out from the sensor 11F. The signal line 11H is electrically connected to a control unit (not shown), for example, and inputs a signal output from the sensor 11F to the control unit based on the magnetic strength detected by the sensor 11F. Can do. The control unit can perform predetermined arithmetic processing on a signal input via the signal line 11H.
In the housing 11 thus formed, the other end of the second cylinder part 11B is an inlet 11M through which water flows in, and one end of the first cylinder part 11A is an outlet 11N through which water flows out. The opening directions of the inflow port 11M and the outflow port 11N are in directions orthogonal to each other. That is, the housing 11 is formed with an inlet 11M through which water flows and an outlet 11N through which water flows out.

The strainer body 12 includes a frame body 12A and a net 12B.
The frame body 12A has a cylindrical shape in which a plurality of openings 12C are formed on the outer peripheral surface. The outer diameter of the frame 12A extends from one end to the center and is substantially the same as the inner diameter of the step portion 11D of the first cylinder portion 11A. The outer diameter of the other end of the frame 12A is substantially the same as the inner diameter of the strainer chamber 11E. The frame body 12A has a plurality of openings 12C between one end and the other end. In addition, groove portions 12E and 12F are formed on the outer peripheral surfaces of the one end portion and the other end portion of the frame body 12A so as to extend in the circumferential direction, and O-rings are fitted in the respective groove portions. The other end portion of the frame body 12A is closed, and a protruding portion 12D protruding in a direction away from the frame body is provided along the central axis of the frame body 12A from the closed portion.
The net 12B is formed in a cylindrical shape and covers each opening 12C of the frame 12A from the outer peripheral surface side of the frame 12A. That is, the strainer body 12 is cylindrical.
A restricting member 14 is attached to one end of the frame 12A. In the restricting member 14, a plurality of columnar members 14 </ b> B extending in a radial direction from the central axis of the annular portion 14 </ b> A are coupled to the inner peripheral surface of the annular portion 14 </ b> A having an annular shape (see FIG. 2).

The rectifying member 13 has a shaft portion 13A extending in one direction and four rotary blade portions 13B. The shaft portion 13A has a cylindrical shape and extends in one direction.
Each rotary blade part 13B has the same shape. Each rotary blade portion 13B has a belt shape, and one of the two long sides is connected to the outer peripheral surface of the shaft portion 13A, and is formed in a spiral shape around the central axis of the shaft portion 13A. Adjacent rotor blades 13B are arranged at positions shifted by 90 degrees in the circumferential direction of the shaft portion 13A. An annular member 13C having an annular shape is connected to a side of each rotary blade located at one end of the shaft portion 13A on the side away from the shaft portion 13A in the radial direction.
Further, a disc-shaped disk member 13D is coaxially connected to the shaft portion 13A at the other end of the shaft portion 13A. The outer diameter of the disk member 13D is smaller than the inner diameter of the frame body 12A of the strainer body 12. A magnet 13E is embedded in a part of the outer peripheral edge of the disk member 13D (see FIG. 2). Further, the side of each rotary blade portion 13B on the side away from the shaft portion 13A in the radial direction is formed so as not to protrude outward from the outer periphery of the disk member 13D.
The flow regulating member 13 is housed in the frame body 12A with the side on which the disk member 13D is provided facing the other end side of the frame body 12A of the strainer body 12. The rectifying member 13 is rotatable about the central axis of the shaft portion 13A with respect to the frame body 12A.

The strainer body 12 to which the rectifying member 13 and the restricting member 14 are assembled is such that the restricting member 14 of the strainer body 12 is inserted into the first reduced diameter portion 11K of the first lid 11C through the protruding portion 12D of the strainer body 12. It is inserted into the strainer chamber 11E from the attached side. And the strainer main body 12 with which the rectification | straightening member 13 and the control member 14 were assembled | attached is arrange | positioned in the strainer chamber 11E by tightening the 1st cover body 11C in the screw thread of the other end part of 11 A of 1st cylinder parts. That is, the housing 11 houses the strainer body 12.
At this time, the O-ring of the groove portion 12E of the frame body 12A is crushed by the inner peripheral surface of the step portion 11D of the first cylinder portion 11A and the bottom surface of the groove portion 12E, so that the outer peripheral surface of the one end portion of the frame body 12A and the first The inner peripheral surface of the cylindrical step 11D is connected in a watertight manner.
Further, the O-ring of the groove portion 12F of the frame body 12A is crushed by the inner peripheral surface of the strainer chamber 11E and the bottom surface of the groove portion 12F, so that the inner peripheral surface of the other end portion of the first cylinder portion 11A and the other of the frame body 12A. The outer peripheral surface of the end portion is connected in a watertight manner, and the other end portion of the first cylindrical portion 11A is closed in a watertight manner.
At this time, the position of the magnet 13E of the rectifying member 13 and the position of the sensor 11F of the first lid 11C in the central axis direction of the strainer body 12 are substantially the same. Further, in the first cylinder portion 11A, a portion located on the first lid body 11C side with respect to the second cylinder portion 11B is a retention portion 11G in which water is easily retained. The staying part 11G is formed at a position sandwiching the second cylinder part 11B with respect to the outlet 11N. The staying part 11G is located outside the path connecting the inflow port 11M and the outflow port 11N. In other words, the first cylinder portion 11A of the housing 11 of the strainer device 10 is formed with a staying portion 11G in which the inflowing water stays. And a part of rotary blade part 13B is arrange | positioned in the retention part 11G.
Further, when the first lid 11C is removed from the other end of the first cylinder portion 11A, the strainer body 12 assembled with the rectifying member 13 and the regulating member 14 can be taken out from the strainer chamber 11E.

In addition, an opening / closing valve 30 that is a water stop cock is connected to the other end of the second cylindrical portion 11 </ b> B of the housing 11. The on-off valve 30 has a valve housing cylinder part 31, an on-off valve body 32, and an operation part 33. That is, the strainer device 10 is attached to the water stop cock.
The valve storage cylinder 31 has a cylindrical shape with both ends opened. Threads are formed on the inner peripheral surfaces of the one end and the other end of the valve storage cylinder 31.
Further, the valve storage cylinder part 31 is provided with an operation shaft storage cylinder part 34 and a third cylinder part 35. The operation shaft storage tube portion 34 has a cylindrical shape, and one end portion is connected to the outer peripheral surface of the valve storage tube portion 31 to communicate with the valve storage tube portion 31 and extend in a direction orthogonal to the valve storage tube portion 31. ing. A screw thread is formed on the outer peripheral surface of the other end portion of the operation shaft storage cylinder portion 34.
The third cylinder part 35 has a cylindrical shape, and the other end is connected to the outer peripheral surface of the valve storage cylinder part 31 to communicate with the valve storage cylinder part 31, and the operation shaft storage cylinder is sandwiched between the valve storage cylinder part 31. The portion 34 extends coaxially. A screw thread is formed on the inner peripheral surface of one end of the third cylindrical portion 35. Further, a closing member 51 for closing the third cylindrical portion 35 in a watertight manner is fastened to one end portion of the third cylindrical portion 35.

  The on-off valve body 32 is a so-called ball valve. The on-off valve body 32 is formed with a first water passage 32A that passes through the center and a second water passage 32B that extends in the direction perpendicular to the first water passage 32A through the center and communicates with the first water passage 32A. Yes. The on-off valve body 32 is housed in the valve housing cylinder 31 so that the center axis of the valve housing cylinder 31 and the center axes of the operation shaft housing cylinder 34 and the third cylinder 35 intersect each other. Yes.

  One end of a substantially cylindrical operation shaft 32C is connected to the on-off valve body 32 at a position coaxial with the second water passage 32B and sandwiching the center of the on-off valve body 32. The operation shaft portion 32C is provided with a flange portion 32D at the center portion in the central axis direction. The operation shaft portion 32 </ b> C is inserted through the operation shaft storage tube portion 34, and the flange portion 32 </ b> D is disposed along the other end surface of the operation shaft storage tube portion 34. In addition, a pair of grooves 32E extending in the circumferential direction are formed side by side in the central axis direction of the operation shaft portion 32C on the outer peripheral surface of the operation shaft portion 32C located in the operation shaft storage tube portion 34. An O-ring is fitted. When these O-rings are crushed by the inner peripheral surface of the operation shaft storage cylinder portion 34 and the bottom surface of each groove portion 32E, the inner peripheral surface of the operation shaft storage tube portion 34 and the operation shaft portion 32C are connected in a watertight manner, The operation shaft storage cylinder 34 is closed in a watertight manner.

  A second lid body 36 is attached to the other end portion of the operation shaft storage cylinder portion 34. The second lid 36 has a cylindrical shape, a thread is formed on the inner peripheral surface of one end, and the inner peripheral surface of the other end is reduced in diameter to form a second reduced diameter portion 36A. . The second lid body 36 is inserted into the operation shaft portion 32 </ b> C protruding from the operation shaft storage tube portion 34, and is fastened to a screw thread at the other end of the operation shaft storage tube portion 34. The flange portion 32D of the operation shaft portion 32C is sandwiched between the other end surface of the operation shaft storage tube portion 34 and the second reduced diameter portion 36A of the second lid body 36.

  The operation unit 33 includes an operation unit main body 33A and a knob unit 33B. The operation unit main body 33A has a cylindrical shape. The operation portion main body 33A is coaxially connected to the operation shaft portion 32C protruding from the second lid body 36 by a screw S. The knob portion 33B extends from the outer peripheral surface of the operation portion main body 33A in a direction orthogonal to the central axis of the operation portion main body 33A.

A connecting tube portion 37 is provided at the other end of the valve housing tube portion 31. The connecting cylinder portion has a cylindrical shape with both ends opened, and a thread is formed on the outer peripheral surface of one end and the inner peripheral surface of the other end. The connecting cylinder part 37 is provided with a flange part 37A at the center part in the central axis direction. Further, a groove portion 37B extending in the circumferential direction is formed on one end portion side of the flange portion 37A, and an O-ring is fitted in the groove portion 37B. One end of the connecting tube portion 37 is fastened to the other end of the valve housing tube portion 31. In the connecting cylinder part 37, the flange part 37 </ b> A is in contact with the other end surface of the valve storage cylinder part 31. The connecting cylinder part 37 is watertight with the other end part of the valve storage cylinder part 31 by the O-ring of the groove part 37B being crushed by the inner peripheral surface of the other end part of the valve storage cylinder part 31 and the bottom surface of the groove part 37B. It is connected. Further, a water supply pipe 50 for supplying water is fastened to the other end portion of the connecting cylinder portion 37. The water supply pipe 50 stands up from the floor surface F and extends as shown in FIG.
In the open / close valve 30 formed in this way, one end of the valve housing cylinder 31 is fastened to the other end of the second cylinder 11 </ b> B of the housing 11. The flange portion 11 </ b> J of the second cylinder portion 11 </ b> B is in contact with one end surface of the valve storage cylinder portion 31.
The valve storage cylinder portion 31 is configured so that the O-ring of the groove portion 11L of the second cylinder portion 11B is crushed by the inner peripheral surface of one end portion of the valve storage cylinder portion 31 and the bottom surface of the groove portion 11L. It is connected to the end in a watertight manner.

The on-off valve 30 can rotate the on-off valve body 32 around the central axis of the operation shaft portion 32C via the operation shaft portion 32C by operating the operation portion 33.
When the opening / closing valve 30 matches the direction in which the first water passage 32 </ b> A extends to the direction of the central axis of the valve storage cylinder portion 31, one end side of the valve storage cylinder portion 31, the other end portion side of the valve storage cylinder portion 31, and It will be in the communication state which the 3rd cylinder part 35 connected.
Further, the opening / closing valve 30 is configured such that when the direction in which the first water passage 32 </ b> A extends is orthogonal to the direction of the central axis of the valve storage tube portion 31, the one end side of the valve storage tube portion 31 and the valve storage tube portion 31. The other end side and the third cylinder portion 35 are not communicated with each other.

The operation unit 33 is operated to bring the on-off valve 30 into a communication state. Then, the water supplied from the water supply pipe 50 flows into the strainer device 10 through the opening / closing valve 30 and the inlet 11M of the second cylinder portion 11B of the housing 11. And the foreign material mixed in water is collected by the net | network 12B of the strainer main body 12. FIG. When each rotating blade portion 13B of the rectifying member 13 receives the water that has passed through the net 12B, the rectifying member 13 rotates. Then, the water flows around the shaft portion 13A of the rectifying member 13 by the rotation of the rectifying member 13, and flows out from the outlet 11N of the first cylindrical portion 11A. That is, the water in the strainer body 12 swirls around the shaft portion 13A of the rectifying member 13 and flows. At this time, the water located in the staying part 11G of the first cylinder part 11A flows out of the staying part 11G on the flow of water generated by the rotary blade part 13B of the rectifying member 13, and the outlet 11N of the first cylinder part 11A It becomes easy to flow toward the side. Thus, the strainer device 10 can make it difficult for water to stay in the staying part 11G.
Further, the water located between the outer peripheral surface of the strainer body 12 and the inner peripheral surface of the strainer chamber 11E is also guided by the water swirling in the strainer main body 12, and swirls around the shaft portion 13A of the rectifying member 13. Flowing. As a result, the flow of water can be prevented from concentrating on the net 12B located in the area where the second cylinder portion 11B and the strainer chamber 11E communicate with each other, and the load on the net 12B can be more widely dispersed. 12B can be made difficult to break.

  At this time, the sensor 11F of the first lid 11C detects the magnetism of the magnet 13E that rotates together with the rectifying member 13. That is, the sensor 11 </ b> F detects the rotation of the rectifying member 13 by detecting the magnet 13 </ b> E rotating with the rectifying member 13. The sensor 11F outputs a signal based on the magnetic strength detected by the sensor 11F, and inputs this signal to the control unit via the signal line 11H. And the state which the rectification member 13 rotates (for example, the rotation speed etc. which the rectification member 13 rotates per unit time, etc.) can be obtained by performing predetermined arithmetic processing with respect to the input signal by a control part.

  In addition, as shown in FIG. 3 (B), when using a water supply pipe 52 extending in the lateral direction from the wall surface W instead of the water supply pipe 50, the closing member 51 is fastened to the other end of the connecting cylinder part 37. The other end portion of the connecting tube portion 37 is closed in a watertight manner, and the water supply pipe 52 is tightened into the third tube portion 35. Thereby, the posture of the strainer device 10 can be made the same as when the water supply pipe 50 rising from the floor surface F is fastened to the other end portion of the connecting cylinder portion 37.

  As described above, in the strainer device 10, when the rotary blade portion 13 </ b> B receives water by the water flowing into the strainer body 12, the rectifying member 13 rotates. As a result, the flow of water in the space in which the strainer main body 12 is accommodated is swirled to prevent the water flow from concentrating on a part of the net 12B of the strainer main body 12, and the load on the net 12B can be broadened. Since it can disperse | distribute, the network 12B can be made hard to be damaged.

  Therefore, the strainer device 10 of the present invention can satisfactorily collect foreign matters mixed in the water flowing in for a longer period of time.

  Further, the strainer device 10 includes a sensor 11F that detects the rotation of the rectifying member 13. As the amount of foreign matter collected in the net 12B of the strainer device 10 increases, the flow rate of water passing through the net 12B decreases. Then, since the amount of water received by the rotary blade portion 13B of the rectifying member 13 is reduced, the rotational speed of the rectifying member 13 is also reduced. That is, the strainer device 10 can grasp the extent to which the net 12B has collected foreign matter based on the rotation of the rectifying member 13 detected by the sensor 11F.

  Further, the strainer device 10 houses a strainer body 12, and includes a housing 11 in which an inlet 11M through which water flows in, an outlet 11N through which water flows out, and a staying part 11G in which the water flows in are formed, are rotated. A part of the wing part 13B is arranged in the stay part 11G. For this reason, when the rotary blade part 13B receives the water flowing into the strainer body 12, the rectifying member 13 rotates, and the water staying in the staying part 11G on the flow generated by the rotary wing part 13B rotating together with the rectifying member 13 is retained. It becomes easy to flow out from the retention part 11G. That is, the strainer device 10 can prevent water from staying in the staying part 11G.

The present invention is not limited to the first embodiment described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention.
(1) In the first embodiment, four rotating blade portions are provided, but may be three or less, or may be five or more.
(2) In the first embodiment, the magnetism of the rectifying member magnet is detected by the sensor. However, a coil in which a plurality of metal wires are bundled on the outer peripheral surface of the first lid is provided, and the magnet rotates together with the rectifying member. It is good also as a structure which an induced current produces in a coil. That is, the coil generates electric power as the rectifying member rotates. In addition, since the magnitude of the induced current generated in the coil changes according to the number of revolutions per unit time of the rectifying member, a signal corresponding to the magnitude of the induced current is input to the control section, and this signal is calculated by the control section. By processing, it is also possible to grasp the extent to which the net has collected foreign matter.
Also, if the light bulb or LED is turned on by this induced current, the brightness of the light bulb or LED that changes depending on the magnitude of the induced current changes. It is possible to grasp the extent to which foreign matter has been collected.
Alternatively, the rectifying member may be provided with a rotating shaft that penetrates the first lid, and the rotating shaft of the generator may be connected to the rotating shaft, and the generator may be driven by the rotation of the rectifying member to generate electric power.
(3) In the first embodiment, the rotor blade portion is provided from one end of the rectifying member to the other end. However, the rotor blade portion may be provided at the one end portion and the other end portion without being provided at the central portion of the rectifying member. .
(4) In the first embodiment, water flows in from the second tube portion and flows out from one end portion of the first tube portion, but water flows in from one end portion of the first tube portion, and the second tube You may let it flow out of the part.
(5) In Example 1, the net covers each opening of the frame from the outer peripheral surface side, but the net may be arranged on the inner peripheral surface side of the frame.

DESCRIPTION OF SYMBOLS 10 ... Strainer apparatus 11 ... Housing 11F ... Sensor 11G ... Stay part 11M ... Inlet 11N ... Outlet 12 ... Strainer main body 12B ... Net 13 ... Rectification member 13B ... Rotary blade part

Claims (3)

Has a net to collect foreign matter mixed in the inflowing water, a cylindrical strainer body,
A rectifying member that is housed in the strainer body and has a rotor blade that receives the water, and that rotates when the rotor blade receives the water;
A strainer device comprising:   The strainer device according to claim 1, further comprising a sensor that detects rotation of the rectifying member. A housing in which the strainer body is housed, an inlet through which the water flows in, an outlet through which the water flows out, and a stay portion in which the water that has flowed in are formed;
3. The strainer device according to claim 1, wherein at least a part of the rotating blade portion is disposed in the staying portion.

Images