JP6539867B2 - Drainage trap - Google Patents

Description

  The present invention relates to a drainage trap that discharges drainage from equipment and forms a trap function to prevent odor from the downstream and backflow of pests indoors.

Equipment such as washing machines and bathtubs drain water by their use, but if drainage pipes that discharge the drainage are simply connected to the sewage side, odors and pests from the downstream side will flow back into the room . Then, the said problem is solved by providing the apparatus which has a trap function called a drainage trap.
The drainage trap has a sealing part capable of storing drainage inside, and by making the drainage flow path full of water (water sealing) by the drainage stored in the sealing part, odor and odor from the downstream side to indoor Form a trap function to prevent pests from invading.
Here, when the washing machine is a facility device, the above-mentioned drainage trap is a washing machine as a receptacle that prevents the room from being submerged in water when water leakage occurs due to a failure of the washing machine as another facility device or equipment failure. The structure is such that drainage from the waterproof pan flows in. In the case where the bathtub is a facility equipment, the drainage trap has a structure in which drainage from a bathtub waterproof pan on which the bathtub is mounted as another facility equipment or a washroom waterproof pan receiving bathroom drainage flows in ing. That is, the drainage trap has a first flow path into which the drainage from the installation equipment flows, and a second flow path into which the drainage from the other installation equipment flows.

In the drainage trap described in Patent Document 1, drainage from a washing machine as equipment and water from a waterproof pan as other equipment flows in, and the trap body, the flange member, the sealing water bottle, the deodorizing cylinder, the foam stopper pipe, the eye It consists of a plate.
The trap body is a box with a bottom and a substantially cylindrical shape and an opening at the top, and a discharge port is opened from the side. The flange member is in the form of a cylinder having an outwardly extending bowl-like portion at its upper end, and is screwed with a female screw provided on the inner periphery of the trap body by a male screw provided on the outer periphery.
The sealed water weir is a bowl-shaped member disposed inside the trap body, and is capable of storing therein the drainage discharged from the equipment.
The deodorizing cylinder is a cylindrical member attached to the flange member and forming a drainage flow path inside, and the lower end thereof is inserted into the inside of the sealing water bottle.
The defoaming pipe is a tubular member disposed inside the deodorizing cylinder and forming a drainage channel inside. In addition, the foam stopper pipe has at its lower end a guide portion for guiding the drainage passing through the inside to the drainage flow path formed by the outer periphery of the deodorizing cylinder and the inner periphery of the water sealing gutter. It is arrange | positioned so that it may be located below.
The tray is a circular member attached to the flange member and has a net-like collection portion for discharging the drainage produced on the waterproof pan into the drainage trap but preventing the outflow of dust larger than a predetermined amount. ing.

The drainage trap described in Patent Document 1 having the above configuration includes a first flow path for discharging drainage from a washing machine as equipment and a second flow path for discharging drainage from a waterproof pan as another equipment. It is formed.
When the drainage from the washing machine is generated, all the drainage flows into the trap body through the bubbling pipe, and is guided by the guide portion to the drainage flow path formed by the outer periphery of the deodorizing cylinder and the inner periphery of the sealing ring. And the drainage which overflowed the seal ring is discharged to the piping further downstream from the discharge port opened to the trap main body side. Therefore, the waste water passing through the first flow path hardly passes through the flow path formed by the inner circumference of the deodorizing cylinder and the outer circumference of the defoaming pipe.
On the other hand, when drainage occurs on the waterproof pan, the drainage passes through the mesh and flows into the trap body. The said drainage descends the drainage flow path formed of the deodorization cylinder inner circumference and the bubble prevention pipe circumference, inverts the flow path at the bottom of the water sealing gutter, and the drainage overflowing the water sealing gutter is opened to the side of the trap body. It is discharged to the piping further downstream from the outlet.

That is, the drainage trap has a structure to prevent the drainage from flowing backward from the waterproof pan by guiding the drainage discharged from the washing machine to the outside of the deodorizing cylinder by means of the foam stopper pipe.
However, when the drainage trap generates a large amount of drainage from the washing machine, or when a large amount of foam is mixed in the drainage from the washing machine, the drainage is a gap in the guide portion of the antifoaming pipe. Further, there is a problem that the second flow path flows back and overflows on the waterproof pan.

Patent Document 2 describes a drainage trap in which a float type non-return valve is provided in a second flow passage which is a drainage flow passage from a waterproof pan as another equipment. The float-type check valve uses a valve body called float, which has a specific gravity lower than that of water, and when fluid from the downstream side is generated, the valve body floats up by drainage and blocks the second flow path. It is a check valve that can prevent backflow. However, the waste water discharged from the washing machine as equipment is often a foamy waste water that has been bubbled by a detergent. Since the foamy drainage contains air inside, the mass per volume is small, and therefore the specific gravity is also low, so the float check valve often does not operate normally, and the backflow of drainage is surely prevented. It was difficult.
Further, in the drainage trap described in Patent Document 2, since the float type non-return valve is provided in the eye plate, in addition to the height width of the deodorizing cylinder, the drainage trap is at least a float non-return valve. The width required to rise was required, and the overall height of the entire device had increased. In addition, since the sealing water portion formed by the deodorization cylinder and the sealing water portion needs to have a predetermined height or more according to the standard or the like, it is difficult to reduce the total height simply by shortening the deodorizing cylinder.

JP 2008-196169 A JP 2001-2000056 A

  This invention makes it a subject to provide the drainage trap which improved the backflow prevention function which prevents backflows, such as drainage from the 1st flow path side, in view of the above-mentioned problem, holding down the whole height of a device.

The present invention according to claim 1 for solving the above problems is:
With drainage outlet where drainage flows in,
A cylindrical deodorizing cylinder having a downward opening and extending downward from the drainage port;
A sealing portion for storing the lower end of the deodorization cylinder inside and storing drainage to form sealing water,
A drainage trap having a discharge port for discharging the drainage overflowing the sealing portion to the downstream side,
The deodorization cylinder is the first flow path into which drainage from equipment and equipment flows,
A second flow path into which drainage from other equipment and equipment flows,
A check valve disposed in the second flow path for preventing back flow such as drainage from the first flow path side,
The second flow path joins the first flow path inside the deodorizing cylinder ,
Check valve is a drain trap to the energized characterized Rukoto so as to close the second passage by waste water flowing into the deodorant cylinder when the waste water from the first flow path.

  The present invention according to claim 2 is characterized in that the second flow passage bends the flow passage in the deodorizing cylinder so that the second flow passage merges with the first flow passage in a substantially horizontal direction. It is a trap.

  The above "substantially horizontal direction" does not refer to a state without any inclination, but includes one having an inclination angle of about several degrees.

  According to a third aspect of the present invention, the non-return valve is a swing-type non-return valve, one end of which is rotatably fixed in the deodorizing cylinder, from the substantially horizontal direction to the second flow passage. It is a waste_water | drain trap of Claim 1 or Claim 2 characterized by contact | abutting.

  The present invention according to claim 4 is characterized in that the check valve maintains the blockage of the second flow passage when there is no inflow of drainage from the upstream side. It is a drainage trap as described in or one.

The present invention according to claim 5 is the drainage trap according to any one of claims 1 to 4, characterized in that the deodorization cylinder is inclined relative to the vertical direction as it proceeds downward. It is.

According to a sixth aspect of the present invention, in the drainage trap according to any one of the first to fifth aspects,
It is a drainage trap characterized by having a cylindrical casing body which forms a channel inside, and forming the second channel by attaching the casing body to a deodorization cylinder.

According to the first aspect of the present invention, since the second flow path is provided with the non-return valve for preventing the backflow of the drainage from the first flow path side, when there is a large amount of drainage from the first flow path, When there is foamy drainage, the drainage is prevented from flowing backward in the second flow path.
In addition to the height of the deodorizing cylinder, the height width of the non-return valve is required in addition to the height of the deodorizing cylinder because the conventional drainage trap provided the non-return valve on the eye plate. By arranging the non-return valve in the cylinder, the overall height of the device can be reduced.
Furthermore, since the second flow passage merges with the first flow passage inside the deodorization cylinder, the first flow passage and the second flow passage can configure the trap function using common sealing water, It is possible to prevent one of the flow paths from running out of sealing water.
According to the second and third aspects of the present invention, since the first flow path is joined in the substantially horizontal direction, the flow path area at the meeting point can be largely secured, so that a suitable drainage flow rate can be obtained. Can be maintained.
According to the fourth aspect of the present invention, even when the drainage channel is filled with a fluid having a specific gravity lower than that of water, such as foamy drainage, it is possible to preferably prevent the backflow. In addition, although the above-mentioned "specific gravity is lower than water" actually is not lower in specific gravity than water, it includes a fluid whose mass per volume is lower than water by containing a large amount of air and the like.
According to the fifth aspect of the present invention, the second flow path merges with the first flow path inside the deodorizing cylinder by being inclined with respect to the vertical direction as the deodorizing cylinder moves downward. Can be formed by injection molding.
According to the sixth aspect of the present invention, by removing the casing body, cleaning of the non-return valve, the second flow passage, and the like becomes possible, and the maintainability is improved.

It is sectional drawing which shows the drainage trap of this invention. It is a disassembled perspective view which shows the structure of a drainage trap. It is a disassembled perspective view which shows the structure of a deodorizing cylinder. It is a reference drawing showing the flow of drainage of the first channel. It is a reference drawing showing the flow of drainage of the 2nd channel. It is sectional drawing which shows the drainage trap of this invention which concerns on 2nd embodiment. It is a disassembled perspective view which shows the structure of a drainage trap. It is a disassembled perspective view which shows the structure of a deodorizing cylinder. It is a reference drawing showing the flow of drainage of the first channel. It is a reference drawing showing the flow of drainage of the 2nd channel. It is a reference drawing showing the construction state of a drainage trap.

  Hereinafter, the drainage trap 1 of the present invention will be described with reference to the drawings. The description given below is for the purpose of facilitating the understanding of the embodiments, and the invention is not to be understood as being limited thereby.

  Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. 1 to 5 and 11.

As shown in FIG. 11, the drainage trap 1 according to the present embodiment is attached to the opening of a waterproof pan 200 as another facility device on which the washing machine 100 as a facility device is placed.
The waterproof pan 200 is substantially square in plan view, has pedestals for mounting the washing machine 100 at its four corners, and has a saucer shape whose outer periphery is covered with the waterproof wall, and is circular at the bottom The drainage trap 1 mounting hole is open. The mounting hole is opened at the lowest position of the waterproof pan 200, and all drainage and the like generated on the waterproof pan 200 are formed to flow into the drainage trap 1 when the construction shown in FIG. 1 is completed. There is.

  As shown in FIGS. 1 to 3, the drainage trap 1 is composed of a trap body 2, a flange member 4, a water seal 7, a deodorizing cylinder 9, an eyelet 22 and a drainage elbow 23, and the drainage from the washing machine 100 is It has the 1st flow path 11 which discharges, and the 2nd flow path 13 which discharges the drainage from waterproofing pan 200. As shown in FIG.

  The trap body 2 is substantially cylindrical with a bottom, and has a box-like shape with openings formed on the top and side surfaces thereof. An opening formed on the upper surface of the trap main body 2 is screwed with a female screw on its inner periphery, and is screwed with a flange member 4 described later via the packing P and the waterproof pan 200. The opening formed on the side surface of the trap main body 2 is a discharge port 3 for discharging the drainage flowed into the interior of the trap main body 2 to a pipe further downstream, and the discharge port 3 is cylindrically extended and further The downstream piping is bonded.

  The flange member 4 has a cylindrical shape, and includes an outwardly facing flanged portion formed at the upper end thereof and a tubular portion extended downward from the lower end of the flanged portion. A male screw portion is screwed on the outer periphery of the cylindrical portion, and is screwed with the trap main body 2 through the packing P and the waterproof pan 200, and is extended inward at the middle in the inner periphery of the cylindrical portion An inwardly directed step 5 and a projection 6 are formed. The outer periphery of the bowl-like portion is larger in diameter than the mounting hole of the waterproof pan 200, but the outer periphery of the cylindrical portion is smaller in diameter than the mounting hole. Then, a sealing dam 7 to be described later is placed on the stepped portion 5, and a deodorizing cylinder 9 to be described later is engaged with the projection 6.

  The water sealing ring 7 has a bottomed cylindrical shape and a bowl shape whose upper side is opened, and a plurality of notches 8 are formed in the circumferential direction at the upper side portion. The notch 8 is substantially rectangular, and the sealing gutter 7 can store drainage (sealing water) from the bottom to the lower end of the notch 8.

The deodorizing cylinder 9 is a cylindrical member which forms a drainage channel inside, and the lower end thereof is disposed between the bottom surface of the water sealing rod 7 and the notch 8, and the side wall of the deodorizing cylinder 9 is discharged downward as it goes downward. It is inclined about 8 degrees to the vertical direction toward the side. That is, the deodorization cylinder 9 is inclined with respect to the vertical direction as it moves downward. Further, the deodorizing cylinder 9 is composed of a first-class inlet 10, a first channel 11, a second inlet 12, a second channel 13, a check valve 15, a valve cover 18, and a mounting portion 20. The check valve 15 is composed of a valve seat 16 and a valve body 17 provided inside the deodorizing cylinder 9.
The first-class inlet 10 is an inlet of the first flow path 11 and is opened above the top surface of the deodorizing cylinder 9 and above the second inlet 12, and a drainage elbow 23 connected to the washing machine 100 is attached. Therefore, all the drainage drained from the washing machine 100 flows into the first channel 11 from the first-class inlet 10.
The first flow path 11 is a drainage flow path through which the drainage flowed in from the first-class inlet 10 flows, and is inclined approximately 8 degrees with respect to the vertical direction toward the discharge port 3. Further, in the first flow passage 11, in the deodorizing cylinder 9, a second flow passage 13 to be described later merges in a substantially horizontal direction, and a valve body 17 is attached to the merged position.
The second inflow port 12 is an inflow port of the second flow path 13 and is opened at the upper surface of the deodorizing cylinder 9, and the flow path is opened on the waterproof pan 200. Therefore, all the drainage generated on the waterproof pan 200 flows into the second flow path 13 from the second inlet 12.
The second flow path 13 is a drainage flow path through which the drainage flowed in from the second inflow port 12 flows, and after being inclined about 8 degrees with respect to the vertical direction toward the discharge port 3, In the inside of 9, the first flow passage 11 merges with the first flow passage 11 in a substantially horizontal direction. In addition, the second flow path 13 is an end portion thereof, and has a valve seat 16 with which the valve body 17 abuts at a joining portion with the first flow path 11, and the valve body 17 abuts with the valve seat 16 The flow path is blocked. Here, the valve seat 16 is substantially vertical in cross section, and the valve body 17 abuts against the valve seat 16 in a substantially horizontal direction. Note that although the valve seat 16 is described as “vertically cross-sectional view,” in fact, the cross-section of the valve seat 16 shown in FIG. 1 is inclined at about 6 degrees with respect to the vertical direction. It is a face. Therefore, although "the valve body 17 is described as being in contact with the valve seat 16 in a substantially horizontal direction", the valve body 17 is actually in contact with the valve seat 16 in an inclined state of about 6 degrees, The valve body 17 blocks the second flow passage 13 by its own weight when drainage does not flow into the second flow passage 13 from the upstream side.
The valve body 17 is a substantially rectangular plate made of a material having a specific gravity higher than that of water, and the upper end thereof is disposed at the boundary between the first flow passage 11 and the second flow passage 13. It is fixed freely. Moreover, the convex part is formed over the circumference | surroundings of the valve body 17, and it abuts on the said valve seat 16 by the said convex part.
The valve cover 18 is a plate having a valve presser 19 at the lower side, and after the valve body 17 is disposed in the deodorant cylinder 9, the valve presser 19 allows the valve body 17 to be freely pivotable from above the deodorant cylinder 9. It is a member to fix. The valve cover 18 is welded to the deodorizing cylinder 9 after the valve body 17 is disposed.
The mounting portion 20 is provided on the outer periphery of the upper end of the deodorizing cylinder 9, and comprises a groove portion 21 engaged with the projection portion 6 of the flange member 4 and a packing. The groove portion 21 is formed at four places around the mounting portion 20 at every 90 degrees in the circumferential direction, and is inclined upward from the lower end of the mounting portion 20. The width of the groove 21 in the top and bottom direction is slightly larger than the width of the protrusion 6 in the top and bottom direction, and the protrusion 6 can slide in the groove 21. Further, the projection 6 is located at the end of the groove 21 in the construction completion state.

  The drainage elbow 23 is a substantially L-shaped pipe in a side view, and is connected to a bellows-like flexible pipe (not shown) connected to the washing machine 100 on the upstream side, and the lower end thereof is connected to the first inlet 10 It is inserted.

  The tray 22 is a substantially semicircular member placed above the deodorizing cylinder 9 and above the second inlet 12, and drains drainage generated on the waterproof pan 200 into the drainage trap 1. However, it has a mesh-like collection part that prevents the outflow of large dust that may clog the piping.

  In the state where drainage does not flow in the first flow passage 11 and the second flow passage 13 (during no drainage), the drainage trap 1 blocks the second flow passage 13 by its own weight. Further, at this time, the valve body 17 is in contact with the valve seat 16 by a convex portion provided on the outer periphery thereof.

  The flow of drainage when drainage is generated from the washing machine 100 with respect to the drainage trap 1 will be described with reference to FIG. In FIG. 4, a part of the flow of the drainage generated from the washing machine 100 is indicated by a two-dot chain line.

First, the drainage generated from the washing machine 100 flows from the first inlet 10 into the first flow passage 11 in the deodorizing cylinder 9 through the flexible pipe and the drainage elbow 23.
Here, the waste water flowing into the first flow path 11 flows downward of the deodorizing cylinder 9, but a part of the waste water urges the valve body 17 toward the second flow path 13. Therefore, while the drainage is flowing in the first flow passage 11, the second flow passage 13 is blocked more firmly than in the case of no drainage, and the second flow is caused even when there is a large amount of drainage from the washing machine 100, etc. There is no backflow of drainage to the passage 13.
Then, the drainage having reached the lower end of the deodorizing cylinder 9 reverses the flow at the bottom surface of the water sealing gutter 7 and ascends the drainage flow path formed by the outer periphery of the deodorizing cylinder 9 and the inner circumference of the water sealing gutter 7. Then, the waste water reaching the notch 8 provided on the side surface of the water sealing ring 7 overflows to the outside of the water sealing hole 7 and is discharged from the discharge port 3 of the trap main body 2 toward the sewage side.

  Next, the flow of drainage when drainage is generated on the waterproof pan 200 will be described using FIG. In FIG. 5, a part of the flow of the drainage generated on the waterproof pan 200 is indicated by a two-dot chain line.

First, when drainage occurs on the waterproof pan 200, the drainage flows on the waterproof pan 200 and flows into the second flow path 13 through the grid 22 and the second inlet 12. At this time, dust, dirt and the like larger than a predetermined size are captured by the collection portion of the tray 22 and do not enter the second flow path 13.
Next, the drainage flowed into the second flow path 13 is bent by about 90 degrees in the flow direction by the bending portion 14 of the second flow path 13 and abuts on the valve body 17. At this time, since water pressure is applied to the valve body 17 in a direction away from the valve seat 16, the second flow path 13 is opened by pivoting about the upper end thereof.
And the drainage which rotated the valve body 17 flows into the first channel 11 from the substantially horizontal direction, and flows downward of the deodorizing cylinder 9.
The subsequent flow passes through the drainage flow path formed by the outer periphery of the deodorization cylinder 9 and the inner circumference of the sealing gutter 7, as with the flow of the drainage water flowing through the first flow path 11, and sewage from the notch 8 and the discharge port 3 It is discharged towards the side.
When drainage from the waterproof pan 200 is completed, the check valve 15 rotates the valve body 17 by its own weight and abuts on the valve seat 16 to close the second flow path 13 again.

  When drainage from the washing machine 100 or the waterproof pan 200 is finished, part of the drainage that has flowed into the trap body 2 is stored inside the sealed diaphragm 7 and a part of the drainage flow path on the inner periphery of the deodorization cylinder 9 The trap function is formed by bringing the drainage flow path formed by the outer periphery of the deodorizing cylinder 9 and the inner periphery of the water sealing ring 7 into a full water (water seal) state.

In the drainage trap 1 of the present invention, the second flow path 13 is provided with the non-return valve 15 (the valve seat 16 and the valve body 17) for preventing the back flow from the first flow path 11 side. When there is a large amount of drainage, or when there is a foamy drainage, the drainage does not backflow to the second flow path 13. Since the non-return valve 15 has a structure in which the second flow path 13 is closed when there is no drainage, even in the case where the drainage flow path is filled with a fluid having a lower specific gravity than water, such as foamy drainage. It is possible to preferably prevent backflow. Here, "having a specific gravity lower than that of water" means a fluid whose mass per volume is lower than that of water by containing a large amount of air etc., although the specific gravity is not actually lower than that of water.
Further, since the valve body 17 abuts the valve seat 16 of the second flow path 13 in a substantially horizontal direction, the drainage flow path at the time of valve opening is wide, and it is possible to secure a suitable drainage flow rate. Furthermore, since the check valve 15 is provided in the deodorizing cylinder 9, the overall height of the device can be reduced.
And since the second flow passage 13 joins the first flow passage 11 in the substantially horizontal direction inside the deodorization cylinder 9, the first flow passage 11 and the second flow passage 13 form a trap function using the same sealing water. It is possible to prevent either one of the flow channels from being sealed.
The deodorizing cylinder 9 is inclined about 8 degrees with respect to the vertical direction as it moves downward, and the valve seat 16 is inclined about 6 degrees in the same direction as the deodorizing cylinder 9. Therefore, by forming the boundary between the first flow passage 11 and the second flow passage 13 as a parting line, the deodorization cylinder 9 can be integrally formed by injection molding.

  Next, a drainage trap 1 according to a second embodiment of the present invention will be described using FIGS. 6 to 11. The drainage trap 1 according to the second embodiment is different from the drainage trap 1 according to the first embodiment only in the deodorizing cylinder 9 and the meshing plate 22, so only the corresponding portion will be described.

As shown in FIG. 6 to FIG. 8, the deodorization cylinder 9 is a cylindrical member forming a drainage channel inside, and the lower end thereof is disposed between the bottom surface of the water seal 7 and the notch 8, The side wall is hanging down. Further, the deodorizing cylinder 9 is composed of a first-class inlet 10, a first flow passage 11, a second inlet 12, a second flow passage 13, a check valve 15, a mounting portion 20, and a casing body 24. Further, the check valve 15 is constituted by a valve seat 16 and a valve body 17 provided on a casing body 24 inserted inside the deodorizing cylinder 9.
The first-class inlet 10 is an inlet of the first flow path 11 and is opened above the top surface of the deodorizing cylinder 9 and above the second inlet 12, and a drainage elbow 23 connected to the washing machine 100 is attached. Therefore, all the drainage drained from the washing machine 100 flows into the first channel 11 from the first-class inlet 10.
The first flow path 11 is a drainage flow path through which the drainage flowed in from the first-class inlet 10 flows, and the side wall is suspended. Further, in the first flow passage 11, in the deodorizing cylinder 9, a second flow passage 13 to be described later merges in a substantially horizontal direction, and a valve body 17 is attached to the merged position.
The second inflow port 12 is an inflow port of the second flow path 13 and is opened at the upper surface of the deodorizing cylinder 9, and the flow path is opened on the waterproof pan 200. Therefore, all the drainage generated on the waterproof pan 200 flows into the second flow path 13 from the second inlet 12. Further, the casing body 24 is inserted into the second inlet 12, and all the drainage generated on the waterproof pan 200 flows into the casing body 24 from the second inlet 12.
The casing body 24 is a cylindrical body having a substantially semicircular shape in plan view, and constitutes a drainage flow path to be the second flow path 13 inside, and after being inclined about 8 degrees with respect to the vertical direction toward the discharge port 3 The first flow path 11 merges with the first flow path 11 in the substantially horizontal direction inside the deodorizing cylinder 9 through the bending portion 14. In addition, the casing body 24 is a side surface thereof, and has a valve seat 16 with which the valve body 17 abuts at a joining portion with the first flow path 11, and the valve body 17 abuts with the valve seat 16 Is blocked. Here, the valve seat 16 is substantially vertical in cross section, and the valve body 17 abuts against the valve seat 16 in a substantially horizontal direction. Note that although the valve seat 16 is described as “vertically cross-sectional view,” in fact, the cross-section of the valve seat 16 shown in FIG. 1 is inclined at about 6 degrees with respect to the vertical direction. It is a face. Therefore, although "the valve body 17 is described as being in contact with the valve seat 16 in a substantially horizontal direction", the valve body 17 is actually in contact with the valve seat 16 with an inclination of about 6 degrees, The valve body 17 blocks the second flow passage 13 by its own weight when drainage does not flow into the second flow passage 13 from the upstream side.
The valve body 17 is a substantially oval plate made of a material having a specific gravity higher than that of water, and the upper end thereof is rotatably fixed on the side surface of the casing body 24. Moreover, the convex part is formed over the circumference | surroundings of the valve body 17, and it abuts on the said valve seat 16 by the said convex part.
The mounting portion 20 is provided on the outer periphery of the upper end of the deodorizing cylinder 9, and comprises a groove portion 21 engaged with the projection portion 6 of the flange member 4 and a packing. The groove portion 21 is formed at four places around the mounting portion 20 at every 90 degrees in the circumferential direction, and is inclined upward from the lower end of the mounting portion 20. The width of the groove 21 in the top and bottom direction is slightly larger than the width of the protrusion 6 in the top and bottom direction, and the protrusion 6 can slide in the groove 21. Further, the projection 6 is located at the end of the groove 21 in the construction completion state.

  The tray 22 is a substantially semicircular member placed above the deodorizing cylinder 9 and above the second inlet 12, and drains drainage generated on the waterproof pan 200 into the drainage trap 1. However, it has a mesh-like collection part that prevents the outflow of large dust that may clog the piping.

  The flow of drainage when drainage is generated from the washing machine 100 with respect to the drainage trap 1 will be described with reference to FIG. In FIG. 9, a part of the flow of the drainage generated from the washing machine 100 is indicated by a two-dot chain line.

First, the drainage generated from the washing machine 100 flows from the first inlet 10 into the first flow passage 11 in the deodorizing cylinder 9 through the flexible pipe and the drainage elbow 23.
Here, the waste water flowing into the first flow path 11 flows downward of the deodorizing cylinder 9, but a part of the waste water urges the valve body 17 toward the second flow path 13. Therefore, while the drainage is flowing in the first flow passage 11, the second flow passage 13 is blocked more firmly than in the case of no drainage, and the second flow is caused even when there is a large amount of drainage from the washing machine 100, etc. There is no backflow of drainage to the passage 13.
Then, the drainage having reached the lower end of the deodorizing cylinder 9 reverses the flow at the bottom surface of the water sealing gutter 7 and ascends the drainage flow path formed by the outer periphery of the deodorizing cylinder 9 and the inner circumference of the water sealing gutter 7. Then, the waste water reaching the notch 8 provided on the side surface of the water sealing ring 7 overflows to the outside of the water sealing hole 7 and is discharged from the discharge port 3 of the trap main body 2 toward the sewage side.

  Next, the flow of drainage when drainage is generated on the waterproof pan 200 will be described using FIG. In FIG. 10, a part of the flow of the drainage generated on the waterproof pan 200 is indicated by a two-dot chain line.

First, when drainage occurs on the waterproof pan 200, the drainage flows on the waterproof pan 200, and flows into the second flow path 13 formed in the casing body 24 through the eyelet 22 and the second inlet 12. . At this time, dust, dirt and the like larger than a predetermined size are captured by the collection portion of the tray 22 and do not enter the second flow path 13.
Next, the drainage flowed into the second flow path 13 is bent by about 90 degrees in the flow direction by the bending portion 14 of the second flow path 13 and abuts on the valve body 17. At this time, since water pressure is applied to the valve body 17 in a direction away from the valve seat 16, the second flow path 13 is opened by pivoting about the upper end thereof.
And the drainage which rotated the valve body 17 flows into the first channel 11 from the substantially horizontal direction, and flows downward of the deodorizing cylinder 9.
The subsequent flow passes through the drainage flow path formed by the outer periphery of the deodorization cylinder 9 and the inner circumference of the sealing gutter 7, as with the flow of the drainage water flowing through the first flow path 11, and sewage from the notch 8 and the discharge port 3 It is discharged towards the side.
When drainage from the waterproof pan 200 is completed, the check valve 15 rotates the valve body 17 by its own weight and abuts on the valve seat 16 to close the second flow path 13 again.

  When drainage from the washing machine 100 or the waterproof pan 200 is finished, part of the drainage that has flowed into the trap body 2 is stored inside the sealed diaphragm 7 and a part of the drainage flow path on the inner periphery of the deodorization cylinder 9 The trap function is formed by bringing the drainage flow path formed by the outer periphery of the deodorizing cylinder 9 and the inner periphery of the water sealing ring 7 into a full water (water seal) state.

In the drainage trap 1 of the present invention, the second flow path 13 is provided with the non-return valve 15 (the valve seat 16 and the valve body 17) for preventing the back flow from the first flow path 11 side. When there is a large amount of drainage, or when there is a foamy drainage, the drainage does not backflow to the second flow path 13. Since the non-return valve 15 has a structure in which the second flow path 13 is closed when there is no drainage, even in the case where the drainage flow path is filled with a fluid having a lower specific gravity than water, such as foamy drainage. It is possible to preferably prevent backflow. Here, "having a specific gravity lower than that of water" means a fluid whose mass per volume is lower than that of water by containing a large amount of air etc., although the specific gravity is not actually lower than that of water.
Further, since the valve body 17 abuts the valve seat 16 of the second flow path 13 in a substantially horizontal direction, the drainage flow path at the time of valve opening is wide, and it is possible to secure a suitable drainage flow rate. Furthermore, since the check valve 15 is provided in the deodorizing cylinder 9, the overall height of the device can be reduced.
And since the second flow passage 13 joins the first flow passage 11 in the substantially horizontal direction inside the deodorization cylinder 9, the first flow passage 11 and the second flow passage 13 form a trap function using the same sealing water. It is possible to prevent either one of the flow channels from being sealed.
Further, the deodorizing cylinder 9 has a casing body 24 inside, and the casing body 24 is detachable from the deodorizing cylinder 9. Therefore, by removing the casing body 24 from the deodorizing cylinder 9, it is possible to clean the check valve 15 etc without removing the deodorizing cylinder 9.

  The drainage trap 1 of the present invention is not limited to the above embodiment. For example, in the above embodiment, the drainage trap 1 is attached to the washing machine as the equipment and the waterproof pan 200 as the other equipment, but the equipment is a tank body such as a bath, The equipment may be a bathtub pan or a washroom pan. Also, it may be attached to a facility having two sinks called a so-called double sink, where the facility device is one sink and the other facility device is the other sink.

DESCRIPTION OF SYMBOLS 1 drainage trap 2 trap main body 3 discharge port 4 flange member 5 step part 6 protrusion part 7 sealing water pipe 8 notch 9 deodorizing cylinder 10 first class inlet 11 first channel 12 second inlet 13 second channel 14 bent section 15 Non-return valve 16 Valve seat 17 Valve body 18 Valve lid 19 Valve retainer 20 Mounting part 21 Groove part 22 Eye plate 23 Drainage elbow 24 Casing body P Packing 100 Packing machine 100 Washing machine 200 Waterproof pan

Claims (6)

With drainage outlet where drainage flows in,
A cylindrical deodorizing cylinder having a downward opening and extending downward from the drainage port;
A sealing portion for storing the lower end of the deodorization cylinder inside and storing drainage to form sealing water,
A drainage trap having a discharge port for discharging the drainage overflowing the sealing portion to the downstream side,
The deodorization cylinder is the first flow path into which drainage from equipment and equipment flows,
A second flow path into which drainage from other equipment and equipment flows,
A check valve disposed in the second flow path for preventing back flow such as drainage from the first flow path side,
The second flow path joins the first flow path inside the deodorizing cylinder ,
Check valve drain trap to the energized characterized Rukoto so as to close the second passage by waste water flowing into the deodorant cylinder when the waste water from the first flow path. The drainage trap according to claim 1, wherein the second flow path bends the flow path in the deodorization cylinder and joins the first flow path in a substantially horizontal direction. The non-return valve is a swing-type non-return valve, one end of which is rotatably fixed in the deodorizing cylinder, wherein the non-return valve abuts on the second flow path in a substantially horizontal direction. Or the drainage trap of Claim 2. 4. The drainage trap according to any one of claims 1 to 3, wherein the check valve maintains the blockage of the second flow passage when there is no inflow of drainage from the upstream side. The drainage trap according to any one of claims 1 to 4, wherein the deodorization cylinder is inclined with respect to the vertical direction as it proceeds downward. The drainage trap according to any one of claims 1 to 5, wherein
What is claimed is: 1. A drainage trap comprising a cylindrical casing body forming a flow passage inside, wherein the casing body is attached to a deodorizing cylinder to form a second flow passage.

Images