JP2011026907A - Under-floor drainage type flush toilet bowl - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an under-floor drainage type flush toilet bowl which can achieve prompt and strong generation of siphon and which can obtain water conservation effect. <P>SOLUTION: A flange 3 communicating to an under-floor drain pipe 2 is fixed on the floor surface F, and the flange 3 and the drain outlet 1c of the toilet bowl 1 are connected to each other by a drain socket 5 provided with an adjuster member 7 which can be cut for length adjustment. Thus, a drainage channel R is formed. An above-floor throttle part P1 above the floor surface F and an under-floor throttle part P2 below the floor surface F are formed inside the drainage channel R, and two-step siphon by the above-floor throttle part P1 and the under-floor throttle part P2 can be produced. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an underfloor drainage type flush toilet that drains into a drain pipe buried under the floor.

  Conventionally, as disclosed in Patent Document 1, a flange communicating with a drain pipe under the floor is fixed to the floor surface, and the flange and the toilet outlet are connected with a drain socket to drain the floor. There is an underfloor drainage flush toilet. Here, the drain socket is constituted by a drain port connecting member connected to the drain port of the toilet bowl, an adjuster member that can be cut and adjusted in length, and a drain pipe connecting member connected to the drain pipe under the floor.

JP 2008-184745 A

  In the underfloor drainage flush toilet disclosed in the above-mentioned Patent Document 1, the throttle part that activates the siphon during drainage is formed above the floor surface upstream of the adjuster member of the drain socket. The siphon was weak because of the low head drop and the low water head pressure. Further, the adjuster member of the drain socket is bent back and has a large resistance, so that the drainage flow rate per unit is small, the cleaning ability is not sufficient, and it is difficult to obtain a sufficient water saving effect.

An object of the present invention is to provide an underfloor drainage flush toilet that can strengthen a siphon and obtain a sufficient water-saving effect. In order to achieve at least a part of this object, the following measures are taken.
According to the present invention, a flange communicating with a drain pipe under the floor is fixed to the floor surface, and the drain outlet of the toilet is connected by a drain socket having an adjuster member that can be cut and adjusted in length. In the formed underfloor drainage flush toilet,
The gist of the invention is that a siphon generating upper floor throttle part above the floor surface and a siphon generating lower floor throttle part below the floor surface are formed in the drainage channel.

  In the underfloor drainage type flush toilet of the present invention, since the upper floor throttle part above the floor surface and the lower floor throttle part below the floor surface are formed in the drainage channel, the siphon is quickly generated at the upper floor throttle part. In addition, since siphons are also generated at the underfloor throttle part, it is possible to generate two-step strong siphons, achieve a powerful drainage capacity, and achieve a water-saving effect.

Moreover, in the underfloor drainage type flush toilet of the present invention, the underfloor throttle part may be formed in a portion that is swallowed by the flange of the drain socket.
If it carries out like this, a floor under-squeeze part will be formed in the part swallowed by the flange of a drain socket, and a throttle part can be arranged well under the floor.

Moreover, the underfloor drainage type flush toilet of this invention WHEREIN: The said underfloor narrowing part shall be formed in the part made to squeeze into the said drain pipe of the said flange.
If it carries out like this, the floor fixed part can be satisfactorily installed under the floor by swallowing and connecting the flange fixed to the floor surface to the drain pipe.

Moreover, in the underfloor drainage flush toilet of the present invention, the cross-sectional area of the underfloor throttle part may be set smaller than the cross-sectional area of the above-floor throttle part.
By doing so, since the cross-sectional area of the under-floor throttle part is smaller than the cross-sectional area of the above-ground throttle part, the second-stage siphon can be reliably activated under the floor, and a strong siphon can be obtained.

Moreover, in the underfloor drainage type flush toilet of the present invention, an inclined guide path for applying drainage to the inner wall of the drainage pipe may be formed on the downstream side of the underfloor throttle part.
In this way, a siphon is generated at the throttle section under the floor, and when the drainage flows down the guide path downstream, the drainage hits the inner wall of the drainage pipe. This acts as a resistance and improves the generation of the siphon under the floor. The siphon force generated under the floor can be improved, and a better water-saving effect can be obtained.

Further, the present invention fixes a flange communicating with a drain pipe under the floor to the floor surface, and connects the flange and the toilet outlet with a drain socket provided with an adjuster member that can be cut and adjusted in length. In the under-floor drainage flush toilet with a path,
In the drainage channel, an above-floor throttle part for generating siphons is formed above the floor surface, and an inclined guide channel for applying drainage to the inner wall of the drainage pipe below the floor surface. The gist is that the cross-sectional area of the guide path is set to be equal to or smaller than the cross-sectional area of the on-floor throttle part.
In this way, the drainage that flows in the guide path hits the inner wall of the drain pipe, and resistance is generated, thereby generating a siphon below the floor surface, and a siphon generated in the throttle on the floor and a siphon generated in the guide path. As a whole, the siphon power is improved and a water-saving effect is obtained.

Further, in the underfloor drainage type flush toilet in which the guide path is formed under the floor together with the above-mentioned throttle part, the guide path may be formed in the drain socket.
If it carries out like this, a guide path can be favorably arrange | positioned under a floor | bed by forming a guide path in a drain socket and connecting a drain socket to a flange.

In addition, in the underfloor drainage type flush toilet in which the guide path is formed under the floor together with the above-described throttle part, the guide path may be formed in the flange.
If it carries out like this, a guide path can be favorably arrange | positioned under a floor by inserting a flange in a drain pipe and fixing to a floor surface.

The present invention also relates to an underfloor drainage type flush toilet in which a flange communicating with a drain pipe under the floor is fixed to the floor, and a drain outlet is formed by connecting a drain outlet of the toilet to the flange. The gist of the present invention is that an upper diaphragm portion for generating siphons above the floor surface is formed, and an underfloor diaphragm portion for generating siphons is formed below the floor surface.
If it carries out like this, a siphon can be generated in two steps, an upper floor throttle part on the floor, and an underfloor throttle part under the floor, the generation of the siphon becomes quick and strong, and a good water-saving effect can be obtained.

Further, the present invention provides an underfloor drainage type flush toilet in which a flange communicating with a drain pipe under the floor is fixed to the floor surface, and a drainage channel is formed by connecting the flange and a drain outlet of the toilet bowl with a drain socket. In the road, an upper diaphragm portion for generating siphons is formed above the floor surface, and an inclined guide path is formed below the floor surface to apply drainage to the inner wall of the drain pipe. The gist of the present invention is that the cross-sectional area of the guide path is set to be equal to or smaller than the cross-sectional area of the on-floor throttle part.
In this way, siphons can be generated quickly at the top throttle on the floor, and siphons can be generated by resisting drainage in the guide path under the floor, improving the siphoning power as a whole and saving water. Is obtained.

It is a whole cross-section block diagram of the underfloor drain-type flush toilet of 1st Example. It is an expanded sectional block diagram of the structural member of the drainage channel of FIG. It is an expanded sectional block diagram of the structural member of the drainage channel of 2nd Example. It is an expanded sectional block diagram of the structural member of the drainage channel of 3rd Example. It is an expanded sectional block diagram of the structural member of the drainage channel of 4th Example. It is a cross-sectional block diagram of the underfloor drain-type flush toilet of 5th Example. It is a cross-sectional block diagram of the underfloor drain-type flush toilet of 6th Example. It is a cross-sectional block diagram of the underfloor drainage type flush toilet of 7th Example. It is a cross-sectional block diagram of the underfloor drain-type flush toilet of 8th Example.

  Next, the form for implementing this invention is demonstrated using an Example.

FIG. 1 is a cross-sectional configuration diagram of an underfloor drainage flush toilet, and FIG. 2 is an enlarged cross-sectional configuration diagram of components of a drainage channel.
A drain socket 5 is connected to the drain port 1c of the toilet body 1 of the underfloor drainage flush toilet. The downstream end of the drain socket 5 is swallowed into the flange 3, and the flange 3 is below the floor surface F. The drainage pipe 2 is buried in the vertical direction and attached.
In the toilet body 1, a trap channel 1b is formed on the rear side (the left side in the drawing) of the bowl portion 1a so as to be inclined upward, and a drain port 1c is formed on the downstream side of the trap channel 1b. A drainage channel R extending from the drainage port 1c through the drainage socket 5 and the flange 3 to the drainage pipe 2 is formed.

The drain socket 5 constituting the drainage channel R includes a drain port connecting member 6, an adjuster member 7, and a drain pipe connecting member 8.
The drain port connecting member 6 has a cylindrical structure with an open top and bottom that is connected to the drain port 1c with a rubber packing 12 interposed therebetween, and the above-mentioned floor throttle portion with a reduced cross-sectional area in the drain port connecting member 6 P1 is formed.
The adjuster member 7 extends substantially horizontally from a bent portion 7a (which is eccentric to the rear and folded back to the front side), and an upper end of the bent portion 7a is formed at the drain port connecting member. The adjuster member 7 is bonded to the drain port connecting member 6. The extension pipe 7b of the adjuster member 7 is connected to the insertion part 8a of the drain pipe connection member 8 in a plug-in form by cutting the side connected to the drain pipe connection member 8 and adjusting the length. . In addition, the position shift between the drain pipe 2 and the drain port 1c can be absorbed by adjusting the length of the extension pipe 7b.
The flange 3 is fixed to the floor surface F by screws 4 and 4 on the upper surface of the drain pipe 2 buried under the floor. The flange 3 has a tubular shape hanging down from the center of the fixing portion 3a fixed to the floor surface F. The cylindrical portion 3 b is integrally formed, and the cylindrical portion 3 b is inserted into the drain pipe 2 and connected to the drain pipe 2.

A drain pipe connecting member 8 of a drain socket 5 is connected to the flange 3 fixed to the floor surface F with a gasket 13 interposed. In this example, the drain pipe connecting member 8 is suspended from the lower end of the drain pipe connecting member 8. A stagnation part 9 is formed continuously in a shape, and an inclined cylinder part 11 having an inclined shape is further integrally formed at the lower end of the cylindrical stagnation part 9. The swallow-in part 9 and the inclined cylinder part 11 integrally formed with the drain pipe connecting member 8 are installed in a state of being inserted into the cylinder part 3b of the flange 3 and swallowed.
The inclined cylinder portion 11 is integrated with a smaller diameter than the inner diameter of the squeezed portion 9, and a step portion 10 that narrows the drainage channel R is formed on the upper end side of the inclined tube portion 11, and an inner portion of the step portion 10. Is the under-floor throttle part P2 having a reduced cross-sectional area. The cross-sectional area of the underfloor throttle part P2 is set smaller than the cross-sectional area of the above-floor throttle part P1.

In the drainage channel R having such a configuration, when draining, the drainage pushed into the drainage port 1c from the trap channel 1b is squeezed by the above-mentioned throttle part P1 when flowing down the drainage port connecting member 6 of the drainage socket 5. Siphon is generated. Drainage is sucked by the generated siphon to the adjuster member 7 side, passes through the drainage pipe connecting member 8, flows down into the drainage pipe 2 through the swallowing part 9, and at this time, the underfloor throttle part P2 is formed. Therefore, siphon is generated also in the underfloor throttle part P2, and the drainage is sucked more strongly and drained to the drainage pipe 2 side.
Further, when the drainage flows down along the inclined cylinder part 11, it flows down the inclined guide path RG formed in the inclined cylinder part 11 and hits the inner wall of the drainage pipe 2. A resistance is generated in the drained water, and the generated resistance assists the siphon force of the siphon generated in the underfloor throttle part P2, and a stronger siphon force is generated.

In this way, since the first stage siphon is generated in the upper throttle part P1 above the floor surface F, the siphon is generated early in this floor throttle part P1 and the waste water can be sucked into the drainage channel R. Yes, during the continuation of the first-stage siphon, the second-stage siphon is generated in the under-floor throttle part P2 and the guide path RG formed below the floor surface F, and the drainage is strongly drained in the later stage of cleaning. The water can be drained into the pipe 2, and the water can be drained more strongly with a smaller amount of water than before, so that a water-saving effect can be obtained.
Note that the guide path RG formed by the inclined cylinder portion 11 has a function of assisting the siphon. The inclined cylinder portion 11 and the guide path RG are omitted, and the under floor restricting portion P2 is provided at the lower end side of the swallowing portion 9. It is good also as a thing of the structure which formed only.

Next, FIG. 3 shows a second embodiment. FIG. 3 is an enlarged view of components of the drainage channel R, and the toilet body 1 is the same as that of FIG.
In the second embodiment of FIG. 3, the underfloor throttle part P2 and the guide path RG are formed on the flange 3.
The drainage socket 5 constituting the drainage channel R includes a drainage port connecting member 6, an adjuster member 7, and a drainage pipe connecting member 8 in which a floor throttle part P1 having a reduced cross-sectional area is formed. The lower end of the pipe connecting member 8 is connected to the flange 3 with a gasket 13 interposed.
The flange 3 includes a fixing portion 3a fixed to the floor surface F by screws 4, a cylindrical portion 3b that is integrally suspended at the central portion of the fixing portion 3a, and an inner peripheral side in the cylindrical portion 3b. A step portion 3c having a step shape and an inclined cylindrical portion 3d integrally formed in an inclined manner downward from the step portion 3c are formed, and an inner portion of the step portion 3c becomes an underfloor throttle portion P2 having a reduced cross-sectional area. An inclined guide path RG is formed in the inclined cylindrical portion 3d. In addition, the cross-sectional area of the underfloor throttle part P2 of the flange 3 is set smaller than the cross-sectional area of the above-floor throttle part P1 formed in the drain outlet connection member 6 of the drain socket 5.
In this way, when the cylindrical portion 3 b is inserted into the drain pipe 2 and the flange 3 is fixed to the floor surface F with the screws 4, the under floor throttle portion P <b> 2 and the guide path RG are disposed below the floor surface F. In this state, the drain socket 5 can be connected and mounted on the flange 3.

Also in this example, the waste water from the toilet body 1 side flows down from the drain port 1 c into the drain port connecting member 6, siphon is generated at the floor throttle P <b> 1 in the drain port connecting member 6, and the drainage is the adjuster member 7. The second stage siphon is generated in this portion, and the drainage flowing along the inclined cylindrical portion 3d on the downstream side of the lower floor throttling portion P2 is drained from the drain pipe 2. It becomes resistance when it hits the wall surface of this, and the generated siphon force of the siphon generated at the underfloor throttle part P2 is assisted by this generated resistance, so that a stronger siphon force is generated.
In this way, drainage can be drained more strongly into the drainpipe 2 by the first siphon generated at the upper throttle part P1 and the second siphon generated at the lower throttle part P2. A good water-saving effect can be obtained.
In FIG. 3, even if the inclined cylinder portion 3 d formed integrally with the flange 3 is omitted and only the underfloor throttle portion P <b> 2 is formed in the flange 3, substantially the same effect can be obtained. it can.

Next, FIG. 4 shows a third embodiment and is an enlarged cross-sectional view of components constituting the drainage channel. The toilet body is the same as that shown in FIG.
The drainage channel R includes a drainage socket 5, a flange 3, and a drainage pipe 2, and the drainage socket 5 includes a drainage port connecting member 6 in which a floor-squeezed portion P <b> 1 having a reduced cross-sectional area is formed, and an adjuster member 7. And a drainage pipe connecting member 8, and a swallowing portion 9 is continuously formed integrally on the lower end side of the drainage pipe connecting member 8, and the lower end side of the swallowing portion 9 is inclined in an inclined manner. A cylindrical portion 11 is integrally formed, and an inclined guide path RG is formed in the inclined cylindrical portion 11.

The flange 3 fixed to the floor surface F with the screw 4 is formed with a cylindrical portion 3b hanging down from the fixing portion 3a, and this cylindrical portion 3b is connected in a squeezed manner in a drain pipe 2 embedded under the floor. .
The squeezed portion 9 and the inclined cylindrical portion 11 are disposed by being squeezed inside the cylindrical portion 3 b of the flange 3.

  Even in the drainage channel R having such a structure, the drainage flowing down from the toilet body 1 side through the drain outlet 1c is generated by the siphon at the upper throttle part P1 and sucked downstream, and further, the inclined cylinder part 11 below the floor. When the water flows down, resistance is caused by the drainage hitting the inner wall of the drainage pipe 2, and a smaller siphon is generated in this resistance. As a whole, the siphon on the floor throttle P1 and the siphon on the guide path RG As a result, the siphon power is improved and a water-saving effect is obtained.

Next, FIG. 5 is an enlarged cross-sectional view of a drainage channel showing a fourth embodiment.
In FIG. 5, the drainage channel R is constituted by a drainage socket 5, a flange 3, and a drainage pipe 2, and the drainage socket 5 includes a drainage port connecting member 6 in which a floor throttle part P <b> 1 having a reduced cross-sectional area is formed. The drainage pipe connection member 8 is composed of an adjuster member 7 and a drainage pipe connection member 8 which is continuously and integrally formed with a swallow portion 9 on the lower end side of the drainage pipe connection member 8. An inclined portion 11 a that inclines inwardly and narrows the drainage channel R is integrally formed, and an underfloor throttle portion P <b> 2 is formed on the lower end side of the drainage pipe connecting member 8 by the inclined portion 11 a. The cross-sectional area of the underfloor restricting portion P2 is set smaller than the cross-sectional area of the above-described restrictor P1 of the floor. The flange 3 fixed to the floor surface F with the screw 4 is formed as a cylindrical portion 3b hanging from the fixing portion 3a. And this cylinder part 3b is connected in the drainage pipe 2 embed | buried under the floor in the shape of swallowing.
The squeezed portion 9 and the inclined portion 11a are disposed by being squeezed inside the cylindrical portion 3b of the flange 3.
Also in this example, the waste water from the toilet body 1 side flows down from the drain port 1 c into the drain port connecting member 6, siphon is generated at the floor throttle P <b> 1 in the drain port connecting member 6, and the drainage is the adjuster member 7. Then, the drainage is further squeezed by the underfloor squeeze part P2, and a second-stage siphon is generated in this portion, and a stronger siphon force is generated.

Next, FIG. 6 shows a fifth embodiment. In FIG. 6, the diameter is gradually reduced toward the lower side in an inclined manner inside the cylindrical portion 3b of the flange 3 inserted into the drain pipe 2. An inclined portion 3e is integrally formed, and an underfloor throttle portion P2 and an inclined guide path RG are formed inside the inclined portion 3e.
The drain socket 5 that constitutes the drainage channel R includes a drain port connecting member 6, an adjuster member 7, and a drain pipe connecting member 8 in which a floor throttle part P1 having a reduced cross-sectional area is formed. The lower end of the pipe connecting member 8 is connected to the flange 3 with a gasket 13 interposed.
Even in such a configuration, the waste water from the toilet body 1 side flows down from the drain port 1c into the drain port connecting member 6, and siphons are generated at the upper throttle part P1 in the drain port connecting member 6, and The drainage flowing inside the inclined portion 3e hits the inner wall of the drainpipe 2 to add resistance. Further, the drainage is squeezed by the underfloor restricting portion P2, and siphon is generated in this portion. It will be obtained.

Next, FIG. 7 shows a sixth embodiment. In the sixth embodiment, the flange 3 connected to the drain pipe 2 embedded in the floor surface F in an insertion manner is fixed to the floor surface F with screws 4. The drainage port 1c of the toilet body 1 is connected to the flange 3 with a gasket 13 interposed.
That is, the toilet body 1 is tilted upward from the bowl portion 1a to form a trap channel 1b, and a hanging channel 1d is formed in a hanging shape from the rear end side of the trap channel 1b. The floor throttle part P1 with a reduced diameter is formed on the lower end side, and further, a horizontal path 1f is formed in the toilet body 1 substantially horizontally from the floor throttle part P1, and a drainage channel R is formed in the toilet body 1 It is.

The flange 3 connected via the gasket 13 to the drain outlet 1c of the toilet body 1 is integrally formed with a cylindrical portion 3b in a hanging manner at the center of the fixed portion 3a fixed to the floor F. From the cylindrical portion 3b, A stepped portion 3c that protrudes inward and has a reduced diameter is integrally formed, and the stepped portion 3c forms an underfloor throttle portion P2 having a reduced cross-sectional area. An inclined cylindrical portion 3d is integrally formed to be inclined downward from the under floor throttle portion P2, and an inclined guide path RG is formed in the inclined cylindrical portion 3d.
The cross-sectional area of the under-floor throttle part P2 is set smaller than the cross-sectional area of the above-floor throttle part P1 in the toilet body 1, and the cross-sectional area of the guide path RG is set to be equal to or smaller than the cross-sectional area of the above-floor throttle part P1. .

In this way, by fixing the flange 3 integrally formed with the underfloor throttle part P2 and the inclined cylinder part 3d to the floor surface F, and connecting the drain outlet 1c of the toilet body 1 to the flange 3, the trap channel 1b during drainage. The waste water pushed into the floor is squeezed by the above-floor throttle part P1 of the down passage 1d, and siphon is generated. Drained water is sucked by the generated siphon and flows down through the horizontal path 1f into the cylindrical portion 3b of the flange 3 from the drain port 1c. At this time, the underfloor restricting portion P2 is formed, so this underfloor restricting portion P2 However, siphon is generated, and the drainage is sucked more strongly and drained to the drainage pipe 2 side.
Further, when the drainage flows down along the inclined cylindrical portion 3d, it flows down in the inclined guide path RG formed in the inclined cylindrical portion 3d and hits the inner wall of the drainage pipe 2. A resistance is generated in the drained water, and the generated resistance assists the siphon force of the siphon generated in the underfloor throttle part P2, and a stronger siphon force is generated.

Moreover, in such a type, water saving can be achieved only by replacing the flange 3 of the old toilet with the flange 3 having the shape as shown in FIG.
The underfloor throttle part P2 and the inclined cylinder part 3d may be formed separately in the cylinder part 3b of the flange 3. Further, the shape may be a shape that does not include the inclined cylindrical portion 3d only by the underfloor throttle portion P2.

Next, FIG. 8 shows a seventh embodiment, in which the diameter is reduced toward the lower side in an inclined manner inside the cylindrical portion 3b of the flange 3 connected to the drain pipe 2 buried under the floor. The part 3e is provided integrally, and the underfloor throttle part P2 and the guide path RG are formed inside the inclined part 3e.
Such a flange 3 is fixed to the floor surface F via screws 4 and attached to the drain pipe 2 in a connected manner, and in this state, the drain port 1c of the toilet body 1 is disposed on the flange 3 with the gasket 13 interposed therebetween. Can be connected.
Even in such a configuration, the drainage pushed into the trap channel 1b during drainage is squeezed by the on-floor restricting portion P1 of the hanging channel 1d to generate a siphon, and the drainage is sucked by the generated siphon and the horizontal channel 1f. The drainage port 1c flows down into the cylindrical portion 3b of the flange 3, but at this time, since the inclined portion 3e is reduced in diameter downward, a siphon is generated at the portion of the underfloor throttle portion P2. Furthermore, the drainage that flows along the guide path RG hits the inner wall of the drain pipe 2, so that resistance is generated, the siphon force is improved as a whole, and a water-saving effect is obtained.

Next, FIG. 9 shows an eighth embodiment.
In this example, the flange 3 inserted into the drain pipe 2 and fixed to the floor surface F is composed of a fixed portion 3a and a hanging cylindrical portion 3b, and a separate insertion is provided in the cylindrical portion 3b. The wearing member 14 is inserted.
The insertion member 14 is provided with an inclined portion 14b that forms a guide path RG that is reduced in diameter toward the lower side inside the cylindrical portion 14a that is inserted in a substantially tight manner on the inner periphery of the cylindrical portion 3b of the flange. It is integrally formed.
By inserting the separate insertion member 14 into the flange 3 in this way, the underfloor throttle portion P2 and the inclined guide path RG can be formed on the inner peripheral side of the cylindrical portion 3b of the flange 3. Even in such a configuration, the drainage pushed into the trap channel 1b during drainage is squeezed by the floor top throttle portion P1 of the hanging channel 1d to generate a siphon, and the drainage is sucked by the generated siphon, and the horizontal channel Although it flows down into the insertion member 14 from the drain port 1c through 1f, since the inclined portion 14b is reduced in diameter toward the lower side at this time, siphon is generated in the portion of the underfloor throttle portion P2. Further, the drainage flowing along the guide path RG hits the inner wall of the drainage pipe 2 so that resistance is generated, the siphon force is improved as a whole, and a water saving effect is obtained.
In such a structure, a good water-saving effect can be achieved by attaching a separate insertion member 14 to the existing flange 3.

DESCRIPTION OF SYMBOLS 1 Toilet body 1a Bowl part 1b Trap flow path 1c Drainage port 1d Drooping path 1f Horizontal path 2 Drainage pipe 3 Flange 3a Fixing part 3b Cylindrical part 3c Step part 3d Inclined cylinder part 3e Inclined part 4 Screw 5 Drainage socket 6 Drainage port connection member 7 Adjuster member 7a Bent part 7b Extension pipe 8 Drain pipe connection member 9 Pinch part 10 Step part 11 Inclined cylinder part 11a Inclined part 14 Inserting member 14a Cylindrical part 14b Inclined part P1 Floor-squeezed part P2 Floor-squeezed part R Drainage channel RG Guide road

Claims (10)

A floor communicating with a drain pipe under the floor is fixed to the floor surface, and the drain outlet of the toilet is connected with a drain socket having an adjuster member that can be cut and adjusted in length to form a floor under the drainage channel. In drainage flush toilets,
In the drainage channel,
An underfloor drainage type flush toilet comprising a siphon generating top floor for siphon generation above the floor and a siphon generating bottom floor for siphon generation below the floor.   The underfloor drainage type flush toilet according to claim 1, wherein the underfloor throttle part is formed in a portion that is swallowed by the flange of the drain socket.   The underfloor drainage flush toilet according to claim 1, wherein the underfloor throttle part is formed in a portion of the flange that is swallowed into the drain pipe.   4. The underfloor drainage flush toilet according to claim 1, wherein the cross-sectional area of the underfloor restrictor is set to be smaller than the cross-sectional area of the underfloor restrictor.   5. An inclined guide path for applying drainage to the inner wall of the drain pipe is formed on the downstream side of the underfloor throttle part. Under-floor drainage flush toilet as described in 1. A floor communicating with a drain pipe under the floor is fixed to the floor surface, and the drain outlet of the toilet is connected with a drain socket having an adjuster member that can be cut and adjusted in length to form a floor under the drainage channel. In drainage flush toilets,
In the drainage channel,
An upper diaphragm portion for generating siphons is formed above the floor surface, and an inclined guide path is formed below the floor surface for applying drainage to the inner wall of the drain pipe. The underfloor drainage flush toilet is characterized in that the cross-sectional area of is set to be equal to or smaller than the cross-sectional area of the above-mentioned throttle part.   The underfloor drainage type flush toilet according to claim 6, wherein the guide path is formed in the drain socket.   The underfloor drainage flush toilet according to claim 6, wherein the guide path is formed in the flange. In the underfloor drainage type flush toilet in which a flange communicating with the drain pipe under the floor is fixed to the floor surface, and a drainage channel is formed by connecting a drain outlet of the toilet to the flange.
In the drainage channel,
An underfloor drainage flush toilet characterized in that an upper floor restriction part for generating siphons above the floor surface is formed, and an underfloor restriction part for generating siphons is formed below the floor surface. In the underfloor drainage type flush toilet in which the flange communicating with the drain pipe under the floor is fixed to the floor surface, and the drain outlet of the toilet bowl is connected by a drain socket to form a drainage channel.
In the drainage channel,
An upper diaphragm portion for generating siphons is formed above the floor surface, and an inclined guide path is formed below the floor surface for applying drainage to the inner wall of the drain pipe. The underfloor drainage flush toilet is characterized in that the cross-sectional area of is set to be equal to or smaller than the cross-sectional area of the above-mentioned throttle part.

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