JP2020180470A - Flush toilet - Google Patents

Abstract

To provide a flush toilet capable of satisfactorily discharging filth.SOLUTION: A flush toilet 1 includes a toilet bowl 10 and a trap drainage channel 20. The toilet bowl 10 communicates with a trap drainage channel 20 downstream thereof. The trap drainage channel 20 has an upward flow path 23, a first downward flow path 25, and a second downward flow path 27. The upward flow path 23 is formed extending upward. The first downward flow path 25 continues to the downstream end of upward flow path 23 and formed in a flat slope with bottom 25A descending downstream. The second downward flow path 27 opens to the bottom 25A of the first downward flow path 25 extending downward.SELECTED DRAWING: Figure 4

Description

The present invention relates to a flush toilet.

Patent Document 1 shows a conventional toilet bowl. This toilet bowl includes a bowl section and a drain trap section. The bowl part receives filth. The drain trap portion has an inlet portion, an ascending pipe, a descending pipe, and an intermediate pipe. The inlet is connected below the bowl. The ascending line is connected to the inlet and extends upward. The descending pipeline extends downward toward the drainage pipe. The intermediate pipeline is arranged in the middle so as to connect the ascending pipeline and the descending pipeline. The intermediate pipeline has a retention surface. The retention surface is formed so as to have a downward slope from the upstream side to the downstream side, and filth is temporarily retained when the toilet bowl is washed. A contraction portion is formed on the retention surface. The condensing portion is formed so that the flow path area of the drainage becomes smaller from the upstream side to the downstream side. In this toilet bowl, by retaining filth on the retention surface, the lower limit water level of the drain trap portion and the water level of the accumulated water in the bowl portion can be raised by the amount of filth, and the head pressure can be temporarily increased. Then, since the condensing portion is formed on this retention surface, the flow velocity of the drainage can be increased. With these, it is said that this toilet bowl can improve the discharge performance.

Japanese Unexamined Patent Publication No. 2018-112004

However, in the toilet bowl of Patent Document 1, the flow path resistance is increased by forming a retention surface for retaining filth in the drain trap portion and forming a condensing portion in which the flow path is reduced. In this case, there is a risk of further retention of filth.

The present invention has been made in view of the above-mentioned conventional circumstances, and an object to be solved is to provide a flush toilet that can satisfactorily discharge filth.

The flush toilet of the present invention
It is equipped with a toilet bowl and a trap drainage channel that communicates with the downstream side of the toilet bowl.
The trap drainage channel
An ascending flow path formed extending upward,
A first descending flow path formed by a flat inclined surface that is continuous with the downstream end of the ascending flow path and whose bottom surface descends toward the downstream side.
A second descending flow path that opens to the bottom surface of the first descending flow path and extends downward,
have.

In this flush toilet, the bottom surface of the first descending flow path of the trap drainage channel is formed by a flat inclined surface. As a result, it is possible to suppress the retention of filth in the first descending flow path, and it is possible to suppress the deterioration of drainage performance.

Therefore, the flush toilet of the present invention can satisfactorily discharge filth.

The above "flat" is not intended to be completely flat, but is substantially flat, such as one that is curved to the extent that it does not significantly affect the retention of filth and the flow of washing water. Also includes.

It is a top view of the flush toilet which concerns on Example 1. FIG. It is a left side view of the flush toilet which concerns on Example 1. FIG. It is a figure which shows the toilet bowl apparatus provided with the flush type toilet bowl which concerns on Example 1, and is the cross-sectional view corresponding to line III-III of FIG. It is a perspective sectional view of the flush toilet which concerns on Example 1. FIG. It is a figure which shows the flush toilet which concerns on Example 1, and is the cross-sectional view corresponding to the VV line of FIG. FIG. 5 is an enlarged cross-sectional view of a main part of the flush toilet according to the first embodiment. It is an enlarged view of the main part in the cross section of VII-VII of FIG. FIG. 6 is a sectional view taken along line VIII-VIII of FIG. It is an enlarged view of the main part in the IX-IX line cross section of FIG. FIG. 6 is a cross-sectional view taken along line XX of FIG. FIG. 6 is a sectional view taken along line XI-XI of FIG.

Preferred embodiments of the present invention will be described.

In the flush toilet of the present invention, the width of the bottom surface of the first descending flow path can be formed larger than the opening diameter of the second descending flow path. In this case, since the flow path area in the first descending flow path can be easily formed to be larger than the flow path area in the second descending flow path, a flush toilet that suppresses the retention of filth can be easily realized.

In the flush toilet of the present invention, the length of the bottom surface of the first descending flow path may be formed larger than the opening diameter of the second descending flow path. In this case, since the inclined surface can be made long, the circulating washing water can be rectified. As a result, the filth can be smoothly washed away and the retention can be suppressed.

Next, Example 1 which embodies the flush toilet of the present invention will be described with reference to the drawings. In the following description, the vertical direction is the vertical direction (the vertical direction of FIGS. 2, 3, 6, 8, 10, and 11) when the flush toilet is installed, and the front-back direction. The side where the toilet bowl is formed is the front, the side where the trap drainage channel is formed is the rear (in FIGS. 2 and 3, the right side is the front side and the left side is the rear side), and the left and right directions are flushed. The left and right sides (left and right in FIGS. 1 and 5) viewed from the front (toilet bowl side) of the flush toilet with the toilet bowl installed.

<Example 1>
The flush toilet 1 of the first embodiment is a flush toilet. As shown in FIGS. 1 to 4, the flush toilet 1 includes a toilet bowl portion 10, a trap drainage channel 20, a peripheral wall portion 30, a water guide portion 40, and a tank installation portion 50.

The toilet bowl portion 10 receives filth and circulates washing water for cleaning the filth. As shown in FIGS. 1, 3 and 4, the toilet bowl portion 10 has an upper wall portion 11, an intermediate wall portion 15, a lower wall portion 17, and a bottom wall portion 19. The upper wall portion 11 forms the upper peripheral edge of the toilet bowl portion 10. The upper wall portion 11 has a band shape that rises in the vertical direction, and is slightly inclined outward toward the upper side. Further, the upper end peripheral edge of the upper wall portion 11 has a substantially elliptical shape when viewed from above. The upper wall portion 11 is formed with a spout 11A having a lateral direction on the left side of the center on the left and right sides on the rear side. The water spouting port 11A discharges the washing water supplied from the water guiding portion 40 into the toilet bowl portion 10.

As shown in FIGS. 1, 3 and 4, the intermediate wall portion 15 forms the front-rear surface and the left-right side surface of the toilet bowl portion 10 below the upper wall portion 11. That is, the intermediate wall portion 15 gradually inclines downward from the lower ends on the front-rear side and the left-right side of the upper wall portion 11 and expands.

The lower wall portion 17 and the bottom wall portion 19 form a recess 13 in the lower portion of the toilet bowl portion 10. As shown in FIGS. 1, 3 and 4, the lower wall portion 17 forms the front-rear surface and the left-right side surface of the toilet bowl portion 10 inside and below the intermediate wall portion 15. The lower wall portion 17 has a tubular shape that rises in the vertical direction, and is slightly inclined inward from the lower end of the intermediate wall portion 15 downward. As shown in FIG. 3, the bottom wall portion 19 forms the bottom surface of the toilet bowl portion 10 inside and below the lower wall portion 17. The bottom wall portion 19 is slightly inclined downward from the lower end of the lower wall portion 17 toward the inside. The bottom wall portion 19 is formed with an inflow portion X of the trap drainage channel 20 at the rear portion. As shown in FIG. 3, in the flush toilet 1, the water reservoir surface R is formed above the upper surface of the bottom wall portion 19.

The trap drainage channel 20 is formed so as to communicate with the downstream side of the toilet bowl portion 10. The trap drainage channel 20 is provided in the lower part of the toilet bowl portion 10 to form a pool of water. The height of the pool surface R in the toilet bowl portion 10 is determined by the height of the top C of the trap drainage channel 20. The trap drainage channel 20 extends rearward from the toilet bowl portion 10. The trap drainage channel 20 is a so-called S trap. As shown in FIGS. 3 to 11, the trap drainage channel 20 has an introduction flow path 21, an ascending flow path 23, a first descending flow path 25, and a second descending flow path 27.

The upstream end of the introduction flow path 21 is continuous with the inflow portion X of the trap drainage channel 20 formed in the bottom wall portion 19 of the toilet bowl portion 10. That is, the trap drainage channel 20 communicates with the downstream side of the toilet bowl portion 10. The introduction flow path 21 extends downward from the lower end rear portion of the toilet bowl portion 10 and is curved rearward toward the downstream side. As shown in FIGS. 3, 4, 6, and 8, the downstream end of the introduction flow path 21 faces the horizontal direction and opens rearward. The lower end A of the downstream end of the introduction flow path 21 is the lowermost end of the trap drainage channel 20. Further, the front end B of the upstream end of the introduction flow path 21 is the front end of the inflow portion X, and is the front end of the trap drainage channel 20. Further, the upstream end of the introduction flow path 21 is the inflow portion X, and the front end of the inflow portion X is the front end B of the introduction flow path 21.

The ascending flow path 23 is continuous with the opening at the downstream end of the introduction flow path 21. That is, the lower end of the upstream end of the ascending flow path 23 is the lower end A of the downstream end of the introduction flow path 21. The ascending flow path 23 is inclined diagonally backward toward the upper side. The downstream end of the ascending flow path 23 faces horizontally and opens rearward. The lower end of the downstream end of the ascending flow path 23 is the top C in the trap drainage channel 20. As shown in FIGS. 10 and 11, the top C extends substantially horizontally in the left-right direction.

As shown in FIG. 6, in this embodiment, the inclination angle θ2 of the ascending flow path 23 is larger than the inclination angle θ1 of the introduction flow path 21. Specifically, the inclination angle θ2 of the ascending flow path 23 with respect to the horizontal plane is about 70 °, and the inclination angle θ1 of the introduction flow path 21 with respect to the horizontal plane is about 60 °. As described above, in this embodiment, both the inclination angle θ1 of the introduction flow path 21 and the inclination angle θ2 of the ascending flow path 23 are set to have a size of 45 ° or more. By forming the introduction flow path 21 and the ascending flow path 23 in this way, it is possible to form the trap drainage channel 20 whose size is suppressed in the front-rear direction.
In the case of this embodiment, the inclination angles θ1 and θ2 are the inclination angles of the linear portions of the introduction flow path 21 and the ascending flow path 23. When the introduction flow path or the ascending flow path is curved, the inclination angles θ1 and θ2 may be the inclination angles of the entire curved portion by observing the curved portion on average.

Further, as shown in FIGS. 7 to 11, in this embodiment, the trap drainage channel 20 is a region from the inflow portion X, which is the inlet of the introduction flow path 21, to the top portion C, which is the downstream end of the ascending flow path 23. In the cross section of the flow path, the size in the left-right direction is formed larger than the size in the orthogonal direction in the left-right direction. By forming the introduction flow path 21 and the ascending flow path 23 in this way, it is possible to form the trap drainage channel 20 in which not only the size in the front-rear direction but also the size in the vertical direction is suppressed.
In this embodiment, the cross section of the flow path from the region below the pool surface R as the intermediate position of the rising flow path 23 to the top C, which is the downstream end of the rising flow path 23, is also in the left-right direction. The size is formed larger than the size in the orthogonal direction in the left-right direction. For the region near the downstream end of the ascending flow path and the region near the downstream end of the introduction flow path (upstream end of the ascending flow path), the size in the direction orthogonal to the left-right direction is formed larger than that in the left-right direction. May be good. Even if the size of the flow path cross section of these regions is larger in the direction orthogonal to the left-right direction than the size in the left-right direction, the influence on the size of the trap drainage channel in the front-rear direction is small. Further, by making the size of the flow path cross section of these regions orthogonal to the left-right direction smaller than the size in the left-right direction, it is possible to contribute to suppressing the size of the trap drainage channel in the vertical direction.

As shown in FIGS. 3 to 5, the first descending flow path 25 is continuous with the opening at the downstream end of the ascending flow path 23. That is, the lower end of the upstream end of the first descending flow path 25 is the lower end of the downstream end of the ascending flow path 23, and is the top C of the trap drainage channel 20. The first descending flow path 25 is a flow path having a substantially rectangular cross-sectional shape. The first descending flow path 25 extends rearward. In the first descending flow path 25, the lower surface of the inner surface, that is, the bottom surface 25A is slightly inclined downward toward the downstream side (rear). As shown in FIGS. 3 to 5, the bottom surface 25A of the first descending flow path 25 is formed of a flat inclined surface. Specifically, the bottom surface 25A is substantially horizontal in the left-right direction as shown in FIGS. 10 and 11, and is directed backward with a substantially constant gradient in the front-rear direction as shown in FIGS. 3 and 4. It is formed in a flat shape that inclines downward as it increases.

The downstream end of the first descending flow path 25 is closed toward the rear. As shown in FIG. 5, the side surface of the inner surface of the first descending flow path 25 is formed with a substantially constant width W from the upstream end to the downstream side. Further, as shown in FIG. 3, the upper surface 25B of the inner surface of the first descending flow path 25 extends rearward at a substantially constant height. That is, the first descending flow path 25 is formed in a form in which the vertical width gradually increases from the upstream end toward the downstream side.

As shown in FIGS. 3 to 5 and 11, the second descending flow path 27 is a flow path having a substantially circular cross-sectional shape. The second descending flow path 27 is open at the downstream end of the bottom surface 25A of the first descending flow path 25. The second descending flow path 27 extends in the vertical direction, and its downstream end opens downward. A drainage socket 70 is connected to the lower end of the second descending flow path 27. The drainage socket 70 of this embodiment is connected to the lower end of the second descending flow path 27, and is connected to a drainage pipe P that passes under the trap drainage channel 20 and extends forward to be pulled out to the floor surface F. Be connected.
The drainage socket 70 can have a distance (drainage core) of about 200 mm to 550 mm from the wall surface Y behind the flush toilet 1 to the center of the drainage pipe P by cutting and adjusting the length.

As shown in FIG. 5, the opening diameter D of the second descending flow path 27 in the bottom surface 25A of the first descending flow path 25 is smaller than the size of the bottom surface 25A in the width direction. In other words, the width W of the bottom surface 25A of the first descending flow path 25 is larger than the opening diameter D of the second descending flow path 27. Further, the flow path area of the first descending flow path 25 is larger than the flow path area of the second descending flow path 27.
Further, the opening diameter D of the second descending flow path 27 is smaller than the front-back distance from the opening front end of the second descending flow path 27 to the front end of the bottom surface 25A of the first descending flow path 25 (to the top C). In other words, the length L of the bottom surface 25A of the first descending flow path 25 is larger than the opening diameter D of the second descending flow path 27.

As shown in FIG. 3, a heater H1 for preventing freezing is attached to the trap drainage channel 20. The heater H1 is composed of a heating element composed of a nichrome wire and an aluminum sheet that generate heat when energized. The heater H1 has a tapered tubular shape that opens vertically, and is attached so as to wind around the front outer peripheral surface of the introduction flow path 21 and the rear outer peripheral surface of the ascending flow path 23. The heater H1 is attached to the trap drainage channel 20 in a form in which the lower end surface 20A of the trap drainage channel 20 at a position corresponding to the drainage socket 70 described later is exposed. Therefore, the position of the lower end surface 20A of the trap drainage channel 20 can be formed closer to the floor surface F as compared with the trap drainage channel to which the heater that covers the lower end surface is attached. The outer peripheral surface of the heater H1 is covered with a cushioning material H2 having a fireproof function, and the outer peripheral surface of the cushioning material H2 and the lower end surface 20A of the trap drainage channel 20 are covered with a dew-proof material H3 having a heat insulating function. There is. Like the heater H1, the cushioning material H2 has a tapered tubular shape that opens vertically. For this reason, the lower end surface 20A of the trap drainage channel 20 is configured to face the inner surface of the dew-proof material H3 that covers the outermost side of the trap drainage channel 20.

As shown in FIG. 3, the trap drainage channel 20 has an introduction flow path 21 rather than a distance in the front-rear direction from the lower end A to the front end B of the introduction flow path 21 in the shape of the central cross section of the flush toilet 1 in the left-right direction. It is formed in a form substantially equal to the distance in the front-rear direction from the lower end A (the lower end of the upstream end of the ascending flow path 23) to the top C.

As shown in FIG. 2, the peripheral wall portion 30 is provided so as to be connected around the toilet bowl portion 10 and the trap drainage channel 20. The space below the toilet bowl portion 10 and the trap drainage channel 20 is invisible from the outside by the peripheral wall portion 30. The peripheral wall portion 30 has a front portion 31 that surrounds the front and sides of the toilet bowl portion 10, and a rear portion 32 that surrounds the lower side and the rear of the trap drainage channel 20. The front portion 31 and the rear portion 32 are formed so as to rise upward from the lower end surface which becomes the contact surface with the floor surface F when installed. The upper end of the front portion 31 extends to the upper end of the toilet bowl portion 10. As shown in FIGS. 7 to 11, the rear portion 32 is connected so that the upper end of the side portion is abutted against the outer wall surface of the trap drainage channel 20 from the side. As shown in FIG. 2, the upper end of the side portion of the rear portion 32 is formed to be curved from the upstream end to the downstream end of the introduction flow path 21 in the side view in the introduction flow path 21 of the trap drainage channel 20. Further, the upper end of the side portion of the rear portion 32 is inclined in the ascending flow path 23 of the trap drainage channel 20 from the upstream end to the downstream end of the ascending flow path 23 in the side view as shown in FIG. It rises and extends in a form that slopes more gently than. Further, the upper end of the side portion of the rear portion 32 is substantially horizontal in the first descending flow path 25 of the trap drainage channel 20 from the upstream end to the rear of the first descending flow path 25 in the side view, as shown in FIG. It is extending.

As shown in FIGS. 1 to 4, the water guide portion 40 is formed behind the toilet bowl portion 10 and above the trap drainage channel 20. The water guiding portion 40 is formed so as to be surrounded by the rear portion of the upper wall portion 11 of the toilet bowl portion 10, the bottom surface portion 41, the left and right surface portions 43, the rear surface portion 45, and the upper surface portion 47. Washing water flows through the water guide section 40. The water guide unit 40 communicates with the water discharge port 11A, and when the toilet bowl is washed, the wash water is supplied into the toilet bowl portion 10 through the water discharge port 11A.

As shown in FIGS. 3 and 4, the bottom surface portion 41 extends rearward continuously to the lower end of the rear portion of the upper wall portion 11 of the toilet bowl portion 10. The upper surface of the bottom surface portion 41 forms the lower surface 40A of the water conducting portion 40. The bottom surface portion 41 has a central front end edge, left and right front end edges, left and right end edges, and a rear end edge when viewed from above. The central front edge is curved along the rear of the upper end of the toilet bowl 10. The left and right front edge edges are inclined rearward from both ends of the central front edge edge toward the left and right outward directions. The left and right edges extend parallel to the rear from the outer edges of the left and right front edges. The trailing edge extends linearly and connects the trailing ends of the left and right edges. The bottom surface portion 41 has a flat plate shape that is inclined downward from the left and right end edges toward the left and right center portions 41A. That is, the lower surface 40A of the water guiding portion 40 is inclined downward from the left and right both end edges toward the left and right central portions 41A. Further, in the bottom surface portion 41, the left and right central portions 41A are slightly inclined downward toward the front. That is, the left and right central portions 41A of the lower surface 40A of the water guiding portion 40 are inclined downward toward the front.

As shown in FIGS. 1 and 3, the left and right surface portions 43 rise in the vertical direction from the left and right front end edges and the left and right end edges of the bottom surface portion 41, and slightly extend outward toward the upper side. Further, the left and right surface portions 43 have substantially the same height as the upper wall portion 11 of the toilet bowl portion 10. The front end portions of the left and right surface portions 43 extend in the left-right direction from the left and right ends of the toilet bowl portion 10. The rear surface portion 45 rises substantially vertically in the vertical direction from the rear end edge of the bottom surface portion 41. The rear surface portion 45 is formed with an insertion hole 45A in which a distribution pipe connected to an outlet of a cleaning tank (not shown) is inserted in the left and right central portions. The upper surface portion 47 has substantially the same shape as the bottom surface portion 41 when viewed from above. The upper surface portion 47 is continuous with the upper end edges of the rear portion, the left and right surface portions 43, and the rear surface portion 45 of the upper wall portion 11 of the toilet bowl portion 10 so as to close the upper portion of the water guiding portion 40. The upper surface portion 47 is formed so as to extend behind the toilet bowl portion 10. Specifically, the upper surface portion 47 is formed so that the upper surface thereof horizontally extends to the rear of the toilet bowl portion 10 with the flush toilet bowl 1 installed.

As shown in FIGS. 1 to 3, the water conveyance portion 40 is provided with a pair of cylindrical portions 49. The pair of cylindrical portions 49 are formed so as to extend in the vertical direction in a form of connecting the upper surface portion 47 and the bottom surface portion 41. The pair of cylindrical portions 49 are provided at positions symmetrical with respect to the left and right centers. The pair of cylindrical portions 49 are formed with through holes 49A penetrating the upper surface of the upper surface portion 47 and the lower surface of the bottom surface portion 41, respectively. The pair of through holes 49A have a predetermined interval. The pair of through holes 49A are mounting holes for fixing the toilet seat device or the like arranged on the upper surface portion 47.

The tank installation portion 50 is provided on the upper surface of the rear portion of the flush toilet 1. A cleaning tank (not shown) for storing cleaning water is installed in the tank installation unit 50. The tank installation portion 50 is formed by being recessed in a concave shape. In the tank installation portion 50, a distribution pipe connected to the outlet of the cleaning tank is inserted and arranged in the insertion hole 45A of the rear surface portion 45.

The water guide unit 40 communicates with the trap drainage channel 20 by a drainage passage 60. Specifically, as shown in FIGS. 1 and 3, the drain passage 60 is a toilet bowl from the inflow port 61 that opens to the lower surface 40A of the water guide portion 40 (the upper surface of the bottom surface portion 41 forming the water guide portion 40). It is formed below the pool surface R of the portion 10 and extends to the outlet 63 which opens at the upper part of the introduction flow path 21 of the trap drainage channel 20. The drainage passage 60 allows the wash water in the water guide portion 40 to flow directly into the trap drainage channel 20 without going through the toilet bowl portion 10. The drainage passage 60 prevents the washing water from flowing out to the toilet bowl portion 10 when the washing water becomes weak to some extent at the end of the toilet bowl washing when the washing water is discharged from the water guiding portion 40. As a result, it is possible to prevent the formation of streaky scale formed by the flow of a small amount of washing water flowing down the surface of the toilet bowl portion 10.

In the flush toilet 1 having such a configuration, when the toilet bowl is washed, the flush water flows from the water guide portion 40 through the toilet bowl portion 10 into the trap drainage channel 20. In the trap drainage channel 20, the washing water descends the introduction flow path 21 and pushes away filth while ascending the ascending flow path 23 to reach the first descending flow path 25. The first descending flow path 25 is formed of a flat inclined surface whose bottom surface 25A descends toward the downstream. Therefore, the washing water smoothly flows down the first descending flow path 25 along the bottom surface 25A to reach the second descending flow path 27 and is discharged.

The width W of the bottom surface 25A of the first descending flow path 25 is formed to be larger than the opening diameter D of the second descending flow path 27. Therefore, the washing water flowing through the first descending flow path 25 can smoothly flow down to the second descending flow path 27 without causing clogging of filth or the like. Further, the bottom surface 25A of the first descending flow path 25 is formed so that its length L is larger than the opening diameter D of the second descending flow path 27. Therefore, the washing water is rectified while flowing down the first descending flow path 25, and the filth is smoothly washed away.

As described above, the flush toilet 1 of the first embodiment includes a toilet bowl portion 10 and a trap drainage channel 20. A trap drainage channel 20 communicates with the toilet bowl portion 10 on the downstream side thereof. The trap drainage channel 20 has an ascending flow path 23, a first descending flow path 25, and a second descending flow path 27. The first descending flow path 25 is formed so as to extend downward from the lower end of the toilet bowl portion 10. The ascending flow path 23 is formed so as to extend upward. The first descending flow path 25 is formed by a flat inclined surface that is continuous with the downstream end of the ascending flow path 23 and whose bottom surface 25A descends toward the downstream. The second descending flow path 27 opens to the bottom surface 25A of the first descending flow path 25 and extends downward.

As described above, in the flush toilet 1, the bottom surface 25A of the first descending flow path 25 of the trap drainage channel 20 is formed by a flat inclined surface. As a result, it is possible to suppress the retention of filth in the first descending flow path 25, and it is possible to suppress the deterioration of drainage performance.

Therefore, the flush toilet 1 of Example 1 can satisfactorily discharge filth.

Further, the width W of the bottom surface 25A of the first descending flow path 25 is formed to be larger than the opening diameter D of the second descending flow path 27. Therefore, the flow path area of the first descending flow path 25 can be easily formed to be larger than the flow path area of the second descending flow path 27. This makes it possible to easily realize a flush toilet that suppresses the retention of filth.

Further, the length L of the bottom surface 25A of the first descending flow path 25 is formed to be larger than the opening diameter D of the second descending flow path 27. Therefore, since the inclined surface can be made long, the circulating washing water can be rectified. As a result, the filth can be smoothly washed away and the retention can be suppressed.

The present invention is not limited to the examples described by the above description and drawings, and for example, the following examples are also included in the technical scope of the present invention.
(1) In Example 1, a flush toilet is illustrated, but the flush toilet according to the present invention may be a siphon type. Further, the flush toilet according to the present invention is not limited to the floor-standing toilet, and may be a wall-mounted toilet.
(2) In the first embodiment, an embodiment including a tank installation portion in which a washing tank is installed has been illustrated, but it is not essential that the flush toilet according to the present invention is provided with a tank installation portion. That is, the flush toilet according to the present invention may be of a so-called tankless type, such as a configuration in which washing water is directly supplied from a water supply pipe by opening and closing a flush valve, an on-off valve, or the like. The tank installation part according to 1 is not essential.
(3) In the first embodiment, a mode including a water guide portion having a specific configuration is illustrated, but the configuration of the water guide portion is not limited to the configuration of the first embodiment.
(4) In the first embodiment, the embodiment provided with the drainage passage is illustrated, but the drainage passage is not an indispensable configuration in the flush toilet according to the present invention.
(5) In Example 1, the embodiment including the peripheral wall portion is illustrated, but the peripheral wall portion is not an essential configuration in the flush toilet according to the present invention. The case where the peripheral wall portion is provided is not limited to the embodiment of the first embodiment, and may be another embodiment such as a form in which the upper end of the flush toilet is entirely covered.
(6) In the first embodiment, a mode in which a drainage socket that passes under the trap drainage channel, extends forward, and is connected to a drainage pipe on the floor is connected to the lower end of the second descending flow path. However, the drainage socket may extend downward from the second descending flow path and be connected to the drainage pipe on the floor.
(7) In Example 1, the width of the bottom surface of the first descending flow path is formed larger than the opening diameter of the second descending flow path, but this is not essential. The flush toilet according to the present invention may be formed so that the width of the bottom surface of the first descending flow path and the opening diameter of the second descending flow path are substantially the same size.
(8) In Example 1, the length of the bottom surface of the first descending flow path is formed larger than the opening diameter of the second descending flow path, but this is not essential. The flush toilet according to the present invention may be formed so that the length of the bottom surface of the first descending flow path is smaller than the opening diameter of the second descending flow path, and the length of the bottom surface of the first descending flow path and the first 2 The opening diameter of the descending flow path may be formed to be substantially the same size.
(9) In Example 1, the trap drainage channel has an introduction flow path, but the introduction flow path is not an essential configuration in the trap drainage channel according to the present invention. The trap drainage channel may have, for example, a form in which the ascending flow path directly communicates with the downstream side of the toilet bowl portion.

1 ... Flush toilet 10 ... Toilet bowl 20 ... Trap drainage channel 23 ... Ascending flow path 25 ... First descending flow path 25A ... Bottom surface of the first descending flow path 27 ... Second descending flow path D ... Second descending flow path Opening diameter L ... Length of the first descending flow path W ... Width of the first descending flow path

Claims (3)

It is equipped with a toilet bowl and a trap drainage channel that communicates with the downstream side of the toilet bowl.
The trap drainage channel
An ascending flow path formed extending upward,
A first descending flow path formed by a flat inclined surface that is continuous with the downstream end of the ascending flow path and whose bottom surface descends toward the downstream side.
A second descending flow path that opens to the bottom surface of the first descending flow path and extends downward,
Has a flush toilet. The flush toilet according to claim 1, wherein the width of the bottom surface of the first descending flow path is larger than the opening diameter of the second descending flow path. The flush toilet according to claim 1 or 2, wherein the length of the bottom surface of the first descending flow path is larger than the opening diameter of the second descending flow path.

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