JP2019108767A - Water closet - Google Patents

Abstract

To provide a water closet that can suppress generation of splattering and abnormal noise of washing water discharged from a rim water discharge port by suppressing local reduction of a channel width in a bent-shaped rim water channel to suppress disturbance of a flow of the washing water.SOLUTION: The water closet comprises a rim water channel and a rim water discharge port through which washing water flows in a rim on either left or right of a front side region of a bowl. The rim water channel has an outer rim water channel, a bent-shaped rim water channel and an inner rim water channel. In a flow channel before bending 34 of the bent-shaped rim water channel, a first intersection angle θ1 in a plan view where a first tangent plane T1 and a second tangent plane T2 of an inner side surface 30 intersect with each other is larger than a second intersection angle φ1 in a plan view where a third tangent plane T3 and a fourth tangent plane T4 of an outside surface 32 of the flow channel before bending intersect with each other.SELECTED DRAWING: Figure 6A

Description

本発明は、水洗大便器に係り、特に、洗浄水源から供給される洗浄水によって洗浄されて汚物を排出する水洗大便器に関する。   BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a flush toilet, and more particularly to a flush toilet that is cleaned by a flush water supplied from a flush water source to discharge dirt.

まず、図９は、従来の水洗大便器の便器本体の概略平面図である。図９に示すように、従来から、洗浄水源から供給される洗浄水によって洗浄されて汚物を排出する水洗大便器２００として、例えば、便器本体２０２のボウル２０４を前後方向に二等分する中心軸線Ｘよりも前方側の領域Ｆで左右の一方側のリム２０６において、屈曲形状（例えば、Ｕターン形状）の領域Ｕを備えたリム導水路２０８が設けられたものが知られている（例えば、特許文献１参照）。
このようなリム導水路２０８は、ボウル２０４の前端を経由することなく、リム２０６の内部で前方に延びる外側リム導水路２１０と、この外側リム導水路２１０の下流側に形成されて内側に向けてＵターン形状に屈曲する屈曲リム導水路２１２と、この屈曲リム導水路２１２の下流側に形成されて後方のリム吐水口２１４まで延びる内側リム導水路２１６と、を備えており、リム吐水口２１４から後方に向かってリム吐水が行われるようになっている。 First, FIG. 9 is a schematic plan view of the toilet body of the conventional flush toilet. As shown in FIG. 9, conventionally, as a flush toilet 200 which is cleaned by the flush water supplied from the flush water source and discharges the dirt, for example, a central axis which bisects the bowl 204 of the toilet body 202 in the front-rear direction It is known that a rim water conduit 208 provided with an area U of a bent shape (for example, a U-turn shape) is provided at one of the left and right rims 206 in an area F on the front side of X (for example, Patent Document 1).
Such a rim conduit 208 is formed on the downstream side of the outer rim conduit 210 so as to extend inward, with the outer rim conduit 210 extending forward inside the rim 206 without passing through the front end of the bowl 204. And an inner rim conduit 216 formed on the downstream side of the bent rim conduit 212 and extending to the rear rim spout 214, the rim spout being formed into a U-turn shape. The rim spout is performed from 214 toward the rear.

特開２０１７−１６０６７１号公報JP, 2017-160671, A

しかしながら、上述した従来の水洗大便器２００のリム導水路２０８において、特に、Ｕターン形状の屈曲リム導水路２１２については、ボウル２０４の上縁のリム２０６の内部の限られたスペース内でＵターン形状に折り返すように設計されているため、屈曲リム導水路２１２内の流路幅が他の流路に比べて狭くなっている。
また、上述した従来の水洗大便器２００のリム導水路２０８においては、その流路幅が局所的に狭くなる程、この狭められた領域に洗浄水が流れ込めない状態となって、リム吐水口２１４まで導かれてしまうおそれもある。
さらに、上述した従来の水洗大便器２００では、特に、外側リム導水路２１０から屈曲リム導水路２１２を経て内側リム導水路２１６へと差し掛かるＵターン形状の領域Ｕ（図９参照）においては、特に、流路断面が縦長形状となる上側領域内において、局所的に流路が狭くなる箇所があり、このような局所的に狭くなった箇所に洗浄水が流れ込まなかった場合には、流路が急縮小した後に、拡大することになり、洗浄水の流れに乱れが生じ易くなる。これにより、乱れた流れの洗浄水がリム吐水口２１４から吐水されて周囲に飛び散るおそれがあるという問題もある。
また、特に、陶器製の水洗大便器２００のＵターン形状のリム導水路２０８内においては、屈曲リム導水路２１２内の流路幅が製造誤差等により局所的に縮小することがある。このため、屈曲リム導水路２１２内に洗浄水が流れ込まない領域が生じ易くなるため、洗浄水の流れが乱れることにより、乱れた流れの洗浄水がリム吐水口２１４から吐水されて周囲に飛び散るおそれがあるばかりでなく、洗浄水が流れ込めない領域に空気が溜まり易くなる。
したがって、屈曲する領域Ｕを通過する洗浄水の乱れた流れが空気溜まりを巻き込み、不快な異音等も発生し易くなるという問題もある。 However, in the rim conduit 208 of the prior art flush toilet 200 described above, and particularly for the U-turn shaped curved rim conduit 212, the U-turn within the limited space inside the rim 206 of the upper edge of the bowl 204 Because it is designed to be folded back in shape, the channel width in the bent rim conduit 212 is narrower than the other channels.
Further, in the rim water conduit 208 of the conventional flush toilet 200 described above, the flush water can not flow into this narrowed area as the channel width becomes narrower locally, and the rim spout There is also a possibility that it may be led up to 214.
Furthermore, in the above-described conventional flush toilet 200, particularly in the U-turn-shaped region U (see FIG. 9) which extends from the outer rim conduit 210 through the curved rim conduit 212 to the inner rim conduit 216. In particular, in the upper region where the channel cross section has a vertically elongated shape, there is a portion where the channel narrows locally, and when the washing water does not flow into such a locally narrowed portion, the channel After the rapid contraction, it will expand and the flow of washing water is likely to be disturbed. As a result, there is also a problem that the turbulent flow of wash water may be spouted from the rim spout 214 and splash around.
Further, in particular, in the U-turn-shaped rim channel 208 of the flush toilet bowl 200 made of pottery, the channel width in the bent rim channel 212 may be locally reduced due to a manufacturing error or the like. For this reason, a region where washing water does not flow into the curved rim water conduit 212 tends to be generated, and when the flow of washing water is disturbed, the washing water of the turbulent flow may be spouted from the rim spout 214 and splash around. As well as air, it is easy for air to accumulate in the area where wash water can not flow.
Therefore, there is also a problem that the turbulent flow of the washing water passing through the bending area U entrains the air pool and the unpleasant noise and the like are easily generated.

そこで、本発明は、上述した従来技術の問題を解決するためになされたものであり、屈曲形状のリム導水路内の流路幅が局所的に小さくなることを抑制することにより洗浄水の流れの乱れを抑制して、リム吐水口から吐水される洗浄水の飛び散りや異音の発生を抑制することができる水洗大便器を提供することを目的としている。   Therefore, the present invention has been made to solve the above-mentioned problems of the prior art, and the flow of cleaning water is suppressed by suppressing the local reduction in the width of the flow passage in the bent rim water channel. It is an object of the present invention to provide a flush toilet which can suppress the disturbance of the water spout and the generation of abnormal noise and spatter of wash water spouted from the rim spout.

上述した目的を達成するために、本発明は、洗浄水源から供給される洗浄水によって洗浄されて汚物を排出する水洗大便器であって、上縁に形成されるリムと、汚物を受ける汚物受け面と、この汚物受け面と上記リムとの間に形成される棚と、を備えたボウルと、このボウルの下方に接続され汚物を排出する排水路と、上記リムに設けられて上記棚に洗浄水を吐水して旋回流を形成するリム吐水部と、上記洗浄水源から供給される洗浄水を上記リム吐水部に供給する導水路と、を有し、上記ボウルは、その前後方向に二等分する左右方向に延びる中心軸線に対して前方側である前方側領域と後方側である後方側領域と、を備え、上記リム吐水部は、上記ボウルの前方側領域の左右の何れか一方の側の上記リムに上記導水路から供給された洗浄水が通水するリム導水路と、このリム導水路の下流端に設けられて洗浄水を後方に向けて吐水するリム吐水口と、を備え、上記リム導水路は、その入口から上記リムの内部を前方に向かって延びる外側リム導水路と、この外側リム導水路の下流側に形成されて内側に屈曲する屈曲リム導水路と、この屈曲リム導水路の下流側に形成されて後方に向かって上記リム吐水口まで延びる内側リム導水路と、を備えており、
上記屈曲リム導水路は、その下方領域内の内側面の前方側先端部を含み且つ上記下方領域内の外側面に対して直交する流路断面であって、この流路断面を境界として流路方向が折り返される折り返し境界断面と、この折り返し境界断面の上流側に形成される屈曲前流路と、上記折り返し境界断面の下流側に形成される屈曲後流路と、を備え、上記屈曲前流路は、下側領域と、この下側領域の上方に形成されて上記下側領域の流路断面よりも縦長の流路断面を備えた上側領域と、を備え、上記屈曲前流路の上側領域内の少なくとも一部の水平断面において、上記屈曲前流路の内側面は、その平面視の曲率半径が最小となる曲面を含む第１曲面と、この第１曲面の曲面形状が開始する第１始端と、上記第１曲面の曲面形状が終了する第１終端と、上記第１始端に接する第１接平面と、上記第１終端に接する第２接平面と、を備え、上記屈曲前流路の外側面は、その平面視の曲率半径が最小となる曲面を含む第２曲面と、この第２曲面の曲面形状が開始する第２始端と、上記第１曲面の曲面形状が終了する第２終端と、上記第２始端に接する第３接平面と、上記第２終端に接する第４接平面と、を備え、上記第１接平面と上記第２接平面とが互いに交差する平面視の第１交差角度は、上記第３接平面と上記第４接平面とが互いに交差する平面視の第２交差角度よりも大きいことを特徴としている。
このように構成された本発明においては、屈曲リム導水路の屈曲前流路の上側領域内の少なくとも一部の水平断面において、屈曲前流路の内側面の平面視の曲率半径が最小となる曲面を含む第１曲面における第１接平面と第２接平面とが互いに交差する平面視の第１交差角度が、屈曲前流路の外側面の平面視の曲率半径が最小となる曲面を含む第２曲面における第３接平面と第４接平面とが互いに交差する平面視の第２交差角度よりも大きいため、屈曲リム導水路の屈曲前流路の上側領域内における流路断面の横幅が局所的に小さくなってしまうことを抑制することができる。
したがって、屈曲リム導水路の屈曲前流路の上側領域内において洗浄水が流れ易くなるため、屈曲リム導水路の上流端から下流端までの流路全域において、洗浄水が流れない部分が発生することを抑制することができ、洗浄水の流れが乱れることを抑制することができる。その結果、リム吐水口から吐水される洗浄水の飛び散りを抑制することができる。
また、屈曲前流路に流入した洗浄水が、屈曲前流路の下流端付近（折り返し境界断面の直前）の領域において、屈曲前流路の外側面に一旦衝突した後に、下流側にスムーズに安定してガイドされるスペースが十分に確保される。これにより、屈曲リム導水路の屈曲前流路の流路断面の横幅が局所的に小さくなっていても、屈曲前流路内に流入した洗浄水が屈曲後流路に流れ込み易くなるため、屈曲リム導水路内全域においても洗浄水が流れ易くなる。よって、屈曲リム導水路内全域において、洗浄水の流れが乱れることを抑制することができる。
さらに、屈曲リム導水路の屈曲前流路の上側領域内に流入した洗浄水の一部は、屈曲前流路の下流端付近（折り返し境界断面の直前）の領域を通過する前に、屈曲前流路の外側面に一旦衝突した後に上昇する流れを形成する。これにより、屈曲リム導水路の屈曲前流路内の上方に溜まり易い空気は、屈曲前流路内を上昇する洗浄水により、効率良く攪拌される。
したがって、屈曲リム導水路の屈曲前流路の上側領域内に溜まり易い空気について、屈曲前流路の上側領域内を通過する洗浄水が効率よく粉砕して下流側に追い出すことができるため、空気の巻き込みによる異音の発生を抑制することもできる。 In order to achieve the above-mentioned object, the present invention is a flush toilet which is flushed by flush water supplied from a flush water source to discharge dirt, the rim formed on the upper edge and the dirt receiver receiving dirt. A bowl provided with a surface and a shelf formed between the dirt receiving surface and the rim, a drainage path connected below the bowl for discharging dirt, and the shelf provided in the rim The bowl has a rim spouting portion for spouting cleaning water to form a swirling flow, and a water conduit for supplying cleaning water supplied from the cleaning water source to the rim spouting portion, and the bowl has two front and rear directions. The rim water spouting part has either a left side or a right side of the front side area of the bowl, and a front side area on the front side and a rear side area on the rear side with respect to a central axis extending in the left and right direction equally divided. Washed from the headrace to the rim on the side of the And a rim spout provided at the downstream end of the rim conduit for discharging the washing water rearward, and the rim conduit includes the inside of the rim from the inlet thereof. An outer rim conduit extending forward, a bent rim conduit formed on the downstream side of the outer rim conduit and bent inward, and a downstream side of the bent rim conduit formed toward the rear And an inner rim conduit extending to the rim spout;
The bent rim water conduit is a flow passage cross section including the front end of the inner surface in the lower region and orthogonal to the outer surface in the lower region, the flow passage being bordered by the flow passage cross section A bending boundary section whose direction is turned back, a pre-bending flow channel formed on the upstream side of the turning boundary cross section, and a post-bending flow channel formed on the downstream side of the turning boundary cross section; The channel includes a lower region and an upper region formed above the lower region and having a flow channel cross section longer than the flow channel cross section of the lower region, and the upper surface of the pre-bending flow channel In at least a part of the horizontal cross section in the region, the inner surface of the flow channel before bending is a first curved surface including a curved surface with a minimum curvature radius in plan view, and a curved surface shape of the first curved surface starts A first end, and a first end at which the curved surface shape of the first curved surface ends, A first tangential plane in contact with the first start end, and a second tangential plane in contact with the first end, and the outer surface of the pre-bending passage includes a curved surface with a minimum radius of curvature in plan view A second curved surface, a second starting end at which the curved surface shape of the second curved surface starts, a second end at which the curved surface shape of the first curved surface ends, a third tangent plane in contact with the second starting end, and the second The first intersection angle of the planar view in which the first tangent plane and the second tangent plane intersect with each other includes a fourth tangent plane in contact with the end, the third tangent plane and the fourth tangent plane are It is characterized by being larger than the 2nd crossing angle of plane view which intersects mutually.
In the present invention configured as above, the radius of curvature in plan view of the inner surface of the pre-bending channel is minimized in the horizontal cross section of at least a part of the upper region of the pre-bending channel of the bending rim conduit The first intersection angle in plan view in which the first tangent plane and the second tangent plane in the first curved surface including the curved surface intersect with each other includes a curved surface in which the radius of curvature in plan view of the outer surface of the flow path before bending is minimum. The lateral width of the flow channel cross section in the upper region of the flow passage before bending of the bending rim water conduit is larger than the second crossing angle in plan view where the third tangent plane and the fourth tangent plane in the second curved surface intersect with each other. It can suppress that it becomes small locally.
Therefore, the washing water easily flows in the upper region of the pre-bending flow passage of the bent rim water conduit, so that a portion where the washing water does not flow is generated in the entire flow passage from the upstream end to the downstream end of the bent rim water conduit. It can control that the flow of washing water is disturbed. As a result, it is possible to suppress spattering of wash water spouted from the rim spout.
In addition, after the washing water that has flowed into the pre-bending flow channel once collides with the outer surface of the pre-bending flow channel in the region near the downstream end of the pre-bending flow channel (immediately before the folded boundary cross section), it smoothly goes downstream. Sufficiently guided space is secured. Thereby, even if the lateral width of the flow passage cross section of the bending rim water channel before bending is locally reduced, the wash water flowing into the flow channel before bending is likely to flow into the flow passage after bending, so bending Cleaning water can easily flow in the entire rim water conduit. Therefore, it is possible to suppress the flow of the washing water from being disturbed in the entire area of the bending rim channel.
Furthermore, a part of the washing water that has flowed into the upper region of the pre-flex flow channel of the flexed rim channel before the flex before passing through the area near the downstream end of the pre-flex flow channel (immediately before the folded boundary cross section) Once it collides with the outer surface of the flow path, it forms a rising flow. As a result, the air that tends to accumulate on the upper side in the pre-bending flow path of the curved rim water conduit is efficiently stirred by the washing water rising in the pre-bending flow path.
Therefore, with regard to the air that is likely to be accumulated in the upper region of the pre-bending passage of the bending rim conduit, the washing water passing through the upper region of the pre-bending passage can be efficiently crushed and expelled to the downstream side. It is also possible to suppress the generation of noise due to the involvement of

本発明において、好ましくは、上記平面視の第１交差角度は、上記屈曲前流路が下方から上方に向かう程大きくなる。
このように構成された本発明とは異なる一般的な水洗大便器では、屈曲リム導水路内を流れる洗浄水は、重力の作用により、屈曲リム導水路内の下方領域になる程流れ易く、上方領域になる程流れ難くなる。
これに対し、本発明によれば、屈曲前流路の上側領域内の内側面の平面視の第１曲面における第１接平面と第２接平面とが互いに交差する平面視の第１交差角度について、屈曲前流路が下方から上方に向かう程大きくしたことにより、屈曲前流路の上側領域内の上方領域にも洗浄水が十分に流れ込み易くなる。
したがって、屈曲リム導水路の屈曲前流路の上側領域内の洗浄水を屈曲後流路に向けてよりスムーズに安定してガイドすることができるため、リム吐水口から吐水される洗浄水の飛び散りをより効果的に抑制することができる。
また、屈曲リム導水路の屈曲前流路の上側領域内に溜まり易い空気について、通過する洗浄水によりさらに効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をより効果的に抑制することもできる。 In the present invention, preferably, the first intersecting angle in the plan view becomes larger as the pre-bending flow path goes upward from the lower side.
In a general flush toilet different from the present invention configured as described above, the flush water flowing in the bent rim channel is likely to flow to the lower region in the bent rim channel due to the action of gravity, and is upward It becomes difficult to flow to the area.
On the other hand, according to the present invention, the first intersection angle in plan view in which the first tangent plane and the second tangent plane in the first curved surface of the inner surface in the upper side region of the flow path before bending intersect in plan view. By making the pre-bending flow passage larger from the lower side to the upper side, the washing water can easily flow into the upper region in the upper region of the pre-bending flow path.
Therefore, the washing water in the upper region of the pre-bending flow channel of the bending rim water conduit can be guided more smoothly and stably toward the after-bending flow channel, so the spatter of the washing water spouted from the rim spout Can be suppressed more effectively.
In addition, air that is likely to be accumulated in the upper region of the pre-flex flow path of the flexed rim water conduit can be more efficiently stirred and crushed by the passing wash water and then expelled to the downstream side. The generation of abnormal noise can also be suppressed more effectively.

本発明において、好ましくは、上記屈曲前流路の上側領域内の内側面は、上記屈曲前流路の上流端よりも下流側のガイド始端位置からその下流側のガイド終端位置まで洗浄水をガイドするガイド面を備えており、このガイド面は、上記第１曲面を含む。
このように構成された本発明においては、屈曲リム導水路の屈曲前流路の上側領域の洗浄水について、第１曲面を含むガイド面に沿って屈曲後流路に向けてよりスムーズに安定してガイドすることができる。
したがって、屈曲リム導水路の屈曲前流路の上側領域内に溜まり易い空気について、ガイド面に沿って流れる洗浄水が、さらにより効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をより効果的に抑制することもできる。 In the present invention, preferably, the inner surface in the upper region of the pre-bending flow channel guides cleaning water from the guide start position downstream of the upstream end of the pre-bending flow channel to the guide end position downstream thereof The guide surface includes the first curved surface.
In the present invention configured as described above, the wash water in the upper region of the pre-flex flow channel of the flexed rim water conduit is stabilized more smoothly toward the post-flex flow channel along the guide surface including the first curved surface. Can be guided.
Therefore, with regard to air that tends to be accumulated in the upper region of the pre-flex flow path of the flexed rim water conduit, the wash water flowing along the guide surface can be more efficiently stirred and crushed and then expelled downstream. Therefore, it is possible to more effectively suppress the generation of abnormal noise due to air entrainment.

本発明において、好ましくは、上記ガイド面は、上記第１始端が上記ガイド始端位置となる上記第１曲面と、この第１曲面の第１終端からその下流側の上記ガイド終端位置まで平面視でテーパ状に形成されているテーパ面と、を備えている。
このように構成された本発明においては、屈曲リム導水路の屈曲前流路の上側領域の洗浄水について、ガイド面である第１曲面及びテーパ面に沿って屈曲後流路に向けてさらによりスムーズに安定してガイドすることができる。
したがって、屈曲リム導水路の屈曲前流路の上側領域内に溜まり易い空気について、ガイド面（テーパ面）に沿って流れる洗浄水が、さらにより効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をさらにより効果的に抑制することもできる。 In the present invention, preferably, the guide surface is a plan view from the first curved surface where the first starting end is the guide starting position and the first end of the first curved surface to the guide end position downstream thereof in plan view And a tapered surface formed in a tapered shape.
In the present invention configured as described above, the washing water in the upper region of the pre-bending flow channel of the bending rim water conduit is further directed toward the post-bending flow channel along the first curved surface and the tapered surface which is the guide surface. It can be guided smoothly and stably.
Therefore, with regard to the air that tends to be accumulated in the upper region of the pre-flex flow path of the flexed rim water conduit, the washing water flowing along the guide surface (taper surface) is stirred and crushed more efficiently and then to the downstream side. Since it is possible to drive out, it is also possible to more effectively suppress the generation of abnormal noise due to air entrainment.

本発明において、好ましくは、上記テーパ面の平面視における上記第１曲面の第１終端から上記ガイド終端位置までの距離は、上記テーパ面が下方から上方に位置する程小さくなる。
このように構成された本発明においては、屈曲リム導水路の屈曲前流路の内側面のガイド面のテーパ面について、その平面視におけるテーパ面の始端（第１曲面の第１終端）からガイド終端位置までの距離が、テーパ面が下方から上方に位置する程小さくなるため、屈曲リム導水路の屈曲前流路の上側領域内の洗浄水について、第１曲面及びテーパ面に沿って屈曲後流路に向けてさらによりスムーズに安定してガイドすることができる。
したがって、屈曲リム導水路の屈曲前流路の上側領域内に溜まり易い空気について、ガイド面（テーパ面）に沿って流れる洗浄水が、さらにより効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をさらにより効果的に抑制することもできる。 In the present invention, preferably, the distance from the first end of the first curved surface to the guide end position in plan view of the tapered surface is smaller as the tapered surface is positioned from the lower side to the upper side.
In the present invention configured as described above, with respect to the tapered surface of the guide surface of the inner side surface of the curved rim water channel before bending, the guide from the starting end (first end of the first curved surface) of the tapered surface in plan view Since the distance to the end position becomes smaller as the tapered surface is positioned from the bottom to the top, the wash water in the upper region of the pre-flex flow path of the flexed rim water conduit is bent along the first curved surface and the tapered surface It is possible to guide the flow path more smoothly and stably.
Therefore, with regard to the air that tends to be accumulated in the upper region of the pre-flex flow path of the flexed rim water conduit, the washing water flowing along the guide surface (taper surface) is stirred and crushed more efficiently and then to the downstream side. Since it is possible to drive out, it is also possible to more effectively suppress the generation of abnormal noise due to air entrainment.

本発明において、好ましくは、上記ガイド面は、平面視において上記ガイド始端位置に位置する上記第１始端から上記ガイド終端位置に位置する上記第１終端まで洗浄水をガイドする湾曲状の曲面を形成している上記第１曲面である。
このように構成された本発明においては、屈曲リム導水路の屈曲前流路の上側領域内の洗浄水について、ガイド始端位置に位置する第１曲面の第１始端からガイド終端位置する第１曲面の第１終端までの湾曲状の曲面に沿って屈曲後流路に向けてさらによりスムーズに安定してガイドすることができる。
したがって、屈曲リム導水路の屈曲前流路の上側領域内に溜まり易い空気について、ガイド面（湾曲状の曲面）に沿って流れる洗浄水が、さらにより効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をさらにより効果的に抑制することもできる。 In the present invention, preferably, the guide surface forms a curved curved surface for guiding washing water from the first start located at the guide start position to the first end located at the guide end position in plan view. It is the said 1st curved surface being done.
In the present invention configured as described above, the first curved surface located at the guide start position from the first starting end of the first curved surface located at the guide start end position for the wash water in the upper region of the pre-flexion flow channel of the curved rim water conduit It can guide more smoothly and stably towards a flow path after bending along a curved curved surface up to the first end of the.
Therefore, with regard to the air that tends to be accumulated in the upper region of the pre-flex flow path of the flexed rim water conduit, the washing water flowing along the guide surface (curved curved surface) is stirred and crushed more efficiently and then downstream Since it is possible to drive out to the side, it is also possible to more effectively suppress the generation of abnormal noise due to air entrainment.

本発明において、好ましくは、上記平面視の第１交差角度は、上記ガイド面が下方から上方に位置する程大きくなる。
このように構成された本発明においては、屈曲前流路の内側面の平面視の曲率半径が最小となる曲面を含む第１曲面における第１接平面と第２接平面とが互いに交差する平面視の第１交差角度が、ガイド面が下方から上方に位置する程大きくなるため、屈曲リム導水路の屈曲前流路の上側領域内の洗浄水について、湾曲状の曲面である第１曲面に沿って屈曲後流路に向けてさらによりスムーズに安定してガイドすることができる。
したがって、屈曲リム導水路の屈曲前流路の上側領域内に溜まり易い空気について、ガイド面（湾曲状の第１曲面）に沿って流れる洗浄水が、さらにより効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をさらにより効果的に抑制することもできる。 In the present invention, preferably, the first intersecting angle in the plan view is larger as the guide surface is positioned from the lower side to the upper side.
In the present invention configured as described above, a plane in which the first tangent plane and the second tangent plane in the first curved surface including the curved surface in which the radius of curvature in plan view of the inner surface of the flow path before bending is minimum intersect each other. Since the first intersection angle of view increases as the guide surface is positioned from the bottom to the top, the first curved surface, which is a curved curved surface, is used for washing water in the upper region of the pre-bending flow channel of the bending rim water channel. After bending, it can be guided more smoothly and stably toward the flow path.
Therefore, after the washing water flowing along the guide surface (curved first curved surface) is stirred and crushed more efficiently for air that tends to be accumulated in the upper region of the pre-flex flow path of the flexed rim water conduit Since it is possible to drive out to the downstream side, it is also possible to more effectively suppress the generation of abnormal noise due to the entrainment of air.

本発明の水洗大便器によれば、屈曲形状のリム導水路内の流路幅が局所的に小さくなることを抑制することにより洗浄水の流れの乱れを抑制して、リム吐水口から吐水される洗浄水の飛び散りや異音の発生を抑制することができる。   According to the flush toilet according to the present invention, it is possible to suppress the disturbance of the flush water flow by suppressing the channel width in the bent rim water channel from being locally reduced, and to discharge water from the rim spout It is possible to suppress the spattering of cleaning water and the generation of abnormal noise.

本発明の第１実施形態による水洗大便器の便器本体の概略中央側面断面図である。It is a schematic center side cross-sectional view of the toilet bowl body of a flush toilet according to a first embodiment of the present invention. 本発明の第１実施形態による水洗大便器の便器本体の概略平面図である。It is a schematic plan view of the toilet bowl body of a flush toilet according to a first embodiment of the present invention. 図２のＩＩＩ−ＩＩＩ線に沿った断面図であり、リムの部分を拡大した断面図である。It is sectional drawing along the III-III line of FIG. 2, and is sectional drawing to which the part of the rim was expanded. 図２のＩＶ−ＩＶ線に沿った屈曲リム導水路の側面断面図である。FIG. 4 is a side cross-sectional view of the flexing rim channel along line IV-IV of FIG. 2; 図１のＶ−Ｖ線に沿った断面図であり、リム導水路内の外側リム導水路から屈曲リム導水路及び内側リム導水路を経てリム吐水口までの区間の底面部分を拡大した図である。FIG. 5 is a cross-sectional view taken along the line V-V in FIG. 1, and is an enlarged view of a bottom portion of a section from an outer rim channel in a rim channel to a rim outlet through a bent rim channel and an inner rim channel is there. 図１のＶＡ−ＶＡ線に沿った外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の部分拡大平面断面図である。It is a partially expanded plane sectional view of the upper region in each of the outer rim channel and the curved rim channel along the line VA-VA in FIG. 図１のＶＢ−ＶＢ線に沿った外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の部分拡大平面断面図である。FIG. 6 is a partial enlarged plan cross-sectional view of the upper region of each in the outer rim channel and the curved rim channel along the line VB-VB of FIG. 1; 図１のＶＣ−ＶＣ線に沿った外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の部分拡大平面断面図である。FIG. 6 is a partially enlarged plan sectional view of the upper region of each in the outer rim channel and the bent rim channel along the line VC-VC in FIG. 1; 図５ＡのＡ部拡大図である。It is the A section enlarged view of FIG. 5A. 図５ＢのＢ部拡大図である。It is the B section enlarged view of FIG. 5B. 図５ＣのＣ部拡大図である。It is the C section enlarged view of FIG. 5C. 本発明の第２実施形態による水洗大便器の便器本体の外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の図５Ａと同様な部分拡大平面断面図である。FIG. 5C is a partial enlarged plan cross-sectional view similar to FIG. 5A of the upper region in the outer rim conduit and in the bent rim conduit of the flush toilet bowl body according to a second embodiment of the present invention; 本発明の第２実施形態による水洗大便器の便器本体の外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の図５Ｂと同様な部分拡大平面断面図である。FIG. 5C is a partial enlarged plan cross-sectional view similar to FIG. 5B of the upper region in the outer rim conduit and the curved rim conduit of the toilet bowl body of the flush toilet according to the second embodiment of the present invention. 本発明の第２実施形態による水洗大便器の便器本体の外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の図５Ｃと同様な部分拡大平面断面図である。FIG. 5C is a partial enlarged plan cross-sectional view similar to FIG. 5C of the upper region in the outer rim conduit and in the bent rim conduit of the flush toilet bowl body according to a second embodiment of the present invention; 図７ＡのＡ部拡大図である。It is the A section enlarged view of FIG. 7A. 図７ＢのＢ部拡大図である。It is the B section enlarged view of FIG. 7B. 図７ＣのＣ部拡大図である。It is the C section enlarged view of FIG. 7C. 従来の水洗大便器の便器本体の概略平面図である。It is a schematic plan view of the toilet bowl body of the conventional flush toilet bowl.

つぎに、図１〜図８Ｃを参照して、本発明の第１実施形態による水洗大便器について説明する。
まず、図１は、本発明の第１実施形態による水洗大便器の便器本体の概略中央側面断面図である。また、図２は、本発明の第１実施形態による水洗大便器の便器本体の概略平面図である。
図１及び図２に示すように、本発明の第１実施形態による水洗大便器１は、陶器製の便器本体２を備えている。
ここで、図１及び図２に示す便器本体２においては、その上面に設けられている便座（図示せず）や便蓋（図示せず）等が省略されている。
また、図１及び図２に示す便器本体２においては、その上面の便座（図示せず）及び便蓋（図示せず）の後方側には、使用者の局部を洗浄する衛生洗浄機能装置（図示せず）や便器本体２への給水機能等を備えた給水系機能装置（図示せず）等が設けられている。しかしながら、これらの衛生洗浄機能装置（図示せず）や給水系機能装置（図示せず）の構造については、従来の装置の構造と同様であるため、説明を省略する。 Next, a flush toilet according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 8C.
First, FIG. 1 is a schematic central side cross-sectional view of a toilet bowl body of a flush toilet according to a first embodiment of the present invention. FIG. 2 is a schematic plan view of the toilet body of the flush toilet according to the first embodiment of the present invention.
As shown in FIG. 1 and FIG. 2, the flush toilet 1 according to the first embodiment of the present invention includes a toilet bowl body 2 made of pottery.
Here, in the toilet main body 2 shown in FIGS. 1 and 2, a toilet seat (not shown), a toilet lid (not shown) and the like provided on the upper surface thereof are omitted.
In the toilet body 2 shown in FIGS. 1 and 2, on the rear side of the toilet seat (not shown) and the toilet lid (not shown) on the upper surface, a sanitary washing function device ( A water supply system functional device (not shown) provided with a water supply function to the toilet body 2 and the like is provided. However, the structures of the sanitary washing function device (not shown) and the water supply system functional device (not shown) are the same as the structures of the conventional devices, so the description will be omitted.

つぎに、図１及び図２に示すように、便器本体２は、ボウル形状のボウル面を形成するボウル４を備えている。このボウル４は、上縁に形成されるリム６と、汚物を受ける汚物受け面８と、この汚物受け面８とリム６との間に形成される棚１０と、を備えている。
また、図１及び図２に示すように、便器本体２は、ボウル４の下方に入口１２ａが接続されて、ボウル４内の汚物を排出する排水路である排水トラップ管路１２を備えている。 Next, as shown in FIGS. 1 and 2, the toilet body 2 includes a bowl 4 that forms a bowl-shaped bowl surface. The bowl 4 includes a rim 6 formed on the upper edge, a filth receiving surface 8 for receiving filth, and a shelf 10 formed between the filth receiving surface 8 and the rim 6.
Further, as shown in FIG. 1 and FIG. 2, the toilet body 2 is provided with a drainage trap pipeline 12 which is a drainage channel which is connected to the inlet 12a below the bowl 4 and which discharges the dirt in the bowl 4. .

ここで、図１及び図２に示すように、本発明の第１実施形態による水洗大便器１においては、図２に示す便器本体２のボウル４の平面視において、ボウル４を前後方向に二等分するように水平左右方向に延びる中心軸線を「Ｘ」で示す。また、ボウル４を左右方向に二等分するように水平前後方向に延びる中心軸線を「Ｙ」で示す。さらに、ボウル４の中心Ｏを通る鉛直方向に延びる中心軸線を「Ｚ」で示す。
また、図２に示すように、水洗大便器１の前後左右の方向については、「前」、「後」、「左」、「右」でそれぞれ示している。
そして、図１及び図２に示すように、水洗大便器１のボウル４における中心Ｏ、水平左右方向の中心軸線Ｘ、及び鉛直方向の中心軸線Ｚに対して、前方側、後方側のそれぞれの領域について、「前方側領域Ｆ」、「後方側領域Ｂ」とそれぞれ定義している。
さらに、図２に示すように、水洗大便器１のボウル４における中心Ｏ、水平前後方向の中心軸線Ｙに対して、前方から見て左側、右側のそれぞれの領域について、「左側領域Ｌ」、「右側領域Ｒ」とそれぞれ定義している。 Here, as shown in FIGS. 1 and 2, in the flush toilet 1 according to the first embodiment of the present invention, the bowl 4 is disposed in the front-rear direction in a plan view of the bowl 4 of the toilet body 2 shown in FIG. A central axis extending in the horizontal left-right direction so as to divide equally is indicated by “X”. Further, a central axis extending in the longitudinal direction so as to bisect the bowl 4 in the lateral direction is indicated by "Y". Further, a vertically extending central axis passing through the center O of the bowl 4 is indicated by "Z".
Further, as shown in FIG. 2, the front, rear, left, and right directions are shown for the front, rear, left, and right directions of the flush toilet 1, respectively.
And as shown in FIG.1 and FIG.2, with respect to the center O in the bowl 4 of the flush toilet 1 and the central axis X in the horizontal right and left directions and the central axis Z in the vertical direction, The regions are respectively defined as “front side region F” and “rear side region B”.
Furthermore, as shown in FIG. 2, with respect to the center O in the bowl 4 of the flush toilet 1 and the central axis Y in the horizontal longitudinal direction, “left region L” for each of left and right as viewed from the front, It is defined as "right side area R".

つぎに、図２に示すように、ボウル４は、その前方側領域Ｆの左右の一方の側のリム６、すなわち、便器本体２の前方から見てボウル４の前方側領域Ｆ且つ右側領域Ｒのリム６の内部には、リム吐水部の一部であるリム導水路１４（詳細は後述する）が形成されている。
また、図２に示すように、リム導水路１４は、その前方側に屈曲形状（図２に示す平面視で概ねＵターン形状）の領域Ｕを備えており、リム導水路１４の下流端には、リム吐水部の一部であるリム吐水口１６が形成されている。
さらに、図３に示すように、リム導水路１４の上流側は、洗浄水源である水道（図示せず）から供給される洗浄水をリム導水路１４に供給する導水路である導水管１８に接続されている。この導水管１８の上流側は、洗浄水源である水道（図示せず）に直結されており、この水道の給水圧力を利用して、導水管１８からリム導水路１４内に供給された洗浄水は、リム導水路１４内で前方へ導かれ、その後、内側且つ後方側に屈曲し、下流側のリム吐水口１６まで導かれるようになっている。
そして、リム吐水口１６に導かれた洗浄水は、後方に向けて吐水（リム吐水）され、リム吐水口１６の下流側近傍に形成される通水路２０を経てボウル４内を旋回することにより、ボウル４内に旋回流が形成されるようになっている。
なお、リム６に設けられて洗浄水を吐水してボウル４内に旋回流を形成する吐水口は、リム吐水口１６のみである。 Next, as shown in FIG. 2, the bowl 4 has a rim 6 on one side to the left of the front side area F, that is, a front side area F and a right side area R of the bowl 4 when viewed from the front of the toilet body 2. A rim water conduit 14 (details will be described later) which is a part of the rim water spouting portion is formed inside the rim 6 of the rim.
In addition, as shown in FIG. 2, the rim water conduit 14 is provided with a region U of a bent shape (generally a U-turn shape in a plan view shown in FIG. 2) on its front side. The rim spout 16 which is a part of rim spout part is formed.
Furthermore, as shown in FIG. 3, the upstream side of the rim water conduit 14 is connected to the water conduit 18 which is a water conduit for supplying the rim water conduit 14 with wash water supplied from a water supply (not shown) which is a washing water source. It is connected. The upstream side of the water conduit 18 is directly connected to a water supply (not shown) which is a washing water source, and the wash water supplied from the water conduit 18 into the rim water conduit 14 using the water supply pressure of the water supply. Is guided forward in the rim conduit 14 and then bent inward and backward so as to be led to the rim outlet 16 on the downstream side.
The flush water guided to the rim spout 16 is spouted backward (rim spout), and is circulated in the bowl 4 through the water passage 20 formed in the vicinity of the downstream side of the rim spout 16. , And a swirl flow is formed in the bowl 4.
Note that the rim spout 16 is the only spout provided in the rim 6 to spout the flush water to form a swirl flow in the bowl 4.

なお、本実施形態の水洗大便器１においては、リム吐水部であるリム導水路１４及びリム吐水口１６について、便器本体２の前方から見てボウル４の前方側領域Ｆ内の右側のリム６の内部に配置した形態について説明するが、このような形態に限定されず、リム吐水口を便器本体２の前方から見てボウル４の前方側領域Ｆ内の左側のリム６に配置して後方に向けてリム吐水を行うようにしてもよい。
要するに、リム吐水部であるリム導水路及びリム吐水口ついては、ボウル４の前方側領域Ｆ内の左右の何れか一方の側のリム６に配置して後方に向けてリム吐水を行うような形態であればよい。 In the flush toilet 1 of the present embodiment, the rim 6 on the right side in the front side area F of the bowl 4 as viewed from the front of the toilet body 2 with respect to the rim water conduit 14 and the rim spout 16 that are the rim spouts. However, the present invention is not limited to such a form, and the rim spout is disposed in the left rim 6 in the front side area F of the bowl 4 when viewed from the front of the toilet body 2 Rim spout may be performed toward the
In short, the rim water conduit and the rim spout, which are the rim water spouting part, are disposed at the rim 6 on either side of the front side area F of the bowl 4 and the rim water spouting is performed rearward. If it is

さらに、図１及び図２に示すように、ボウル４の底部には、排水トラップ管路１２の入口１２ａに差し向けられるようにジェット吐水口２２が形成されている。便器本体２の給水系機能装置（図示せず）からジェット吐水口２２に供給された洗浄水は、排水トラップ管路１２の入口１２ａに向けて吐水（ジェット吐水）されるようになっている。
なお、本実施形態による水洗大便器１においては、リム吐水口１６によるリム吐水について水道の給水圧力を利用して行い、ジェット吐水口２２によるジェット吐水について加圧ポンプ（図示せず）を制御することにより貯水タンク（図示せず）内の洗浄水を供給する、いわゆる、ハイブリット式の水洗大便器の形態について説明するが、このような形態に限られず、他の形態についても適用可能である。また、ジェット吐水口２２によるジェット吐水について省略した形態であってもよい。 Furthermore, as shown in FIG. 1 and FIG. 2, a jet spout 22 is formed at the bottom of the bowl 4 so as to be directed to the inlet 12 a of the drainage trap pipeline 12. The flush water supplied from the water supply system functional device (not shown) of the toilet body 2 to the jet spout 22 is spouted (jet spout) toward the inlet 12 a of the drainage trap pipeline 12.
In the flush toilet 1 according to the present embodiment, the rim spout from the rim spout 16 is performed using the water supply pressure of the water, and the pressurizing pump (not shown) is controlled for the jet spout from the jet spout 22. Although a description will be given of the form of a so-called hybrid flush toilet that supplies flush water in a reservoir tank (not shown), the present invention is not limited to such a form, and may be applied to other forms. Further, the jet spouting by the jet spout 22 may be omitted.

つぎに、図１〜図６Ｃを参照して、本発明の第１実施形態による水洗大便器１のリム導水路１４の詳細について説明する。
まず、図２に示すように、リム導水路１４は、導水管１８に接続される入口１４ａからリム６の内部を前方に向かって延びる外側リム導水路２４と、この外側リム導水路２４の下流側に形成されて内側に屈曲する屈曲リム導水路２６と、この屈曲リム導水路２６の下流側に形成されて後方に向かってリム吐水口１６まで延びる内側リム導水路２８と、を備えている。
つぎに、図３は、図２のＩＩＩ−ＩＩＩ線に沿った断面図であり、リムの部分を拡大した断面図である。また、図４は、図２のＩＶ−ＩＶ線に沿った屈曲リム導水路の側面断面図である。さらに、図５は、図１のＶ−Ｖ線に沿った断面図であり、リム導水路内の外側リム導水路から屈曲リム導水路及び内側リム導水路を経てリム吐水口までの区間の底面部分を拡大した図である。 Next, with reference to FIGS. 1 to 6C, the details of the rim conduit 14 of the flush toilet 1 according to the first embodiment of the present invention will be described.
First, as shown in FIG. 2, the rim water conduit 14 includes an outer rim water conduit 24 extending forward from the inside of the rim 6 from an inlet 14 a connected to the water conduit 18, and a downstream of the outer rim water conduit 24. It has a curved rim conduit 26 formed on the side and bent inward, and an inner rim conduit 28 formed on the downstream side of the curved rim conduit 26 and extending rearward to the rim spout 16. .
Next, FIG. 3 is a cross-sectional view taken along the line III-III in FIG. 2 and is an enlarged cross-sectional view of a portion of the rim. 4 is a side cross-sectional view of the bent rim channel along line IV-IV of FIG. Furthermore, FIG. 5 is a cross-sectional view taken along the line V-V of FIG. 1 and shows the bottom of the section from the outer rim channel in the rim channel to the rim spout through the flexed rim channel and the inner rim channel. It is the figure which expanded a part.

まず、図３及び図５に示すように、外側リム導水路２４は、ボウル４の一方側（右側領域Ｒ）のリム６の内部において、ボウル４の前端のリム６を経由することなく、前方に向かって延びている。
また、図３に示すように、外側リム導水路２４の流路断面Ｓ１は、下側領域Ａ１及び上側領域Ａ２をそれぞれ備えており、図３に示す立面視において、流路断面Ｓ１の上側領域Ａ２が下側領域Ａ１よりも縦長となる流路断面を形成している。 First, as shown in FIG. 3 and FIG. 5, the outer rim water conduit 24 is disposed forward of the rim 6 at the front end of the bowl 4 inside the rim 6 on one side (right area R) of the bowl 4. It extends towards the
Further, as shown in FIG. 3, the flow passage cross section S1 of the outer rim water conduit 24 includes the lower area A1 and the upper area A2 respectively, and in the elevation view shown in FIG. A flow passage cross section in which the area A2 is vertically longer than the lower area A1 is formed.

つぎに、図３〜図５に示すように、屈曲リム導水路２６は、上流端位置Ｐ１の上流端流路断面Ｓ２と、下流端位置Ｐ２の下流端流路断面Ｓ３と、上流端位置Ｐ１と下流端位置Ｐ２との間の位置Ｐ３の流路断面Ｓ４と、を備えている。
また、図５に示すように、外側リム導水路２４の下流端位置（屈曲リム導水路２６の上流端位置）Ｐ１及びその流路断面Ｓ２は、外側リム導水路２４の前端に位置しており、図５の平面視の屈曲リム導水路２６の下側領域Ａ１内において、ほぼ半円弧形状に形成される屈曲リム導水路２６の内側面３０の半円弧の始端位置となっている。
すなわち、屈曲リム導水路２６の上流端流路断面Ｓ２は、立面視において、図３に示す外側リム導水路２４の流路断面Ｓ１とほぼ同一形状となっている。
さらに、図４及び図５に示すように、屈曲リム導水路２６の流路断面Ｓ４は、屈曲リム導水路２６の下側領域Ａ１内の内側面３０における前方側の先端位置Ｐ３に位置する先端部３０ａを含み、かつ、下側領域Ａ１内の外側面３２に対して直交している。そして、屈曲リム導水路２６の流路断面Ｓ４は、その前後で流路方向が折り返される境界面（以下「折り返し境界断面Ｓ４」）となっている。 Next, as shown in FIGS. 3 to 5, the bent rim water conduit 26 has an upstream end channel cross section S2 at the upstream end position P1, a downstream end channel cross section S3 at the downstream end position P2, and an upstream end position P1. And a flow passage cross section S4 of a position P3 between the lower end position P2 and the downstream end position P2.
Further, as shown in FIG. 5, the downstream end position of the outer rim water conduit 24 (the upstream end position of the bent rim water conduit 26) P1 and its flow passage section S2 are located at the front end of the outer rim water conduit 24. In the lower area A1 of the bending rim conduit 26 in plan view in FIG. 5, it is located at the beginning of the semicircular arc of the inner surface 30 of the bending rim conduit 26 formed in a substantially half arc shape.
That is, the upstream end flow passage cross section S2 of the curved rim water conveyance channel 26 has substantially the same shape as the flow passage cross section S1 of the outer rim water conveyance channel 24 shown in FIG.
Furthermore, as shown in FIG. 4 and FIG. 5, the flow passage cross section S4 of the bending rim water conduit 26 has a tip located at the front end position P3 of the inner side surface 30 in the lower region A1 of the bending rim water conveyance 26 It includes the portion 30a, and is orthogonal to the outer side surface 32 in the lower area A1. And flow path section S4 of bent rim channel 26 becomes a border plane (following "turning-back border section S4") by which a flow direction is turned up before and after that.

また、図４に示すように、屈曲リム導水路２６の流路断面Ｓ４は、下側領域Ａ１及び上側領域Ａ２（Ａ３〜Ａ５）をそれぞれ備えており、図４に示す立面視において、流路断面Ｓ４の上側領域Ａ２が下側領域Ａ１よりも縦長となる流路断面を形成している。   Further, as shown in FIG. 4, the flow passage cross section S4 of the bending rim water conduit 26 includes the lower region A1 and the upper region A2 (A3 to A5) respectively, and in the elevation view shown in FIG. The upper side area A2 of the road cross section S4 forms a flow path cross section which is vertically longer than the lower side area A1.

つぎに、図５に示すように、屈曲リム導水路２６は、その詳細については後述するが、折り返し境界断面Ｓ４に対して上流側に形成される屈曲前流路３４と、折り返し境界断面Ｓ４に対して下流側に形成される屈曲後流路３６と、を備えている。
また、図５に示すように、屈曲前流路３４の前端且つ外側付近の外側面３２には、外側角部３２ａが設けられている。この外側面３２の外側角部３２ａは、屈曲リム導水路２６の外側面３２の周方向全域の内において、平面視で最小の曲率半径ρ１を備えている。
さらに、図５に示すように、屈曲前流路３４の内側面３０の平面視の最小曲率半径ρ２は、屈曲前流路３４の外側面３２の平面視の最小曲率半径ρ１よりも大きく設定されている（ρ２＞ρ１）。 Next, as shown in FIG. 5, the bending rim water conduit 26 will be described in detail later, but it is possible to use a pre-bending flow channel 34 formed on the upstream side with respect to the turning boundary section S4 and a turning boundary section S4. And a post-bending flow channel 36 formed on the downstream side.
Further, as shown in FIG. 5, an outer corner 32 a is provided on the outer surface 32 near the front end and the outer side of the pre-bending flow channel 34. The outer corner 32 a of the outer side surface 32 has a minimum curvature radius 11 in plan view in the entire circumferential direction of the outer side surface 32 of the bending rim channel 26.
Furthermore, as shown in FIG. 5, the minimum curvature radius 22 of the inner side surface 30 of the pre-bending flow passage 34 in plan view is set larger than the minimum curvature radius ρ1 of the outer side 32 of the pre-bending flow channel 34 in plan view. (Ρ2> ρ1).

つぎに、図３〜図５に示すように、内側リム導水路２の上流端位置（屈曲リム導水路２６の下流端位置）Ｐ２及びその流路断面Ｓ３は、内側リム導水路２８の前端に位置しており、図５の平面視の屈曲リム導水路２６の下方領域内において、ほぼ半円弧形状に形成される屈曲リム導水路２６の内側面３０の半円弧の終端位置となっている。
また、図３に示すように、内側リム導水路２８の流路断面Ｓ５は、屈曲後流路３６の下流端の流路断面Ｓ３とほぼ同一の断面形状となっている。
さらに、内側リム導水路２８の流路断面Ｓ５及びリム吐水口１６の最大高さ寸法Ｈ５（図３参照）は、外側リム導水路２４の流路断面Ｓ１の最大高さ寸法Ｈ１（図３参照）及び屈曲リム導水路２６の折り返し境界断面Ｓ４の最大高さ寸法Ｈ４（図４参照）よりも小さく設定されている。 Next, as shown in FIGS. 3 to 5, the upstream end position of the inner rim water conduit 2 (the downstream end position of the bent rim water conduit 26) P 2 and its flow passage section S 3 are at the front end of the inner rim water conduit 28. In the lower region of the bending rim channel 26 in plan view of FIG. 5, it is located at the end position of the half arc of the inner surface 30 of the bending rim channel 26 formed in a substantially half arc shape.
Further, as shown in FIG. 3, the flow passage cross-section S5 of the inner rim water conduit 28 has substantially the same cross-sectional shape as the flow passage cross-section S3 of the downstream end of the post-bending flow passage 36.
Further, the flow path cross section S5 of the inner rim water conduit 28 and the maximum height dimension H5 (see FIG. 3) of the rim spout 16 are the maximum height dimension H1 of the flow cross section S1 of the outer rim water channel 24 (see FIG. 3) And the maximum height dimension H4 (see FIG. 4) of the folded boundary cross section S4 of the bent rim conduit 26 is set.

つぎに、図５Ａは、図１のＶＡ−ＶＡ線に沿った外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の部分拡大平面断面図である。また、図５Ｂは、図１のＶＢ−ＶＢ線に沿った外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の部分拡大平面断面図である。さらに、図５Ｃは、図１のＶＣ−ＶＣ線に沿った外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の部分拡大平面断面図である。
また、図６Ａは、図５ＡのＡ部拡大図である。さらに、図６Ｂは、図５ＢのＢ部拡大図である。また、図６Ｃは、図５ＣのＣ部拡大図である。
なお、図５Ａ〜図５Ｃにおいては、本実施形態の水洗大便器１のリム導水路１４の外側リム導水路２４及び屈曲リム導水路２６内のそれぞれの上側領域Ａ３〜Ａ５の流路を実線で示している。
また、図５Ａ〜図５Ｃにおいては、本実施形態の水洗大便器１の外側リム導水路２４及び屈曲リム導水路２６内のそれぞれの上側領域Ａ３〜Ａ５の流路と下側領域Ａ１の流路との比較のため、図５に示す本実施形態の水洗大便器１の外側リム導水路内２４、屈曲リム導水路内２６のそれぞれの下側領域Ａ１、及び、内側リム導水路２８について鎖線等の想像線で示している。
さらに、図５Ａ〜図６Ｃにおいては、本実施形態の水洗大便器１の外側リム導水路２４及び屈曲リム導水路２６内のそれぞれの上側領域Ａ３〜Ａ５の流路と同一高さ位置における従来の屈曲リム導水路２１２の屈曲前流路２３４やその内側面２３４に関する外形について鎖線等の想像線で示している。 Next, FIG. 5A is a partially enlarged plan sectional view of the upper region in the outer rim channel and the curved rim channel along the line VA-VA in FIG. 5B is a partially enlarged plan sectional view of the upper region in the outer rim channel and the bent rim channel along the line VB-VB of FIG. Furthermore, FIG. 5C is a partially enlarged plan sectional view of the upper region of each in the outer rim channel and the curved rim channel along the line VC-VC in FIG.
6A is an enlarged view of a portion A of FIG. 5A. Further, FIG. 6B is an enlarged view of a portion B of FIG. 5B. 6C is an enlarged view of a portion C of FIG. 5C.
5A to 5C, the flow paths of the upper rim areas A3 to A5 in the outer rim water conduit 24 and the bent rim water conduit 26 of the rim water conduit 14 of the flush toilet 1 of this embodiment are indicated by solid lines. It shows.
Moreover, in FIG. 5A-FIG. 5C, the flow path of upper side area A3-A5 in each of outer side rim water channel 24 of the flush toilet 1 of this embodiment and the bending rim water channel 26 and the flow path of lower region A1. For comparison with the above, the lower region A1 in the outer rim water conduit 24 of the flush toilet 1 of the present embodiment shown in FIG. 5, the lower region A1 in the bent rim water conduit 26 and the inner rim water conduit 28 shown in FIG. It shows with the imaginary line of.
Furthermore, in FIG. 5A to FIG. 6C, the conventional rim at the same height position as the flow path of the upper area A3 to A5 in the outer rim water conduit 24 and the bent rim water conduit 26 of the flush toilet 1 of this embodiment. The outlines of the pre-bending flow passage 234 of the bent rim conduit 212 and its outer side surface 234 are indicated by imaginary lines such as dashed lines.

図５Ａ及び図６Ａに示すように、図５に示す屈曲前流路３４の下側領域Ａ１よりも上方の上側領域Ａ３の水平断面において、屈曲前流路３４の内側面３０は、その平面視の曲率半径ρ３が最小となる曲面を含む第１曲面Ｃ１を備えている。
つぎに、図６Ａに示すように、第１曲面Ｃ１は、その上流端に位置し、かつ、第１曲面Ｃ１の曲面形状が開始する第１始端Ｐ４を備えている。さらに、第１曲面Ｃ１は、その下流端に位置し、かつ、第１曲面Ｃ１の曲面形状が終了する第１終端Ｐ５を備えている。
また、図６Ａに示す平面視において、第１曲面Ｃ１は、第１始端Ｐ４における曲面に接する第１接平面Ｔ１と、第１終端Ｐ５における曲面に接する第２接平面Ｔ２と、を備えている。
同様に、図５Ａ及び図６Ａに示すように、屈曲前流路３４の上側領域Ａ３内の外側面３２は、その平面視の曲率半径ρ４が最小となる曲面を含む第２曲面Ｃ２を備えている。
また、図６Ａに示すように、第２曲面Ｃ２は、その上流端に位置し、かつ、第２曲面Ｃ２の曲面形状が開始する第２始端Ｐ６を備えている。さらに、第２曲面Ｃ２は、その下流端に位置し、かつ、第２曲面Ｃ２の曲面形状が終了する第２終端Ｐ６を備えている。
また、図６Ａに示す平面視において、第２曲面Ｃ２は、第２始端Ｐ６における曲面に接する第３接平面Ｔ３と、第２終端Ｐ７における曲面に接する第４接平面Ｔ４と、を備えている。
さらに、図６Ａに示す平面視において、第１接平面Ｔ１と第２接平面Ｔ２とが互いに交差する第１交差角度θ１は、第３接平面Ｔ３と第４接平面Ｔ４とが互いに交差する第２交差角度φ１よりも大きく設定されている（θ１＞φ１）。
また、図５Ａに示すように、屈曲リム導水路２６の上側領域Ａ３の下流端については、屈曲前流路３４の上側領域Ａ３の下流端から折り返し境界断面Ｓ４を超えて屈曲後流路３６の上側領域Ａ３まで延びている。 As shown in FIGS. 5A and 6A, in the horizontal cross section of the upper region A3 above the lower region A1 of the pre-bending flow channel 34 shown in FIG. A first curved surface C1 including a curved surface having a minimum curvature radius 33 of
Next, as shown in FIG. 6A, the first curved surface C1 is provided with a first start end P4 located at the upstream end thereof and from which the curved surface shape of the first curved surface C1 starts. Furthermore, the first curved surface C1 is provided with a first end P5 located at the downstream end thereof and at which the curved surface shape of the first curved surface C1 ends.
Further, in plan view shown in FIG. 6A, the first curved surface C1 includes a first tangent plane T1 in contact with the curved surface at the first start end P4 and a second tangent plane T2 in contact with the curved surface at the first end P5. .
Similarly, as shown in FIGS. 5A and 6A, the outer side surface 32 in the upper region A3 of the pre-bending flow channel 34 is provided with a second curved surface C2 including a curved surface having a minimum curvature radius 44 in plan view. There is.
Further, as shown in FIG. 6A, the second curved surface C2 is provided with a second start end P6 located at the upstream end thereof and from which the curved surface shape of the second curved surface C2 starts. Furthermore, the second curved surface C2 is provided with a second end P6 located at the downstream end thereof and at which the curved surface shape of the second curved surface C2 ends.
Further, in a plan view shown in FIG. 6A, the second curved surface C2 includes a third tangent plane T3 in contact with the curved surface at the second start end P6 and a fourth tangent plane T4 in contact with the curved surface at the second end P7. .
Furthermore, in a plan view shown in FIG. 6A, a first intersection angle θ1 at which the first tangent plane T1 and the second tangent plane T2 intersect with each other is a third intersection plane T3 at which the fourth tangent plane T4 intersects with each other. 2 is set larger than the crossing angle φ1 (θ1> φ1).
5A, the downstream end of the upper region A3 of the bending rim conduit 26 from the downstream end of the upper region A3 of the pre-bending passage 34 exceeds the folding boundary cross section S4 and the after-bending passage 36 It extends to the upper area A3.

同様に、図５Ｂ及び図６Ｂに示すように、図５Ａ及び図６Ａに示す屈曲前流路３４の上側領域Ａ３よりも上方の上側領域Ａ４の水平断面において、屈曲前流路３４の内側面３０は、その平面視の曲率半径ρ５が最小となる曲面を含む第１曲面Ｃ３を備えている。
つぎに、図６Ｂに示すように、第１曲面Ｃ３は、その上流端に位置し、かつ、第１曲面Ｃ３の曲面形状が開始する第１始端Ｐ８を備えており、さらに、第１曲面Ｃ３は、その下流端に位置し、かつ、第１曲面Ｃ３の曲面形状が終了する第１終端Ｐ９を備えている。
また、図６Ｂに示す平面視において、第１曲面Ｃ３は、第１始端Ｐ８における曲面に接する第１接平面Ｔ５と、第１終端Ｐ９における曲面に接する第２接平面Ｔ６と、を備えている。
同様に、図５Ｂ及び図６Ｂに示すように、屈曲前流路３４の上側領域Ａ４内の外側面３２は、その平面視の曲率半径ρ６が最小となる曲面を含む第２曲面Ｃ４を備えている。
また、図６Ｂに示すように、第２曲面Ｃ４は、その上流端に位置し、かつ、第２曲面Ｃ４の曲面形状が開始する第２始端Ｐ１０を備えている。さらに、第２曲面Ｃ４は、その下流端に位置し、かつ、第２曲面Ｃ４の曲面形状が終了する第２終端Ｐ１１を備えている。
また、図６Ｂに示す平面視において、第２曲面Ｃ４は、第２始端Ｐ１０における曲面に接する第３接平面Ｔ７と、第２終端Ｐ１１における曲面に接する第４接平面Ｔ８と、を備えている。
さらに、図６Ｂに示す平面視において、第１接平面Ｔ５と第２接平面Ｔ６とが互いに交差する第１交差角度θ２は、第３接平面Ｔ７と第４接平面Ｔ８とが互いに交差する第２交差角度φ２よりも大きく設定されている（θ２＞φ２）。
また、図５Ｂに示すように、屈曲リム導水路２６の上側領域Ａ４の下流端については、屈曲前流路３４の上側領域Ａ４の下流端から折り返し境界断面Ｓ４を僅かに超えて屈曲後流路３６の上側領域Ａ４まで延びている。
しかしながら、屈曲リム導水路２６の上側領域Ａ４の下流端は、図５Ａに示す屈曲リム導水路２６の上側領域Ａ４の下流端に比べて、上流側に位置している。 Similarly, as shown in FIGS. 5B and 6B, in the horizontal cross section of the upper area A4 above the upper area A3 of the pre-bending flow channel 34 shown in FIGS. 5A and 6A, the inner surface 30 of the pre-bending flow channel 34 Has a first curved surface C3 including a curved surface having a minimum curvature radius 55 in a plan view.
Next, as shown in FIG. 6B, the first curved surface C3 is provided with a first starting end P8 located at the upstream end thereof and from which the curved surface shape of the first curved surface C3 starts, and further, the first curved surface C3. Has a first end P9 located at its downstream end and at which the curved surface shape of the first curved surface C3 ends.
Further, in a plan view shown in FIG. 6B, the first curved surface C3 includes a first tangent plane T5 in contact with the curved surface at the first start end P8 and a second tangent plane T6 in contact with the curved surface at the first end P9. .
Similarly, as shown in FIGS. 5B and 6B, the outer side surface 32 in the upper region A4 of the pre-bending flow channel 34 is provided with a second curved surface C4 including a curved surface having a minimum curvature radius 66 in plan view. There is.
Further, as shown in FIG. 6B, the second curved surface C4 is provided with a second start end P10 located at the upstream end thereof and from which the curved surface shape of the second curved surface C4 starts. Furthermore, the second curved surface C4 is provided with a second end P11 located at the downstream end thereof and at which the curved surface shape of the second curved surface C4 ends.
Further, in a plan view shown in FIG. 6B, the second curved surface C4 includes a third tangent plane T7 in contact with the curved surface at the second start end P10 and a fourth tangent plane T8 in contact with the curved surface at the second end P11. .
Furthermore, in a plan view shown in FIG. 6B, a first intersection angle θ2 at which the first tangent plane T5 and the second tangent plane T6 intersect with each other is a third intersection plane T7 and the fourth tangent plane T8 intersect with each other 2 is set larger than the crossing angle φ2 (θ2> φ2).
Further, as shown in FIG. 5B, with regard to the downstream end of the upper region A4 of the bending rim conduit 26 from the downstream end of the upper region A4 of the pre-bending passage 34, it slightly exceeds the folded boundary cross section S4 It extends to the upper region A4 of 36.
However, the downstream end of the upper region A4 of the bending rim conduit 26 is located upstream relative to the downstream end of the upper region A4 of the bending rim conduit 26 shown in FIG. 5A.

さらに、同様に、図５Ｃ及び図６Ｃに示すように、図５Ｂ及び図６Ｂに示す屈曲前流路３４の上側領域Ａ４よりも上方の上側領域Ａ５の水平断面において、屈曲前流路３４の内側面３０は、その平面視の曲率半径ρ７が最小となる曲面を含む第１曲面Ｃ５を備えている。
つぎに、図６Ｃに示すように、第１曲面Ｃ５は、その上流端に位置し、かつ、第１曲面Ｃ５の曲面形状が開始する第１始端Ｐ１２を備えており、さらに、第１曲面Ｃ５は、その下流端に位置し、かつ、第１曲面Ｃ５の曲面形状が終了する第１終端Ｐ１３を備えている。
また、図６Ｃに示す平面視において、第１曲面Ｃ５は、第１始端Ｐ１２における曲面に接する第１接平面Ｔ９と、第１終端Ｐ１３における曲面に接する第２接平面Ｔ１０と、を備えている。
同様に、図５Ｃ及び図６Ｃに示すように、屈曲前流路３４の上側領域Ａ５内の外側面３２は、その平面視の曲率半径ρ８が最小となる曲面を含む第２曲面Ｃ６を備えている。
また、図６Ｃに示すように、第２曲面Ｃ６は、その上流端に位置し、かつ、第２曲面Ｃ６の曲面形状が開始する第２始端Ｐ１４を備えており、さらに、第２曲面Ｃ６は、その下流端に位置し、かつ、第２曲面Ｃ６の曲面形状が終了する第２終端Ｐ１５を備えている。
また、図６Ｃに示す平面視において、第２曲面Ｃ６は、第２始端Ｐ１４における曲面に接する第３接平面Ｔ１１と、第２終端Ｐ１５における曲面に接する第４接平面Ｔ１２と、を備えている。
さらに、図６Ｃに示す平面視において、第１接平面Ｔ９と第２接平面Ｔ１０とが互いに交差する第１交差角度θ３は、第３接平面Ｔ１１と第４接平面Ｔ１２とが互いに交差する第２交差角度φ３よりも大きく設定されている（θ３＞φ３）。
しかしながら、屈曲リム導水路２６の上側領域Ａ５の下流端については、折り返し境界断面Ｓ４を超えることなく、屈曲前流路３４内の前端付近に留まっている。 Furthermore, similarly, as shown in FIG. 5C and FIG. 6C, in the horizontal cross section of the upper region A5 above the upper region A4 of the pre-bending channel 34 shown in FIG. 5B and FIG. The side surface 30 is provided with a first curved surface C5 including a curved surface in which the radius of curvature ρ7 of the planar view is minimum.
Next, as shown in FIG. 6C, the first curved surface C5 is provided with a first start end P12 located at the upstream end thereof and from which the curved surface shape of the first curved surface C5 starts, and further, the first curved surface C5 Has a first end P13 located at its downstream end and at which the curved surface shape of the first curved surface C5 ends.
Further, in a plan view shown in FIG. 6C, the first curved surface C5 includes a first tangent plane T9 in contact with the curved surface at the first start end P12 and a second tangent plane T10 in contact with the curved surface at the first end P13. .
Similarly, as shown in FIGS. 5C and 6C, the outer side surface 32 in the upper region A5 of the pre-bending flow channel 34 is provided with a second curved surface C6 including a curved surface with a minimum curvature radius 88 in plan view There is.
Further, as shown in FIG. 6C, the second curved surface C6 is provided with a second start end P14 located at the upstream end thereof and from which the curved surface shape of the second curved surface C6 starts, and further, the second curved surface C6 is And a second end P15 located at the downstream end of the second curved surface C6 and having the curved surface shape of the second curved surface C6.
Further, in the plan view shown in FIG. 6C, the second curved surface C6 includes a third tangent plane T11 in contact with the curved surface at the second start end P14 and a fourth tangent plane T12 in contact with the curved surface at the second end P15. .
Furthermore, in a plan view shown in FIG. 6C, a first intersection angle θ3 at which the first tangent plane T9 and the second tangent plane T10 intersect with each other is a third intersection plane T11 and the fourth tangent plane T12 intersect with each other It is set larger than the crossing angle φ3 (θ3> φ3).
However, the downstream end of the upper region A5 of the bending rim conduit 26 remains near the front end in the pre-bending flow channel 34 without exceeding the folding boundary cross section S4.

つぎに、図６Ａ〜図６Ｃに示すように、屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ３〜Ａ５内における内側面３０の各平面視の第１交差角度θ１，θ２，θ３は、屈曲前流路３４の上側領域Ａ２内の流路が下方から上方に向かう程大きくなるように設定されている（θ１＜θ２＜θ３））。   Next, as shown to FIG. 6A-FIG. 6C, 1st intersection angle (theta) 1, (theta) 2, (theta) 3 of each planar view of the inner surface 30 in upper region A3-A5 of flow path 34 before bending of bending rim channel 26 is The flow path in the upper region A2 of the pre-bending flow path 34 is set to be larger from the lower side toward the upper side (θ1 <θ2 <θ3).

つぎに、図５に示すように、屈曲リム導水路２６内の下側領域Ａ１に形成される屈曲後流路３６の前端且つ内側付近の外側面３２には、内側角部３２ｂが設けられている。この外側面３２の内側角部３２ｂは、屈曲後流路３６の外側面３２の周方向全域の内で最小の曲率半径ρ９を備えている。
また、図５に示すように、屈曲リム導水路２６の屈曲後流路３６における内側面３０の平面視の最小曲率半径ρ１０は、屈曲後流路３６の外側面３２の内側角部３２ｂの平面視の最小曲率半径ρ９よりも大きく設定されている（ρ１０＞ρ９）。 Next, as shown in FIG. 5, an inner corner 32b is provided on the outer surface 32 near the front end and the inner side of the after-bending channel 36 formed in the lower region A1 in the bending rim channel 26. There is. The inner corner portion 32 b of the outer side surface 32 has the smallest radius of curvature ρ 9 in the entire circumferential direction of the outer side surface 32 of the flow passage 36 after bending.
In addition, as shown in FIG. 5, the minimum curvature radius 1010 of the inner side surface 30 in a plan view of the inner side surface 30 in the after-bending channel 36 of the bent rim conduit 26 is the plane of the inner corner 32 b of the outer surface 32 of the after-bending channel 36. It is set larger than the minimum curvature radius 視 9 of the visual (1010> 視 9).

つぎに、図５に示すように、屈曲リム導水路２６の下側領域Ａ１に形成される屈曲後流路３６の外側面３２の外側角部３２ａにおける平面視の最小曲率半径ρ１は、屈曲後流路３６の外側面３２の内側角部３２ｂにおける平面視の最小曲率半径ρ９よりも小さく設定されている。   Next, as shown in FIG. 5, the minimum radius of curvature 11 in plan view at the outer corner 32a of the outer side surface 32 of the after-bending passage 36 formed in the lower region A1 of the bending rim channel 26 is after bending The radius of curvature is set to be smaller than the minimum radius of curvature 99 in plan view at the inner corner 32b of the outer side surface 32 of the flow path 36.

つぎに、図６Ａ〜図６Ｃに示すように、屈曲リム導水路２６の屈曲前流路３４の各上側領域Ａ３，Ａ４，Ａ５における内側面３０は、洗浄水を下流側にガイドするガイド面Ｇ１，Ｇ２，Ｇ３を備えており、このガイド面Ｇ１，Ｇ２，Ｇ３は、第１曲面Ｃ１，Ｃ３，Ｃ５と、その下流側のテーパ面Ｔ１３，Ｔ１４，Ｔ１５と、を含む。
また、各ガイド面Ｇ１，Ｇ２，Ｇ３の始端位置（ガイド始端位置）は、屈曲前流路３４の上流端位置Ｐ１よりも下流側に位置しており、第１曲面Ｃ１，Ｃ３，Ｃ５の各第１始端Ｐ４，Ｐ８，Ｐ１２の位置に相当している。
さらに、図６Ａ〜図６Ｃに示すように、各テーパ面Ｔ１３，Ｔ１４，Ｔ１５は、第１曲面Ｃ１，Ｃ３，Ｃ５の各第１終端Ｐ５，Ｐ９，Ｐ１３を始端とし、この始端からその下流側の各ガイド終端位置Ｐ１６〜Ｐ１８まで直線状に延びて、平面視の流路がテーパ状に形成されている。
ここで、図５Ａ〜図５Ｃに示す屈曲リム導水路２６（屈曲前流路３２）の上流端流路断面Ｓ２から屈曲前流路３２の上側領域Ａ３〜Ａ５内の各ガイド始端位置Ｐ４，Ｐ８，Ｐ１２の流路断面Ｓ６までの距離ｄ１については、ほぼ一定の距離に設定されている。 Next, as shown in FIG. 6A to FIG. 6C, the inner side surface 30 in each upper region A3, A4, A5 of the pre-bending flow channel 34 of the bending rim water conduit 26 guides the wash water downstream with the guide surface G1. , G2 and G3, and the guide surfaces G1, G2 and G3 include first curved surfaces C1, C3 and C5, and tapered surfaces T13, T14 and T15 on the downstream side thereof.
Further, the start positions (guide start positions) of the guide surfaces G1, G2 and G3 are located downstream of the upstream end position P1 of the pre-bending flow path 34, and each of the first curved surfaces C1, C3 and C5 It corresponds to the positions of the first start ends P4, P8 and P12.
Furthermore, as shown to FIG. 6A-FIG. 6C, each taper surface T13, T14, T15 makes each 1st end P5, P9, P13 of 1st curved surface C1, C3, C5 a starting point, and is downstream from this starting end Each of the guide end positions P16 to P18 linearly extends, and the flow path in plan view is tapered.
Here, each guide start end position P4, P8 in the upper area A3 to A5 of the pre-bending flow path 32 from the upstream end flow path section S2 of the bending rim conduit 26 (pre-bending flow path 32) shown in FIGS. 5A to 5C. The distance d1 to the flow channel cross-section S6 of P12 and P12 is set to a substantially constant distance.

つぎに、図６Ａ〜図６Ｃに示すように、各テーパ面Ｔ１３，Ｔ１４，Ｔ１５の平面視において、その始端位置Ｐ５，Ｐ９，Ｐ１３（第１曲面Ｃ１，Ｃ３，Ｃ５の各第１終端Ｐ５，Ｐ９，Ｐ１３）から各終端位置Ｐ１６〜Ｐ１８（ガイド面Ｇ１，Ｇ２，Ｇ３のガイド終端位置）までの各距離ｄ２，ｄ３，ｄ４は、各テーパ面Ｔ１３，Ｔ１４，Ｔ１５が下方から上方に位置する程小さくなるように設定されている（ｄ２＞ｄ３＞ｄ４）。   Next, as shown in FIGS. 6A to 6C, in plan view of the tapered surfaces T13, T14, and T15, the start positions P5, P9, and P13 (the first ends P5 of the first curved surfaces C1, C3, and C5, respectively). As for the distances d2, d3 and d4 from P9 and P13) to the respective end positions P16 to P18 (guide end positions of the guide surfaces G1, G2 and G3), the tapered surfaces T13, T14 and T15 are positioned from the lower side to the upper side It is set to be relatively small (d2> d3> d4).

つぎに、図５Ａ〜図５Ｃに示すように、各テーパ面Ｔ１３，Ｔ１４，Ｔ１５が、平面視において、屈曲リム導水路２６の折り返し境界断面Ｓ４と成す角度をテーパ角度α，β，γとそれぞれ定義すると、各テーパ角度α，β，γは、各テーパ面Ｔ１３，Ｔ１４，Ｔ１５が下方から上方に位置する程小さくなるように設定されている（α＞β＞γ）。   Next, as shown in FIGS. 5A to 5C, angles formed by the tapered surfaces T13, T14 and T15 with the folded boundary cross section S4 of the bending rim water channel 26 in plan view are respectively referred to as taper angles α, β and γ. When defined, the taper angles α, β and γ are set to be smaller as the taper surfaces T13, T14 and T15 are positioned from the bottom to the top (α> β> γ).

また、図５Ａ〜図６Ｃに示すように、屈曲リム導水路２６の屈曲前流路３４の各上側領域Ａ３，Ａ４，Ａ５における内側面３０の各テーパ面Ｔ１３，Ｔ１４，Ｔ１５は、従来の水洗大便器２００の屈曲リム導水路２１２の屈曲前流路２３４の内側面２３０よりも後方に位置している。その分、図５Ａ〜図６Ｃに示すように、屈曲リム導水路２６の屈曲前流路３４の各テーパ面Ｔ１３，Ｔ１４，Ｔ１５の近傍の流路の容積Ｖ１が、従来の屈曲リム導水路２１２の屈曲前流路２３４のものよりも拡大されるように設定されている。   In addition, as shown in FIGS. 5A to 6C, the tapered surfaces T13, T14, and T15 of the inner side surface 30 in the upper regions A3, A4, and A5 of the pre-bending passage 34 of the bending rim conduit 26 are conventionally cleaned with water. It is located rearward of the inner surface 230 of the pre-bending flow passage 234 of the bent rim channel 212 of the toilet 200. As a result, as shown in FIGS. 5A to 6C, the volume V1 of the flow path in the vicinity of each tapered surface T13, T14, T15 of the flow path 34 before bending of the bending rim water channel 26 corresponds to the conventional bending rim water channel 212. It is set to be larger than that of the pre-bending channel 234 of

つぎに、上述した本発明の第１実施形態による水洗大便器１における作用について説明する。
まず、本発明の第１実施形態による水洗大便器１によれば、図５Ａ〜図６Ｃに示す屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ５）内の水平断面において、屈曲前流路３４の内側面３０の平面視の曲率半径ρ３，ρ５，ρ７が最小となる曲面を含む第１曲面Ｃ１，Ｃ３，Ｃ５における第１接平面Ｔ１，Ｔ５，Ｔ９と第２接平面Ｔ２，Ｔ６，Ｔ１０とが互いに交差する平面視の第１交差角度θ１，θ２，θ３が、屈曲前流路３４の外側面３２の平面視の曲率半径ρ４，ρ６，ρ８が最小となる曲面を含む第２曲面Ｃ２，Ｃ４，Ｃ６における第３接平面Ｔ３，Ｔ７，Ｔ１１と第４接平面Ｔ４，Ｔ８，Ｔ１２とが互いに交差する平面視の第２交差角度φ１，φ２，φ３よりも大きく設定されている。このため、屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ５）内における流路断面の横幅が局所的に小さくなってしまうことを抑制することができる。
したがって、屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ５）内において洗浄水が流れ易くなる。よって、屈曲リム導水路２６の上流端から下流端までの流路全域において、洗浄水が流れない部分が発生することを抑制することができ、洗浄水の流れが乱れることを抑制することができる。その結果、リム吐水口１６から吐水される洗浄水の飛び散りを抑制することができる。
また、図５〜図６Ｃに示すように、屈曲前流路３４に流入した洗浄水が、屈曲前流路３４の下流端付近（折り返し境界断面Ｓ４の直前）の領域において、屈曲前流路３４の外側面３２の外側角部３２ａに一旦衝突した後に、下流側にスムーズに安定してガイドされるスペースが十分に確保される。これにより、屈曲リム導水路２６の屈曲前流路３４の流路断面の横幅が局所的に小さくなっていても、屈曲前流路３４内に流入した洗浄水が屈曲後流路３６に流れ込み易くなるため、屈曲リム導水路２６内全域においても洗浄水が流れ易くなる。よって、屈曲リム導水路２６内全域において、洗浄水の流れが乱れることを抑制することができる。
さらに、図５〜図６Ｃに示すように、屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ５）内に流入した洗浄水の一部は、屈曲前流路３４の下流端付近（折り返し境界断面Ｓ４の直前）の領域を通過する前に、屈曲前流路３４の外側面３２の外側角部３２ａに一旦衝突した後に上昇する流れを形成する。これにより、屈曲リム導水路２６の屈曲前流路３４内の上方に溜まり易い空気は、屈曲前流路３４内を上昇する洗浄水により、効率良く攪拌される。
したがって、屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ５）内に溜まり易い空気について、屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ５）内を通過する洗浄水が効率よく粉砕して下流側に追い出すことができるため、空気の巻き込みによる異音の発生を抑制することもできる。 Below, the effect | action in the flush toilet 1 by 1st Embodiment of this invention mentioned above is demonstrated.
First, according to the flush toilet 1 according to the first embodiment of the present invention, in the horizontal cross section in the upper region A2 (A3 to A5) of the pre-bending flow channel 34 of the bending rim conduit 26 shown in FIGS. 5A to 6C. , And the first tangent plane T1, T5, T9 in the first curved surface C1, C3, C5 including the curved surface in which the curvature radius 33, 55, ρ7 of the inner side surface 30 of the pre-bending passage 34 in plan view is minimized A curved surface where the first intersection angles θ1, θ2 and θ3 in plan view where the planes T2, T6 and T10 intersect with each other have a minimum radius of curvature ρ4, 66 and 88 in plan view of the outer surface 32 of the flow path before bending 34 Larger than the second intersecting angles φ1, φ2, φ3 in plan view in which the third tangent planes T3, T7, T11 and the fourth tangent planes T4, T8, T12 intersect each other in the second curved surfaces C2, C4, C6 including It is set. For this reason, it can suppress that the horizontal width of the flow-path cross section in the upper side area A2 (A3-A5) of the flow path 34 before the bending of the bending rim channel 26 becomes small locally.
Therefore, the washing water can easily flow in the upper region A2 (A3 to A5) of the pre-bending flow channel 34 of the bent rim conduit 26. Therefore, it is possible to suppress the generation of the portion where the washing water does not flow in the entire flow path from the upstream end to the downstream end of the bent rim conduit 26, and it is possible to suppress the flow of the washing water from being disturbed. . As a result, it is possible to suppress spattering of the washing water spouted from the rim spout 16.
Further, as shown in FIG. 5 to FIG. 6C, the washing water having flowed into the pre-bending flow channel 34 is in the region near the downstream end of the pre-bending flow channel 34 (immediately before the folded boundary cross section S4). Once the outer corner 32a of the outer side surface 32 collides, a space which is smoothly and stably guided downstream is sufficiently secured. Thereby, even if the lateral width of the flow passage cross section of the bending rim water conduit 26 before bending is locally reduced, the wash water flowing into the flow before bending 34 flows easily into the flow passage 36 after bending. As a result, the cleaning water can easily flow in the entire area of the bending rim channel 26 as well. Therefore, it is possible to suppress the flow of washing water from being disturbed in the entire area of the bending rim conduit 26.
Furthermore, as shown in FIG. 5 to FIG. 6C, part of the washing water that has flowed into the upper region A2 (A3 to A5) of the pre-bending flow channel 34 of the bending rim conduit 26 is downstream of the pre-bending flow channel 34. Before passing through the area near the end (immediately before the folded boundary cross section S4), it forms a rising flow after colliding with the outer corner 32a of the outer side surface 32 of the pre-bending flow channel 34. As a result, the air that tends to accumulate in the pre-bending flow channel 34 of the bent rim conduit 26 is efficiently agitated by the washing water rising in the pre-bending flow channel 34.
Therefore, with regard to the air that tends to be accumulated in the upper region A2 (A3 to A5) of the pre-flexion flow passage 34 of the bending rim conduit 26, the wash water passing through the upper region A2 (A3 to A5) of the pre-flexion flow passage 34 Since the pulverization can be efficiently performed and driven to the downstream side, it is possible to suppress the generation of abnormal noise due to the entrainment of air.

本実施形態による水洗大便器１とは異なる一般的な水洗大便器においては、屈曲リム導水路内を流れる洗浄水は、重力の作用により、屈曲リム導水路内の下方領域になる程流れ易く、上方領域になる程流れ難くなる。
これに対し、本実施形態による水洗大便器１によれば、屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ）内の内側面３０の平面視の第１曲面Ｃ１，Ｃ３，Ｃ５における第１接平面Ｔ１，Ｔ５，Ｔ９と第２接平面Ｔ２，Ｔ６，Ｔ１０とが互いに交差する平面視の第１交差角度θ１，θ２，θ３について、屈曲前流路３４が下方から上方に向かう程大きくしたことにより、図５Ａ〜図６Ｃに示す屈曲前流路３４内の各上側領域Ａ３〜Ａ５にも洗浄水が十分に流れ込み易くなる。
したがって、屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ５）内の洗浄水を屈曲後流路３６に向けてよりスムーズに安定してガイドすることができるため、リム吐水口１６から吐水される洗浄水の飛び散りをより効果的に抑制することができる。
また、屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ５）内に溜まり易い空気について、通過する洗浄水によりさらに効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をより効果的に抑制することもできる。 In a general flush toilet different from the flush toilet 1 according to the present embodiment, the flush water flowing in the bent rim channel is likely to flow to the lower region in the bent rim channel by the action of gravity. The higher the region is, the harder it is to flow.
On the other hand, according to the flush toilet 1 according to the present embodiment, the first curved surfaces C1, C3 and C5 of the inner side surface 30 in the upper region A2 (A3 to A) of the flow channel before bending 34 With respect to the first intersection angles θ1, θ2, θ3 in plan view in which the tangent planes T1, T5, T9 and the second tangent planes T2, T6, T10 intersect with each other, the flow path 34 before bending is increased as it goes upward from below As a result, the washing water easily flows into the upper regions A3 to A5 in the pre-bending flow channel 34 illustrated in FIGS. 5A to 6C.
Therefore, the wash water in the upper region A2 (A3 to A5) of the pre-flex flow channel 34 of the flexed rim conduit 26 can be guided more smoothly and stably toward the post-flex flow channel 36, so It is possible to more effectively suppress the spatter of the washing water discharged from the water port 16.
In addition, air that is likely to be accumulated in the upper region A2 (A3 to A5) of the pre-bending flow channel 34 of the bent rim conduit 26 is more efficiently stirred and crushed by the passing washing water, and then expelled downstream. Therefore, it is possible to more effectively suppress the generation of abnormal noise due to air entrainment.

さらに、本実施形態による水洗大便器１によれば、図５Ａ〜図６Ｃに示すように、屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ２（Ａ３〜Ａ５）内の内側面３０が、屈曲前流路３４の上流端位置Ｐ１よりも下流側の各ガイド始端位置Ｐ４，Ｐ８，Ｐ１２からその下流側の各ガイド終端位置Ｐ１６〜Ｐ１８まで洗浄水をガイドするガイド面Ｇ１，Ｇ２，Ｇ３を備えており、このガイド面Ｇ１，Ｇ２，Ｇ３が第１曲面Ｃ１，Ｃ３，Ｃ５を含んでいる。これにより、屈曲リム導水路２６の屈曲前流路３４の各上側領域Ａ３〜Ａ５の洗浄水について、第１曲面Ｃ１，Ｃ３，Ｃ５を含むガイド面Ｇ１，Ｇ２，Ｇ３に沿って屈曲後流路３６に向けてよりスムーズに安定してガイドすることができる。
したがって、屈曲リム導水路２６の屈曲前流路３４の各上側領域Ａ３〜Ａ５内に溜まり易い空気について、各ガイド面Ｇ１，Ｇ２，Ｇ３に沿って流れる洗浄水が、さらにより効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をより効果的に抑制することもできる。 Furthermore, according to the flush toilet 1 according to the present embodiment, as shown in FIGS. 5A to 6C, the inner side surface 30 in the upper region A2 (A3 to A5) of the pre-bending flow channel 34 of the bending rim channel 26 Guide surfaces G1, G2, G3 for guiding the washing water from the guide start positions P4, P8, P12 on the downstream side of the upstream end position P1 of the pre-bending passage 34 to the guide end positions P16 to P18 on the downstream side thereof. The guide surfaces G1, G2, G3 include the first curved surfaces C1, C3, C5. Thereby, with regard to the washing water of each upper region A3 to A5 of the pre-bending flow channel 34 of the bending rim conduit 26, the after-bending flow channel along the guide surfaces G1, G2, and G3 including the first curved surfaces C1, C3 and C5 It can be guided more smoothly and stably towards 36.
Therefore, with regard to the air which tends to be accumulated in the upper regions A3 to A5 of the pre-bending flow channel 34 of the bent rim conduit 26, the washing water flowing along the respective guide surfaces G1, G2, and G3 is stirred more efficiently. After being crushed, it can be expelled to the downstream side, so it is possible to more effectively suppress the generation of abnormal noise due to air entrainment.

また、本実施形態による水洗大便器１によれば、図６Ａ〜図６Ｃに示すように、屈曲リム導水路２６の屈曲前流路３４の内側面３０の各ガイド面Ｇ１，Ｇ２，Ｇ３が、第１曲面Ｃ１，Ｃ３，Ｃ５と、この第１曲面Ｃ１，Ｃ３，Ｃ５の第１終端Ｐ５，Ｐ９，Ｐ１３からその下流側のガイド終端位置Ｐ１６〜Ｐ１８まで平面視でテーパ状に形成されているテーパ面Ｔ１３〜Ｔ１５を備えている。このため、屈曲リム導水路２６の屈曲前流路３４の各上側領域Ａ３〜Ａ５の洗浄水について、ガイド面Ｇ１，Ｇ２，Ｇ３である第１曲面Ｃ１，Ｃ３，Ｃ５及びテーパ面Ｔ１３〜Ｔ１５に沿って屈曲後流路３６に向けてさらによりスムーズに安定してガイドすることができる。
したがって、屈曲リム導水路２６の屈曲前流路３４の各上側領域Ａ３〜Ａ５内に溜まり易い空気について、各ガイド面（テーパ面）Ｇ１，Ｇ２，Ｇ３に沿って流れる洗浄水が、さらにより効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をさらにより効果的に抑制することもできる。 Moreover, according to the flush toilet 1 according to the present embodiment, as shown in FIGS. 6A to 6C, each of the guide surfaces G1, G2, G3 of the inner side surface 30 of the flow path 34 before bending of the bending rim channel 26 The first curved surface C1, C3, C5 and the first end P5, P9, P13 of the first curved surface C1, C3, C5 to the guide end position P16 to P18 on the downstream side are tapered in a plan view Tapered surfaces T13 to T15 are provided. For this reason, with regard to the washing water of each upper region A3 to A5 of the pre-bending flow channel 34 of the bending rim water conduit 26, the first curved surfaces C1, C3 and C5 which are the guide surfaces G1, G2 and G3 and the tapered surfaces T13 to T15. It can be guided more smoothly and stably toward the flow path 36 after bending along.
Therefore, with regard to the air that tends to be accumulated in the upper regions A3 to A5 of the pre-bending flow channel 34 of the bent rim conduit 26, the washing water flowing along each guide surface (taper surface) G1, G2, G3 is even more efficient. After being thoroughly stirred and crushed, it can be expelled to the downstream side, so that generation of abnormal noise due to air entrainment can be further effectively suppressed.

さらに、本実施形態による水洗大便器１によれば、図６Ａ〜図６Ｃに示すように、屈曲リム導水路２６の屈曲前流路３４の内側面３０の各ガイド面Ｇ１，Ｇ２，Ｇ３のテーパ面Ｔ１３〜Ｔ１５について、その平面視におけるテーパ面Ｔ１３〜Ｔ１５の始端（第１曲面Ｃ１，Ｃ３，Ｃ５の第１終端）Ｐ５，Ｐ９，Ｐ１３から各ガイド終端位置Ｐ１６〜Ｐ１８までの各距離ｄ２〜ｄ４が、テーパ面Ｔ１３〜Ｔ１５が下方から上方に位置する程小さくなる。このため、屈曲リム導水路２６の屈曲前流路３４の各上側領域Ａ３〜Ａ５の洗浄水について、第１曲面Ｃ１，Ｃ３，Ｃ５及びテーパ面Ｔ１３〜Ｔ１５に沿って屈曲後流路３６に向けてさらによりスムーズに安定してガイドすることができる。
したがって、屈曲リム導水路２６の屈曲前流路３４の各上側領域Ａ３〜Ａ５内に溜まり易い空気について、各ガイド面（テーパ面）Ｇ１，Ｇ２，Ｇ３に沿って流れる洗浄水が、さらにより効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をさらにより効果的に抑制することもできる。 Furthermore, according to the flush toilet 1 according to the present embodiment, as shown in FIGS. 6A to 6C, the tapers of the guide surfaces G1, G2, and G3 of the inner side surface 30 of the flow path 34 before bending of the bending rim channel 26 With respect to surfaces T13 to T15, distances d2 to d respectively from guide start positions P16 to P18 from the start ends (first ends of first curved surfaces C1, C3 and C5) P5, P9 and P13 of tapered surfaces T13 to T15 in plan view The d4 decreases as the tapered surfaces T13 to T15 are positioned from the lower side to the upper side. For this reason, the washing water of each upper region A3 to A5 of the pre-bending flow channel 34 of the bending rim water conduit 26 is directed to the after-bending flow channel 36 along the first curved surfaces C1, C3 and C5 and the tapered surfaces T13 to T15. Can be guided more smoothly and stably.
Therefore, with regard to the air that tends to be accumulated in the upper regions A3 to A5 of the pre-bending flow channel 34 of the bent rim conduit 26, the washing water flowing along each guide surface (taper surface) G1, G2, G3 is even more efficient. After being thoroughly stirred and crushed, it can be expelled to the downstream side, so that generation of abnormal noise due to air entrainment can be further effectively suppressed.

つぎに、図７Ａ〜図８Ｃを参照して、本発明の第２実施形態による水洗大便器１００について説明する。
まず、図７Ａは、本発明の第２実施形態による水洗大便器の便器本体の外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の図５Ａと同様な部分拡大平面断面図である。また、図７Ｂは、本発明の第２実施形態による水洗大便器の便器本体の外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の図５Ｂと同様な部分拡大平面断面図である。さらに、図７Ｃは、本発明の第２実施形態による水洗大便器の便器本体の外側リム導水路内及び屈曲リム導水路内のそれぞれの上側領域の図５Ｃと同様な部分拡大平面断面図である。
つぎに、図８Ａは、図７ＡのＡ部拡大図である。また、図８Ｂは、図７ＢのＢ部拡大図である。さらに、図８Ｃは、図７ＣのＣ部拡大図である。
ここで、図７Ａ〜図８Ｃに示す本発明の第２実施形態による水洗大便器１００において、図１〜図６Ｃに示す本発明の第１実施形態による水洗大便器１の部分と同一部分については同一の符号を付し、これらの説明については省略する。
すなわち、図７Ａ〜図８Ｃに示すように、本発明の第２実施形態による水洗大便器１００においては、屈曲リム導水路１２６の屈曲前流路１３４の上側領域Ａ３〜Ａ５の内側面１３０の部分が、図５〜図５Ｃに示す上述した本発明の第１実施形態による水洗大便器１の屈曲リム導水路２６の屈曲前流路３４の上側領域Ａ３〜Ａ５の内側面３０の部分と異なっており、その他の部分は、第１実施形態の水洗大便器１と共通している。
よって、以下、本発明の第２実施形態による水洗大便器１００においては、屈曲リム導水路１２６の屈曲前流路１３４の上側領域Ａ３〜Ａ５の内側面１３０のみについて、具体的に説明する。 Next, a flush toilet 100 according to a second embodiment of the present invention will be described with reference to FIGS. 7A to 8C.
First, FIG. 7A is a partially enlarged plan sectional view similar to FIG. 5A of the upper region in the outer rim water conduit and in the bent rim water conduit of the toilet bowl body of the flush toilet according to the second embodiment of the present invention . FIG. 7B is a partially enlarged plan sectional view similar to FIG. 5B of the upper region in the outer rim water conduit and the bent rim water conduit of the toilet bowl body of the flush toilet according to the second embodiment of the present invention . Furthermore, FIG. 7C is a partially enlarged plan sectional view similar to FIG. 5C of the upper region in the outer rim water conduit and in the bent rim water conduit of the toilet bowl body of the flush toilet according to the second embodiment of the present invention .
Next, FIG. 8A is an enlarged view of a portion A of FIG. 7A. FIG. 8B is an enlarged view of a portion B of FIG. 7B. Further, FIG. 8C is an enlarged view of a portion C of FIG. 7C.
Here, in the flush toilet 100 according to the second embodiment of the present invention shown in FIGS. 7A to 8C, the same parts as the portions of the flush toilet 1 according to the first embodiment of the present invention shown in FIGS. The same reference numerals are given and description thereof is omitted.
That is, as shown in FIGS. 7A to 8C, in the flush toilet 100 according to the second embodiment of the present invention, a portion of the inner side surface 130 of the upper regions A3 to A5 of the pre-bending flow passage 134 of the bending rim conduit 126 5 to 5C different from the portion of the inner side surface 30 of the upper region A3 to A5 of the pre-bending flow passage 34 of the bent rim water conduit 26 of the flush toilet 1 according to the above-described first embodiment of the present invention shown in FIGS. The other parts are common to the flush toilet 1 of the first embodiment.
Therefore, in the flush toilet 100 according to the second embodiment of the present invention, only the inner side surface 130 of the upper regions A3 to A5 of the pre-bending flow channel 134 of the bending rim channel 126 will be specifically described.

まず、図７Ａ〜図７Ｃにおいては、本実施形態の水洗大便器１００の外側リム導水路２４及び屈曲リム導水路１２６内のそれぞれの上側領域Ａ３〜Ａ５の流路と下側領域Ａ１の流路との比較のため、図５に示す本実施形態の水洗大便器１の外側リム導水路内２４、屈曲リム導水路内２６のそれぞれの下側領域Ａ１、及び、内側リム導水路２８について鎖線等の想像線で示している。
また、図７Ａ〜図８Ｃにおいては、本実施形態の水洗大便器１００の外側リム導水路２４及び屈曲リム導水路１２６内のそれぞれの上側領域Ａ３〜Ａ５の流路と同一高さ位置における従来の屈曲リム導水路２１２の屈曲前流路２３４やその内側面２３４に関する外形について鎖線等の想像線で示している。 First, in FIGS. 7A to 7C, the flow path of the upper area A3 to A5 and the flow path of the lower area A1 in the outer rim water conduit 24 and the bent rim water conduit 126 of the flush toilet 100 of this embodiment. For comparison with the above, the lower region A1 in the outer rim water conduit 24 of the flush toilet 1 of the present embodiment shown in FIG. 5, the lower region A1 in the bent rim water conduit 26 and the inner rim water conduit 28 shown in FIG. It shows with the imaginary line of.
Further, in FIGS. 7A to 8C, the conventional rim at the same height position as the flow path in the upper area A3 to A5 in the outer rim water conduit 24 and the bent rim water conduit 126 of the flush toilet 100 of this embodiment. The outlines of the pre-bending flow passage 234 of the bent rim conduit 212 and its outer side surface 234 are indicated by imaginary lines such as dashed lines.

図７Ａ〜図８Ｃに示すように、本実施形態の水洗大便器１００においては、屈曲リム導水路１２６の屈曲前流路１３４の各上側領域Ａ３，Ａ４，Ａ５における内側面１３０の各ガイド面Ｇ１０１，Ｇ１０２，Ｇ１０３は、その大半が平面視で湾曲状の第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５を形成している。
これにより、図８Ａ〜図８Ｃに示すように、各ガイド面Ｇ１０１，Ｇ１０２，Ｇ１０３は、平面視において、第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５の第１始端Ｐ１０４，Ｐ１０８，Ｐ１１２（ガイド始端位置）から第１終端Ｐ１０５，Ｐ１０９，Ｐ１１３（ガイド始端位置）まで湾曲状の曲面に沿って洗浄水を下流側へガイド可能になっている。
また、図７Ａ〜図７Ｃに示すように、屈曲前流路３２の上流端位置Ｐ１の流路断面Ｓ２から屈曲前流路１３４の各ガイド始端位置Ｐ１０４，Ｐ１０８，Ｐ１１２の各流路断面Ｓ１０６，Ｓ１０７，Ｓ１０８までの各距離ｄ１０１，ｄ１０２，１０３は、下方から上方に位置する程小さくなるように設定されている（ｄ１０１＞ｄ１０２＞ｄ１０３）。
つぎに、図８Ａ〜図８Ｃに示すように、各ガイド面Ｇ１０１，Ｇ１０２，Ｇ１０３は、平面視において、第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５の各第１始端（ガイド始端位置）Ｐ１０４，Ｐ１０８，Ｐ１１２から各第１終端（ガイド終端位置）Ｐ１０５，Ｐ１０９，Ｐ１１３までの区間において、最小曲率半径ρ１０３，ρ１０５，ρ１０７をそれぞれ備えている。 As shown to FIG. 7A-FIG. 8C, in the flush toilet 100 of this embodiment, each guide surface G101 of the inner surface 130 in each upper area A3, A4, A5 of the flow path 134 before bending of the bending rim channel 126 , G102, G103, most of which form curved first curved surfaces C101, C103, C105 in plan view.
Thereby, as shown to FIG. 8A-FIG. 8C, each guide surface G101, G102, G103 is a planar view from 1st first end P104 of the 1st curved surface C101, C103, C105, P108, P112 (guide starting end position) The washing water can be guided downstream along the curved curved surface up to the first end P105, P109, P113 (guide start position).
Further, as shown in FIGS. 7A to 7C, the flow channel cross section S2 of the upstream end position P1 of the pre-bending flow channel 32 to the respective guide start end positions P104, P108, P112 of the pre-bending flow channel 134 The respective distances d101, d102 and 103 to S107 and S108 are set to be smaller as they are positioned higher from the lower side (d101>d102> d103).
Next, as shown in FIGS. 8A to 8C, each of the guide surfaces G101, G102, and G103 has a first start end (guide start position) P104, P108, and P112 of the first curved surface C101, C103, and C105 in plan view. The minimum curvature radius 103, 105105, and 107107 are respectively provided in the section from the point to the first end (guide end position) P105, P109, and P113.

つぎに、図８Ａ〜図８Ｃに示すように、屈曲前流路１３４の各上側領域Ａ３，Ａ４，Ａ５においては、内側面１３０の第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５における各第１接平面Ｔ１０１，Ｔ１０５，Ｔ１０９と各第２接平面Ｔ１０２，Ｔ１０６，Ｔ１１０とが互いに交差する第１交差角度θ１０１，１０２，１０３は、外側面３２の第２曲面Ｃ２，Ｃ４，Ｃ６における各第３接平面Ｔ３，Ｔ７，Ｔ１１と各第４接平面Ｔ４，Ｔ８，Ｔ１２とが互いに交差する第２交差角度φ１，φ２，φ３よりも大きく設定されている（θ１０１＞φ１、θ１０２＞φ２、θ１０３＞φ３）。
さらに、図８Ａ〜図８Ｃに示すように、第１交差角度θ１０１，θ１０２，θ１０３は、屈曲前流路１３４の上側領域Ａ２内の流路が下方から上方に向かう程大きくなるように設定されている（θ１０１＜θ１０２＜θ１０３）。 Next, as shown in FIGS. 8A to 8C, in the upper regions A3, A4, and A5 of the pre-bending flow channel 134, the first tangent planes T101 and T101 on the first curved surfaces C101, C103, and C105 of the inner surface 130. The first intersection angles θ101, 102, and 103 at which T105, T109 and the second tangent planes T102, T106, T110 intersect with each other form third tangent planes T3, T3 at the second curved surfaces C2, C4, C6 of the outer surface 32. The distance T7, T11 and the fourth tangent planes T4, T8, T12 are set to be larger than the second crossing angles φ1, φ2, φ3 (θ101> φ1, θ102> φ2, θ103> φ3).
Furthermore, as shown in FIGS. 8A to 8C, the first intersection angles θ101, θ102, and θ103 are set so that the flow path in the upper region A2 of the flow path 134 before bending becomes larger from the lower side to the upper side (Θ101 <θ102 <θ103).

また、図７Ａ〜図８Ｃに示すように、屈曲リム導水路１２６の屈曲前流路１３４の各上側領域Ａ３，Ａ４，Ａ５における各ガイド面Ｇ１０１，Ｇ１０２，Ｇ１０３を含む内側面１３０は、従来の水洗大便器２００の屈曲リム導水路２１２の屈曲前流路２３４の内側面２３０よりも後方に位置している。その分、図６Ａ〜図６Ｃに示すように、屈曲リム導水路１２６の屈曲前流路１３４の各ガイド面Ｇ１０１，Ｇ１０２，Ｇ１０３の近傍の流路の容積Ｖ１０１が、従来の屈曲リム導水路２１２の屈曲前流路２３４のものよりも拡大されるように設定されている。   Further, as shown in FIGS. 7A to 8C, the inner side surface 130 including the guide surfaces G101, G102, and G103 in the upper regions A3, A4, and A5 of the pre-bending passage 134 of the bending rim conduit 126 is a conventional one. It is located rearward of the inner side surface 230 of the pre-bending flow passage 234 of the bent rim conduit 212 of the flush toilet 200. As a result, as shown in FIGS. 6A to 6C, the volume V101 of the flow path in the vicinity of each guide surface G101, G102, G103 of the pre-flexion flow path 134 of the curved rim water conduit 126 corresponds to the conventional curved rim water conduit 212. It is set to be larger than that of the pre-bending channel 234 of

上述した本発明の第２実施形態による水洗大便器１００によれば、図８Ａ〜図８Ｃに示すように、屈曲リム導水路１２６の屈曲前流路１３４の上側領域Ａ２（Ａ３〜Ａ５）内の水平断面において、屈曲前流路１３４の内側面１３０の平面視の曲率半径ρ１０３，ρ１０５，ρ１０７が最小となる曲面を含む第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５における第１接平面Ｔ１０１，Ｔ１０５，Ｔ１０９と第２接平面Ｔ１０２，Ｔ１０６，Ｔ１１０とが互いに交差する平面視の第１交差角度θ１０１，１０２，１０３が、屈曲前流路１３４の外側面３２の平面視の曲率半径ρ２，ρ４，ρ６が最小となる曲面を含む第２曲面Ｃ２，Ｃ４，Ｃ６における第３接平面Ｔ３，Ｔ７，Ｔ１１と第４接平面Ｔ４，Ｔ８，Ｔ１２とが互いに交差する平面視の第２交差角度φ１，φ２，φ３よりも大きい（θ１０１＞φ１、θ１０２＞φ２、θ１０３＞φ３）。
さらに、図８Ａ〜図８Ｃに示すように、第１交差角度θ１０１，θ１０２，θ１０３が、屈曲前流路１３４の上側領域Ａ２内の流路が下方から上方に向かう程大きい（θ１０１＜θ１０２＜θ１０３）。
これらにより、屈曲前流路１３４の各上側領域Ａ３〜Ａ５の横幅や流路断面積が局所的に小さくなることを抑制することができる。
したがって、屈曲リム導水路１２６の屈曲前流路１３４の上側領域Ａ２（Ａ３〜Ａ５）内に流入した洗浄水の一部は、屈曲前流路１３４の下流端付近（折り返し境界断面Ｓ４の直前）の領域を通過する前に、屈曲前流路１３４の外側面３２の外側角部３２ａに一旦衝突した後に上昇する流れを形成する。これにより、屈曲リム導水路１２６の屈曲前流路１３４内の上方に溜まり易い空気は、屈曲前流路１３４内を上昇する洗浄水により、効率良く攪拌される。
よって、図７Ａ〜図８Ｃに示す屈曲リム導水路１２６の屈曲前流路１３４の各上側領域Ａ３〜Ａ５の洗浄水を屈曲後流路３６に向けてスムーズに安定してガイドすることができるため、リム吐水口１６から吐水される洗浄水の飛び散りを効果的に抑制することができる。
また、図７Ａ〜図８Ｃに示す屈曲リム導水路１２６の屈曲前流路１３４の各上側領域Ａ３〜Ａ５内に溜まり易い空気について、洗浄水が効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生を効果的に抑制することもできる。 According to the flush toilet 100 according to the second embodiment of the present invention described above, as shown in FIGS. 8A to 8C, the upper portion A2 (A3 to A5) of the pre-bending flow passage 134 of the bending rim channel 126 is included. In the horizontal cross section, the first tangents T101, T105, and T109 in the first curved surfaces C101, C103, and C105 that include curved surfaces in which the curvature radii 103103, 105105, and 107107 of the inner side surface 130 of the pre-bending passage 134 are minimum The first intersection angles θ101, 102, and 103 in plan view where the second tangent planes T102, T106, and T110 intersect with each other have a minimum radius of curvature ρ2, 44, 66 in plan view of the outer surface 32 of the flow channel before bending 134. The second intersection in plan view where the third tangent planes T3, T7, T11 and the fourth tangent planes T4, T8, T12 in the second curved surfaces C2, C4, C6 including the curved surfaces intersect each other Degree φ1, φ2, larger than φ3 (θ101> φ1, θ102> φ2, θ103> φ3).
Furthermore, as shown in FIGS. 8A to 8C, the first intersection angles θ101, θ102, and θ103 become larger as the flow path in the upper region A2 of the flow path 134 before bending goes upward from the lower side (θ101 <θ102 <θ103). ).
By these, it can suppress that the horizontal width and flow-path cross-sectional area of each upper side area | region A3-A5 of the flow path 134 before bending | flexion become small locally.
Therefore, a part of the washing water which has flowed into the upper region A2 (A3 to A5) of the pre-bending channel 134 of the bending rim conduit 126 is near the downstream end of the pre-bending channel 134 (immediately before the folding boundary cross section S4) Before passing through the area of the front end of the flow path, the flow forms an ascending flow after colliding with the outer corner 32a of the outer surface 32 of the pre-bending passage 134. As a result, the air that tends to accumulate in the pre-bending flow channel 134 of the curved rim water conduit 126 is efficiently stirred by the washing water rising in the pre-bending flow channel 134.
Therefore, the washing water of each upper region A3 to A5 of the pre-bending flow channel 134 of the bending rim conduit 126 shown in FIGS. 7A to 8C can be smoothly and stably guided toward the post-flexing flow channel 36. The spatter of the flush water spouted from the rim spout 16 can be effectively suppressed.
7A to 8C, after the washing water efficiently stirs and crushes the air that tends to be accumulated in the upper regions A3 to A5 of the pre-bending flow channels 134 of the bent rim water conduit 126, on the downstream side. Since it is possible to drive out, it is also possible to effectively suppress the generation of abnormal noise due to air entrainment.

また、本実施形態による水洗大便器１００によれば、図７Ａ〜図８Ｃに示す屈曲リム導水路１２６の屈曲前流路１３４の内側面１３０の各ガイド面Ｇ１０１，Ｇ１０２，Ｇ１０３が、平面視において第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５の各第１始端（ガイド始端位置）Ｐ１０４，Ｐ１０８，Ｐ１１２から各第１終端（ガイド終端位置）Ｐ１０５，Ｐ１０９，Ｐ１１３まで洗浄水をガイドする湾曲状の曲面を形成している。
そして、図７Ａ〜図８Ｃに示すように、屈曲リム導水路１２６の屈曲前流路１３４の内側面１３０の各ガイド面Ｇ１０１，Ｇ１０２，Ｇ１０３の湾曲状の第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５について、屈曲前流路の内側面の平面視の曲率半径ρ１０３，ρ１０５，ρ１０７が最小となる曲面を含む第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５における第１接平面Ｔ１０１，Ｔ１０５，Ｔ１０９と第２接平面Ｔ１０２，Ｔ１０６，Ｔ１１０とが互いに交差する平面視の第１交差角度θ１０１，θ１０２，θ１０３が、ガイド面Ｇ１０１，Ｇ１０２，Ｇ１０３が下方から上方に位置する程大きくなる。
これらにより、屈曲リム導水路１２６の屈曲前流路１３４の上側領域Ａ３〜Ａ５内の洗浄水について、湾曲状の第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５に沿って屈曲後流路３６に向けてさらによりスムーズに安定してガイドすることができる。
したがって、屈曲リム導水路１２６の屈曲前流路１３４の上側領域Ａ３〜Ａ５内に溜まり易い空気について、ガイド面Ｇ１０１，Ｇ１０２，Ｇ１０３（湾曲状の第１曲面Ｃ１０１，Ｃ１０３，Ｃ１０５）に沿って流れる洗浄水が、さらにより効率よく攪拌して粉砕させた後、下流側に追い出すことができるため、空気の巻き込みによる異音の発生をさらにより効果的に抑制することもできる。 Moreover, according to the flush toilet 100 according to the present embodiment, each of the guide surfaces G101, G102, G103 of the inner side surface 130 of the flow path 134 before bending of the bending rim conduit 126 shown in FIGS. 7A to 8C is a plan view. A curved curved surface is formed to guide the washing water from the first start end (guide start position) P104, P108, P112 of each of the first curved surfaces C101, C103, C105 to the first end (guide end position) P105, P109, P113. doing.
And as shown to FIG. 7A-FIG. 8C, about 1st curved surface C101, C103, C105 of curved shape of each guide surface G101 of the inner surface 130 of the inner surface 130 of the flow path 134 before bending of the bending rim water channel 126, C103, C105, The first tangent plane T101, T105, T109 and the second tangent plane T102 in the first curved surface C101, C103, C105 including the curved surface in which the curvature radius 103103, 105105, ρ107 of the inner surface of the flow path before bending is minimum in plan view The first intersection angles θ101, θ102, and θ103 in plan view in which T106 and T110 intersect with each other become larger as the guide surfaces G101, G102, and G103 are positioned from the lower side to the upper side.
Thus, the washing water in the upper region A3 to A5 of the pre-bending flow channel 134 of the bent rim water conduit 126 is further directed along the curved first curved surfaces C101, C103, and C105 toward the post-bending flow channel 36. It can be guided smoothly and stably.
Therefore, air that tends to be accumulated in the upper regions A3 to A5 of the pre-bending flow channel 134 of the bent rim water conduit 126 flows along the guide surfaces G101, G102, and G103 (curved first curved surfaces C101, C103, and C105). After the washing water is stirred and crushed more efficiently, it can be expelled to the downstream side, so that generation of abnormal noise due to air entrainment can be further effectively suppressed.

１ 本発明の第１実施形態による水洗大便器
２ 便器本体
４ ボウル
６ リム
８ 汚物受け面
１０ 棚
１２ 排水トラップ管路（排水路）
１２ａ 排水トラップ管路の入口
１４ リム導水路（リム吐水部）
１４ａ リム導水路の入口
１６ リム吐水口
１８ 導水管（導水路）
２０ 通水路
２２ ジェット吐水口
２４ 外側リム導水路
２６ 屈曲リム導水路
２８ 内側リム導水路
３０ 屈曲リム導水路の内側面
３０ａ 屈曲リム導水路の内側面の先端部
３２ 屈曲リム導水路の外側面
３２ａ 屈曲リム導水路の外側面の外側角部
３２ｂ 屈曲リム導水路の外側面の内側角部
３４ 屈曲前流路
３６ 屈曲後流路
１００ 本発明の第２実施形態による水洗大便器
１２６ 屈曲リム導水路
１３０ 屈曲リム導水路の内側面
１３４ 屈曲前流路
２００ 従来の水洗大便器
２０２ 便器本体
２０４ ボウル
２０６ リム
２０８ リム導水路
２１０ 外側リム導水路
２１２ 屈曲リム導水路
２１４ リム吐水口
２１６ 内側リム導水路
２３０ 屈曲前流路の内側面
２３４ 屈曲前流路
Ａ１ 外側リム導水路内及び屈曲リム導水路内の下側領域
Ａ２ 外側リム導水路内及び屈曲リム導水路内の上側領域
Ａ３ 外側リム導水路内及び屈曲リム導水路内の上側領域
Ａ４ 外側リム導水路内及び屈曲リム導水路内の上側領域
Ａ５ 外側リム導水路内及び屈曲リム導水路内の上側領域
Ｂ ボウルの後方側領域
Ｃ１ 屈曲前流路の上側領域内の内側面の第１曲面
Ｃ２ 屈曲前流路の上側領域内の外側面の第２曲面
Ｃ３ 屈曲前流路の上側領域内の内側面の第１曲面
Ｃ４ 屈曲前流路の上側領域内の外側面の第２曲面
Ｃ５ 屈曲前流路の上側領域内の内側面の第１曲面
Ｃ６ 屈曲前流路の上側領域内の外側面の第２曲面
Ｃ７ 屈曲前流路の上側領域内の内側面の第１曲面
Ｃ８ 屈曲前流路の上側領域内の外側面の第２曲面
Ｃ１０１ 屈曲前流路の上側領域内の内側面の第１曲面
Ｃ１０３ 屈曲前流路の上側領域内の内側面の第１曲面
Ｃ１０５ 屈曲前流路の上側領域内の内側面の第１曲面
ｄ１ 屈曲リム導水路（屈曲前流路）の上流端流路断面から屈曲前流路のガイド始端位置の流路断面までの距離
ｄ２ 屈曲前流路のテーパ面の始端位置から終端位置までの距離（第１曲面の終端からガイド終端位置までの距離）
ｄ３ 屈曲前流路のテーパ面の始端位置から終端位置までの距離（第１曲面の終端からガイド終端位置までの距離）
ｄ４ 屈曲前流路のテーパ面の始端位置から終端位置までの距離（第１曲面の終端からガイド終端位置まで各距離）
ｄ１０１ 屈曲前流路の上流端流路断面から屈曲前流路のガイド始端位置の流路断面までの距離
ｄ１０２ 屈曲前流路の上流端流路断面から屈曲前流路のガイド始端位置の流路断面までの距離
ｄ１０３ 屈曲前流路の上流端流路断面から屈曲前流路のガイド始端位置の流路断面までの距離
Ｈ１ 外側リム導水路の流路断面の最大高さ寸法
Ｈ４ 屈曲リム導水路の折り返し境界断面の最大高さ寸法
Ｈ５ 内側リム導水路の流路断面及びリム吐水口の最大高さ寸法
Ｆ ボウルの前方側領域
Ｇ１ ガイド面（テーパ面）
Ｇ２ ガイド面（テーパ面）
Ｇ３ ガイド面（テーパ面）
Ｇ１０１ ガイド面（湾曲状の曲面）
Ｇ１０２ ガイド面（湾曲状の曲面）
Ｇ１０３ ガイド面（湾曲状の曲面）
Ｌ ボウルの左側領域
Ｏ ボウルの中心
Ｐ１ 外側リム導水路の下流端位置、屈曲リム導水路の上流端位置
Ｐ２ 内側リム導水路の上流端位置、屈曲リム導水路の下流端位置
Ｐ３ 屈曲リム導水路の下側領域内の内側面の前方側先端位置
Ｐ４ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１始端（ガイド始端位置）
Ｐ５ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１終端、テーパ面の始端位置
Ｐ６ 屈曲前流路の上側領域内の外側面の第２曲面の曲面形状の第２始端
Ｐ７ 屈曲前流路の上側領域内の外側面の第２曲面の曲面形状の第２終端
Ｐ８ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１始端（ガイド始端位置）
Ｐ９ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１終端、テーパ面の始端位置
Ｐ１０ 屈曲前流路の上側領域内の外側面の第２曲面の曲面形状の第２始端
Ｐ１１ 屈曲前流路の上側領域内の外側面の第２曲面の曲面形状の第２終端
Ｐ１２ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１始端（ガイド始端位置）
Ｐ１３ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１終端、テーパ面の始端位置
Ｐ１４ 屈曲前流路の上側領域内の外側面の第２曲面の曲面形状の第２始端
Ｐ１５ 屈曲前流路の上側領域内の外側面の第２曲面の曲面形状の第２終端
Ｐ１６ テーパ面の終端位置（ガイド終端位置）
Ｐ１７ テーパ面の終端位置（ガイド終端位置）
Ｐ１８ テーパ面の終端位置（ガイド終端位置）
Ｐ１０４ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１始端（ガイド始端位置）
Ｐ１０５ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１終端（ガイド終端位置）
Ｐ１０８ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１始端（ガイド始端位置）
Ｐ１０９ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１終端（ガイド終端位置）
Ｐ１１２ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１始端（ガイド始端位置）
Ｐ１１３ 屈曲前流路の上側領域内の内側面の第１曲面の曲面形状の第１終端（ガイド終端位置）
Ｒ ボウルの右側領域
Ｓ１ 外側リム導水路の流路断面
Ｓ２ 屈曲リム導水路の上流端の流路断面
Ｓ３ 屈曲リム導水路の下流端の流路断面
Ｓ４ 屈曲リム導水路の折り返し境界断面
Ｓ５ 内側リム導水路の流路断面
Ｓ６ 屈曲リム導水路のガイド始端位置の流路断面
Ｔ１ 第１接平面
Ｔ２ 第２接平面
Ｔ３ 第３接平面
Ｔ４ 第４接平面
Ｔ５ 第１接平面
Ｔ６ 第２接平面
Ｔ７ 第３接平面
Ｔ８ 第４接平面
Ｔ９ 第１接平面
Ｔ１０ 第２接平面
Ｔ１１ 第３接平面
Ｔ１２ 第４接平面
Ｔ１３ テーパ面
Ｔ１４ テーパ面
Ｔ１５ テーパ面
Ｔ１０１ 第１接平面
Ｔ１０２ 第２接平面
Ｔ１０５ 第１接平面
Ｔ１０６ 第２接平面
Ｔ１０９ 第１接平面
Ｔ１１０ 第２接平面
Ｕ リム導水路の屈曲形状の領域
Ｖ１ 拡大された流路の容積
Ｖ１０１ 拡大された流路の容積
Ｘ ボウルを前後方向に二等分する左右方向に延びる中心軸線
Ｙ ボウルを水平方向に二等分する前後方向に延びる中心軸線
Ｚ ボウルの中心を通る鉛直方向の中心軸線
α ガイド面のテーパ角度
β ガイド面のテーパ角度
γ ガイド面のテーパ角度
θ１ 第１接平面と第２接平面とが互いに交差する平面視の第１交差角度
θ２ 第１接平面と第２接平面とが互いに交差する平面視の第１交差角度
θ３ 第１接平面と第２接平面とが互いに交差する平面視の第１交差角度
θ１０１ 第１接平面と第２接平面とが互いに交差する平面視の第１交差角度
θ１０２ 第１接平面と第２接平面とが互いに交差する平面視の第１交差角度
θ１０３ 第１接平面と第２接平面とが互いに交差する平面視の第１交差角度
ρ１ 屈曲前流路の外側面の平面視の最小の曲率半径
ρ２ 屈曲前流路の内側面の平面視の最小の曲率半径
ρ３ 屈曲前流路の上側領域における内側面の平面視の最小曲率半径
ρ４ 屈曲前流路の上側領域における外側面の平面視の最小曲率半径
ρ５ 屈曲前流路の上側領域における内側面の平面視の最小曲率半径
ρ６ 屈曲前流路の上側領域における外側面の平面視の最小曲率半径
ρ７ 屈曲前流路の上側領域における内側面の平面視の最小曲率半径
ρ８ 屈曲前流路の上側領域における外側面の平面視の最小曲率半径
ρ９ 屈曲後流路における外側面の平面視の最小曲率半径
ρ１０ 屈曲後流路における内側面の平面視の最小曲率半径
ρ１０１ 屈曲前流路の内側面のガイド面の平面視の最小曲率半径
ρ１０２ 屈曲前流路の内側面のガイド面の平面視の最小曲率半径
ρ１０３ 屈曲前流路の内側面のガイド面の平面視の最小曲率半径
φ１ 第３接平面と第４接平面とが互いに交差する平面視の第２交差角度
φ２ 第３接平面と第４接平面とが互いに交差する平面視の第２交差角度
φ３ 第３接平面と第４接平面とが互いに交差する平面視の第２交差角度 1 flush toilet according to the first embodiment of the present invention 2 toilet bowl main body 4 bowl 6 rim 8 dirt receiving surface 10 shelf 12 drainage trap pipeline (drainage channel)
12a drain trap pipeline inlet 14 rim water conduit (rim spout section)
14a Rim channel inlet 16 rim outlet 18 channel (channel)
Reference Signs List 20 water channel 22 jet water discharge port 24 outer rim water channel 26 flexed rim water channel 28 inner rim water channel 30 inner surface of flexed rim channel 30a tip of inner side surface of flexed rim channel 32 outer surface of flexed rim channel 32a Outer corner 32b of the outer surface of the flexed rim conduit Internal corner portion 34b of the outer surface of the flexed rim conduit 34 pre-bent channel 36 post-flexed channel 100 flush toilet according to the second embodiment of the invention 126 flexed rim channel 130 Bent rim water channel inner surface 134 Bent flow channel 200 Conventional flush toilet 202 Toilet main body 204 Bowl 206 Rim 208 Rim water channel 210 Outer rim water channel 212 Flex rim water channel 214 Rim spout 216 Inner rim water channel 230 The inner side of the pre-bending channel 234 The pre-bending channel A1 Outer region in the outer rim channel and lower region in the curved rim channel A2 outside Upper region in the water conduit and in the flexed rim conduit A3 Upper region in the outer rim conduit and in the flexed rim conduit A4 Upper region in the outer rim conduit and in the flexed rim conduit A5 inside the outer rim conduit and Upper region B in the curved rim water channel B back side region of the bowl C1 first curved surface of the inner surface in the upper region of the pre-flexing channel C2 second curved surface in the upper region of the pre-flexing channel C3 curved front The first curved surface C4 of the inner surface in the upper region of the channel The second curved surface C5 of the outer surface in the upper region of the channel before bending C5 The first curved surface of the inner surface in the upper region of the channel before bending C6 The second curved surface C7 of the outer surface in the upper region The first curved surface C8 of the inner surface in the upper region of the channel before bending The second curved surface C101 of the upper region of the channel before bending the upper region of the channel before bending The first curved surface C103 on the inner surface of the inner side Inside the upper region of the flow path before bending The first curved surface C105 The first curved surface d1 of the inner side surface in the upper region of the pre-bending channel d1 The upstream end channel cross-section of the flexing rim water channel (pre-bending channel) Distance to d2 Distance from start position to end position of tapered surface of flow path before bending (distance from end of first curved surface to guide end position)
d3 The distance from the start position to the end position of the tapered surface of the flow path before bending (the distance from the end of the first curved surface to the guide end position)
d4 The distance from the start position to the end position of the tapered surface of the flow path before bending (each distance from the end of the first curved surface to the guide end position)
d101 The distance from the upstream end channel cross section of the channel before bending to the channel cross section of the guide start position of the channel before bending d102 The channel from the upstream end channel section of the channel before bending to the guide starting position of the channel before bending Distance to cross section d103 Distance from upstream end channel cross section of channel before bending to channel cross section of guide start position of channel before bending H1 Maximum height dimension of channel cross section of outer rim water channel H4 curved rim channel Maximum height dimension of folded back section of section H5 Channel section of inner rim water channel and maximum height dimension of rim spout F front side area of bowl G1 Guide surface (taper surface)
G2 Guide surface (Taper surface)
G3 Guide surface (Taper surface)
G101 Guide surface (curved curved surface)
G102 Guide surface (curved curved surface)
G103 Guide surface (curved curved surface)
L Bowl left side area O Center of bowl P1 downstream end position of outer rim channel, upstream end position of flexed rim channel P2 upstream end position of inner rim channel, downstream end position of flexed rim channel P3 flexed rim channel First tip end of the curved surface of the first curved surface of the inner surface in the upper region of the flow path before bending P4 (guide starting position)
P5 The first end of the curved surface shape of the first curved surface of the inner surface in the upper region of the pre-bending flow channel, the start position of the tapered surface P6 The second curved surface of the second curved surface of the outer surface in the upper region of the pre-bending flow channel 2) The second end of the curved surface of the second curved surface of the outer surface in the upper region of the flow path before bending P7: The second end of the curved surface of the second curved surface of the flow passage before the bending; Start position)
P9 The first end of the curved surface shape of the first curved surface of the inner surface in the upper region of the pre-bending passage, the start position of the tapered surface P10 The curved shape of the second curved surface of the second surface in the upper region of the unbending passage 2) The first end of the curved surface shape of the first curved surface of the inner surface in the upper region of the flow passage before bending P12 The second end of the curved shape of the second curved surface of the second curved surface in the upper region of the flow passage before bending P11 Start position)
P13 The first end of the curved surface shape of the first curved surface of the inner surface in the upper region of the flow channel before bending, the start position of the tapered surface P14 The curved surface of the second curved surface of the outer surface in the upper region of the flow channel before bending 2Start point P15 Curved second end of the second curved surface of the outer surface in the upper region of the pre-bending flow path P16 End position of tapered surface (guide end position)
P17 End position of tapered surface (guide end position)
P18 End position of tapered surface (guide end position)
P104 The first start of the curved surface of the first curved surface of the inner surface in the upper region of the flow path before bending (guide start position)
P105 The first end of the curved surface of the first curved surface of the inner surface in the upper region of the flow path before bending (guide end position)
P108 The first start of the curved surface of the first curved surface of the inner surface in the upper region of the flow path before bending (guide start position)
P109 The first end of the curved surface of the first curved surface of the inner surface in the upper region of the flow path before bending (guide end position)
P112 First start of curved surface of first curved surface of inner surface in upper region of flow path before bending (guide start position)
P113 The first end of the curved surface of the first curved surface of the inner surface in the upper region of the flow path before bending (guide end position)
R bowl right side area S1 outer rim water channel flow cross section S2 flow channel cross section at the upstream end of the flex rim water conduit S3 flow path cross section of the downstream end of the flex rim water channel S4 flexed rim water channel folded boundary cross section S5 inner rim Channel cross section S6 of the water channel Water channel cross section T1 first tangent plane T2 second tangent plane T3 third tangent plane T4 fourth tangent plane T5 first tangent plane T6 second tangent plane T7 Third tangent plane T8 fourth tangent plane T9 first tangent plane T10 second tangent plane T11 third tangent plane T12 fourth tangent plane T13 taper surface T14 taper surface T15 taper surface T101 first tangent plane T102 second tangent plane T105 fourth 1 Tangent plane T106 Second tangent plane T109 First tangent plane T110 Second tangent plane U Region of curved shape of rim water conduit V1 Volume of expanded channel V101 of enlarged channel Volume X A horizontally extending central axis Y which bisects the bowl in the front-back direction A central axis extending longitudinally in the horizontal direction which bisects the bowl Z A central axis in the vertical direction passing through the center of the bowl α taper angle of the guide surface β taper angle of guide surface γ taper angle of guide surface θ1 first intersection angle in plan view where the first tangent plane and the second tangent plane intersect with each other θ2 a plane where the first tangent plane and the second tangent plane intersect with each other First intersection angle of view θ3 First intersection angle of plane view where first tangent plane and second tangent plane intersect with each other θ101 first intersection angle of plane view where first tangent plane and second tangent plane intersect with each other θ102 first intersection angle in plan view where the first tangent plane and the second tangent plane intersect with each other θ103 first intersection angle in plan view where the first tangent plane and the second tangent plane intersect each other ρ1 Minimum curvature half of plane view of outer side Diameter 2 2 Minimum curvature radius of the inner side surface of the flow path before bending in plan view 3 3 Minimum radius of curvature of the inner side surface in the upper side area of the flow path before bending 4 Flat shape of the outer surface in the upper area of the flow path before bending Minimum curvature radius 55 Minimum curvature radius in plan view of inner surface in upper region of channel before bending 66 Minimum curvature radius in plan view of outer surface in upper region of channel before bending 77 Inner surface in upper region of channel before bending Minimum radius of curvature 88 in plan view Minimum radius of curvature in plan view of outer surface in upper region of channel before bending 屈曲 9 Minimum radius of curvature in plan of outer surface in channel after bending 1010 Plane of inner surface in channel after bending Minimum curvature radius of view 101101 Minimum curvature radius of the guide surface of the inner surface of the channel before bending in plan view 102102 Minimum radius of curvature of the guide surface of the inner surface of the channel before bending ρ103 内 103 Inner surface of the channel before bending Guy Minimum radius of curvature of the plane in plan view φ1 Second intersecting angle in plan view where the third tangent plane and the fourth tangent plane intersect with each other φ2 Second plan view in which the third tangent plane and the fourth tangent plane intersect each other Crossing angle φ 3 Second crossing angle in plan view where the third tangent plane and the fourth tangent plane intersect with each other

Claims (7)

洗浄水源から供給される洗浄水によって洗浄されて汚物を排出する水洗大便器であって、
上縁に形成されるリムと、汚物を受ける汚物受け面と、この汚物受け面と上記リムとの間に形成される棚と、を備えたボウルと、
このボウルの下方に接続され汚物を排出する排水路と、
上記リムに設けられて上記棚に洗浄水を吐水して旋回流を形成するリム吐水部と、
上記洗浄水源から供給される洗浄水を上記リム吐水部に供給する導水路と、を有し、
上記ボウルは、その前後方向に二等分する左右方向に延びる中心軸線に対して前方側である前方側領域と後方側である後方側領域と、を備え、
上記リム吐水部は、上記ボウルの前方側領域の左右の何れか一方の側の上記リムに上記導水路から供給された洗浄水が通水するリム導水路と、このリム導水路の下流端に設けられて洗浄水を後方に向けて吐水するリム吐水口と、を備え、
上記リム導水路は、その入口から上記リムの内部を前方に向かって延びる外側リム導水路と、この外側リム導水路の下流側に形成されて内側に屈曲する屈曲リム導水路と、この屈曲リム導水路の下流側に形成されて後方に向かって上記リム吐水口まで延びる内側リム導水路と、を備えており、
上記屈曲リム導水路は、その下方領域内の内側面の前方側先端部を含み且つ上記下方領域内の外側面に対して直交する流路断面であって、この流路断面を境界として流路方向が折り返される折り返し境界断面と、この折り返し境界断面の上流側に形成される屈曲前流路と、上記折り返し境界断面の下流側に形成される屈曲後流路と、を備え、上記屈曲前流路は、下側領域と、この下側領域の上方に形成されて上記下側領域の流路断面よりも縦長の流路断面を備えた上側領域と、を備え、
上記屈曲前流路の上側領域内の少なくとも一部の水平断面において、
上記屈曲前流路の内側面は、その平面視の曲率半径が最小となる曲面を含む第１曲面と、この第１曲面の曲面形状が開始する第１始端と、上記第１曲面の曲面形状が終了する第１終端と、上記第１始端に接する第１接平面と、上記第１終端に接する第２接平面と、を備え、
上記屈曲前流路の外側面は、その平面視の曲率半径が最小となる曲面を含む第２曲面と、この第２曲面の曲面形状が開始する第２始端と、上記第１曲面の曲面形状が終了する第２終端と、上記第２始端に接する第３接平面と、上記第２終端に接する第４接平面と、を備え、
上記第１接平面と上記第２接平面とが互いに交差する平面視の第１交差角度は、上記第３接平面と上記第４接平面とが互いに交差する平面視の第２交差角度よりも大きいことを特徴とする水洗大便器。 It is a flush toilet bowl that is cleaned by a flush water supplied from a flush water source to discharge dirt.
A bowl having a rim formed on the upper edge, a filth receiving surface for receiving filth, and a shelf formed between the filth receiving surface and the rim;
A drainage connected to the lower side of this bowl to discharge dirt,
A rim spouter provided on the rim to spout the washing water to the shelf to form a swirling flow;
And a water conduit for supplying wash water supplied from the wash water source to the rim water discharger,
The bowl includes a front side area that is a front side and a rear side area that is a rear side with respect to a central axis extending in the left-right direction that is bisected in the front-rear direction;
The rim water spouting section is a rim water channel through which washing water supplied from the water channel flows to the rim on either side of the front side area of the bowl, and a downstream end of the rim water channel And a rim spout which is provided to spout the washing water rearward,
The rim channel is an outer rim channel extending forward from the inlet to the inside of the rim, a bent rim channel formed on the downstream side of the outer rim channel and bent inward, and the bent rim An inner rim channel formed downstream of the channel and extending rearward to the rim spout;
The bent rim water conduit is a flow passage cross section including the front end of the inner surface in the lower region and orthogonal to the outer surface in the lower region, the flow passage being bordered by the flow passage cross section A bending boundary section whose direction is turned back, a pre-bending flow channel formed on the upstream side of the turning boundary cross section, and a post-bending flow channel formed on the downstream side of the turning boundary cross section; The passage comprises a lower region and an upper region formed above the lower region and having a flow passage cross section longer than the flow passage cross section of the lower region,
In at least a part of the horizontal cross section in the upper region of the pre-bending flow channel,
The inner surface of the flow path before the bending has a first curved surface including a curved surface with a minimum curvature radius in plan view, a first starting end where the curved surface shape of the first curved surface starts, and a curved surface shape of the first curved surface And a first tangential plane contacting the first starting end, and a second tangential plane contacting the first termination.
The outer surface of the pre-bending flow channel is a second curved surface including a curved surface whose curvature radius in plan view is minimum, a second starting end where the curved surface shape of the second curved surface starts, and a curved surface shape of the first curved surface And a third tangential plane in contact with the second start end, and a fourth tangential plane in contact with the second termination,
The first intersection angle in plan view where the first tangent plane and the second tangent plane intersect with each other is higher than the second intersection angle in plan view where the third tangent plane and the fourth tangent plane intersect each other A flush toilet characterized by its large size. 上記平面視の第１交差角度は、上記屈曲前流路が下方から上方に向かう程大きくなる請求項１記載の水洗大便器。   2. The flush toilet according to claim 1, wherein the first intersecting angle in the plan view becomes larger as the flow path before bending goes upward from below. 上記屈曲前流路の上側領域内の内側面は、上記屈曲前流路の上流端よりも下流側のガイド始端位置からその下流側のガイド終端位置まで洗浄水をガイドするガイド面を備えており、このガイド面は、上記第１曲面を含む請求項１又は２に記載の水洗大便器。   The inner surface in the upper region of the pre-bending flow channel has a guide surface for guiding the washing water from the guide start position on the downstream side of the upstream end of the pre-bending flow channel to the guide end position on the downstream side thereof. The flush toilet according to claim 1, wherein the guide surface includes the first curved surface. 上記ガイド面は、上記第１始端が上記ガイド始端位置となる上記第１曲面と、この第１曲面の第１終端からその下流側の上記ガイド終端位置まで平面視でテーパ状に形成されているテーパ面と、を備えている請求項３記載の水洗大便器。   The guide surface is formed in a tapered shape in plan view from the first curved surface where the first starting end is the guide starting position and the first end of the first curved surface to the guide terminating position downstream thereof The flush toilet according to claim 3, further comprising: a tapered surface. 上記テーパ面の平面視における上記第１曲面の第１終端から上記ガイド終端位置までの距離は、上記テーパ面が下方から上方に位置する程小さくなる請求項４記載の水洗大便器。   The flush toilet according to claim 4, wherein the distance from the first end of the first curved surface to the guide end position in a plan view of the tapered surface is smaller as the tapered surface is positioned from the lower side to the upper side. 上記ガイド面は、平面視において上記ガイド始端位置に位置する上記第１始端から上記ガイド終端位置に位置する上記第１終端まで洗浄水をガイドする湾曲状の曲面を形成している上記第１曲面である請求項３記載の水洗大便器。   The guide surface forms a curved curved surface for guiding washing water from the first start end located at the guide start end position to the first end end located at the guide end position in plan view. The flush toilet according to claim 3, which is 上記平面視の第１交差角度は、上記ガイド面が下方から上方に位置する程大きくなる請求項６記載の水洗大便器。   The flush toilet according to claim 6, wherein the first intersection angle in the plan view becomes larger as the guide surface is positioned from the lower side to the upper side.

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