The present application claims priority to and incorporates by reference the entire contents of Japanese Patent Application No. 2020-034299 filed in Japan on Feb. 28, 2020.
An embodiment of the disclosure relates to a flush toilet.
Conventionally, there has been known a flush toilet that spouts flush water from its water spout port so as to supply the flush water to a bowl part (see, Japanese Laid-open Patent Publication No. 2010-031551, for example). In the above-mentioned flush toilet, flush water spouted from the water spout port is divided into two main flows of a swirling flow that swirls around the bowl part and a fall flow that flows toward a water retaining part arranged at an under part of the bowl part, so as to discharge waste by using the above-mentioned swirling flow and fall flow.
However, in the conventional technology, a water spout port is formed in flat-shaped and/or a bottom surface of the water spout port is formed to slope downward toward the water retaining part, so as to form the fall flow. Thus, in the conventional technology, a user may easily visually recognize the water spout port that is formed in flat-shaped, for example, so that there presents possibility of deterioration in design.
A flush toilet according to one aspect of an embodiment includes: a main water guide channel through which flush water supplied from a water supply source flows; a downstream-side water guide channel on a downstream side of the main water guide channel that spouts the flush water from a water spout port of the downstream-side water guide channel; and a convex part formed in the downstream-side water guide channel, wherein the convex part includes: a first guide part that guides upward the flush water flowing through the downstream-side water guide channel; and a second guide part on a downstream side of the first guide part which guides downward the flush water.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
Hereinafter, an embodiment of a flush toilet as disclosed in the present application will be described in detail with reference to the accompanying drawings. Additionally, this invention is not limited by an embodiment as illustrated below. Furthermore, the drawings are schematic, so that it has to be noted that a dimensional relationship between respective elements, a ratio between respective elements, or the like may be different from a real one. Among drawings, a part with a mutually different dimensional relationship or ratio may also be included therein.
Overall Configuration of Flush Toilet
An overall configuration of a flush toilet 1 according to an embodiment will be explained with reference to
In
The flush toilet 1 according to the embodiment is a flush toilet that is mounted on the wall surface 8, i.e. a wall-mounted-type flush toilet. Note that the flush toilet 1 may be a flush toilet that is placed on the floor surface 9, i.e. a floor-mounted-type flush toilet.
The flush toilet 1 includes a toilet body 2 and a private part washing device 3. The flush toilet 1 according to the embodiment is a flush-type toilet (wash-down-type toilet) that washes the toilet body 2 by using flush water supplied from a flush-water supply source so as to discharge waste. Note that the flush toilet 1 may be a siphon-type toilet. The toilet body 2 is made of ceramics, for example. Details of the toilet body 2 will be mentioned later.
The private part washing device 3 includes a washing nozzle, a motor for driving the nozzle, and a motor controller (that are not illustrated). The private part washing device 3 is provided, in order to wash a private part of a user, in an upper part of the toilet body 2 so as to wash a private part of a user by using washing water discharged from the washing nozzle.
In the flush toilet 1, flush water is supplied to the toilet body 2 via a water supplying pipe 4a connected with a water storage tank 4 (one example of water supply source). The flush toilet 1 discharges, to a drainage water pipe 5, waste along with flush water. The water storage tank 4 may be arranged behind the toilet body 2 so as to directly supply therefrom flush water to the toilet body 2.
The flush toilet 1 includes a water supply hose 6a that supplies washing water for washing a private part to the private part washing device 3 and a power source cable 6b that supplies electric power to the private part washing device 3.
Toilet Body
Next, the toilet body 2 according to the embodiment will be explained with reference to
As illustrated in
The bowl part 10 is formed in bowl-shaped to receive waste. The rim part 11 is arranged at an upper edge of the bowl part 10. The rim part 11 is formed to overhang the inside of the bowl part 10 so that flush water does not splash to the outside.
As illustrated in
The main water guide part 20 is connected to the water supplying pipe 4a (see
The common water guide part 21 is arranged on a downstream side of the main water guide part 20, and flush water flows into the common water guide part 21 from the main water guide channel 20a. Specifically, a common water guide channel 21a is formed in the common water guide part 21, and flush water supplied from the main water guide channel 20a flows into the common water guide channel 21a. Note that a protruding part 40 is formed in the common water guide part 21, which will be mentioned later.
As illustrated in
The first water guide channel 30a is formed from a rear portion toward a left portion of the bowl part 10 along the rim part 11. The above-mentioned first water spout port 31a is formed in an end part on a downstream side of the first water guide channel 30a. For example, the first water spout port 31a is arranged in the vicinity of the center of the left portion of the rim part 11.
Therefore, flush water flowing from the main water guide channel 20a into the first water guide channel 30a via the common water guide channel 21a flows counterclockwise in the top view, and then spouts from the first water spout port 31a into the bowl part 10. In other words, the first water guide channel 30a spouts the supplied flush water from the first water spout port 31a.
The second water guide channel 30b is formed along the rim part 11 in a rear part of the bowl part 10. The second water guide channel 30b includes a bending site 30b1 that bends a flowing direction of flush water in the middle of its flow path. Specifically, the bending site 30b1 of the second water guide channel 30b bends a flowing direction of flush water flowing toward the front of the bowl part 10, more specifically, causes the flush water to make a U-turn, so as to guide it to the rear of the bowl part 10. The above-mentioned second water spout port 31b is formed in an end part on a downstream side of the second water guide channel 30b. The second water spout port 31b is arranged at the right rear of the rim part 11, for example.
Therefore, flush water having flowed from the main water guide channel 20a to the common water guide channel 21a via the second water guide channel 30b flows clockwise in the top view, and then a flowing direction thereof is inverted in the bending site 30b1 so as to flow counterclockwise. Next, the flush water is spouted counterclockwise from the second water spout port 31b to the bowl part 10. In other words, the second water guide channel 30b spouts supplied flush water from the second water spout port 31b.
As described above, the downstream-side water guide channels 30 are arranged on a downstream side of the main water guide channel 20a and the common water guide channel 21a so as to spout flush water from the water spout ports 31. The number of the downstream-side water guide channels 30 and the water spout ports 31 is not limited to the above mentioned. In other words, for example, the number of the downstream-side water guide channels 30 and the water spout ports 31 may be one or equal to or more than three. The common water guide channel 21a is arranged between the first water guide channel 30a and the second water guide channel 30b so as to supply flush water having flowed from the main water guide channel 20a to the first water guide channel 30a and the second water guide channel 30b. In other words, in the common water guide part 21, the common water guide channel 21a branches into the first water guide channel 30a and the second water guide channel 30b. Thus, the common water guide part 21 may be referred to as a branching site.
Flush water spouted from the first water spout port 31a and the second water spout port 31b is divided into swirling flows Da1 and Db1 and fall flows Da2 and Db2 in the bowl part 10, this point will be mentioned later.
Flush water spouted from the first and second water spout ports 31a and 31b washes the bowl part 10 discharges waste from the drainage water pipe 5 (see
As illustrated in
Herein, the protruding part 40 formed in the common water guide part 21 will be explained. As illustrated in
The top part 41 is formed in planar-shaped. The inclined part 42 is formed so as to connect the top part 41 and the bottom surface 21b with each other. The inclined part 42 is formed of slopes falling from the top part 41 in the left-right direction and the forward direction.
Thus, a part of flush water having flowed into the common water guide channel 21a collides with the protruding part 40 so as to flow into the first water guide channel 30a and the second water guide channel 30b. Specifically, the protruding part 40 protrude upward from the bottom surface 21b of the common water guide part 21 so as to smoothly change a flowing direction of flush water that is flowing on a side of the bottom surface 21b caused by the gravity, and thus the flush water flows into the first water guide channel 30a and the second water guide channel 30b. Thus, when dividing flush water into the first and second water guide channels 30a and 30b, the flush toilet 1 is capable of smoothly guiding the flush water into the first and second water guide channels 30a and 30b.
Incidentally, as described above, when flush water spouted from the first and second water spout ports 31a and 31b is divided into the swirling flows Da1 and Db1 and the fall flows Da2 and Db2, the flush toilet 1 is capable of efficiently discharging a waste therein.
Specifically, the swirling flows Da1 and Db1 swirl on an outer peripheral side of the bowl part 10, and is capable of efficiently guide a waste adhering to a waste receiving surface 10a of the bowl part 10 and the like toward the water retaining part 13. The fall flows Da2 and Db2 push, into the discharge path 14a of the discharge part 14, a floating waste floating on a retaining water in the water retaining part 13 and the like, so that it is possible to efficiently discharge a floating waste and the like.
Incidentally, in a conventional technology, in order to form fall flow, a water spout port is formed in flat-shaped, or a bottom surface of a water spout port is formed to slope down toward a water retaining part, for example. However, such a flat-shaped water spout port is easily and visually recognized by a user, so that there presents possibility of deterioration in design.
Thus, the flush toilet 1 according to the present embodiment is configured to form a flow flowing toward the water retaining part 13 regardless of shapes of the first and second water spout ports 31a and 31b.
Hereinafter, details of the configuration will be explained, as illustrated in
Hereinafter, the convex part 50 formed in the first water guide channel 30a may be referred to as “first convex part 51” and the convex part 50 formed in the second water guide channel 30b may be referred to as “second convex part 52”, and they may be collectively referred to as “convex parts 50” when explanation is performed without distinction.
For example, the first convex part 51 is formed from a periphery of an upstream-side portion of the first water guide channel 30a to the first water spout port 31a arranged in a downstream-side portion of the first water guide channel 30a. In other words, the first convex part 51 is formed over whole or substantially whole of the first water guide channel 30a along a flowing direction of flush water.
The above-mentioned region of the first water guide channel 30a in which the first convex part 51 is formed is merely one example, and not limited thereto. In other words, for example, the first convex part 51 may be partially formed in a region on a downstream side of the first water guide channel 30a, or may be partially formed in a region on an upstream side of the first water guide channel 30a.
For example, the second convex part 52 is formed from a periphery of an upstream-side portion of the second water guide channel 30b up to the bending site 30b1. Specifically, the second convex part 52 is formed from a periphery of an upstream-side portion of the second water guide channel 30b up to a position on an upstream side of a part of the bending site 30b1 in which a flowing direction of flush water is bent.
The above-mentioned region of the second water guide channel 30b in which the second convex part 52 is formed is merely one example, and not limited thereto. In other words, for example, the second convex part 52 may be partially formed in a region on a downstream side from the bending site 30b1 of the second water guide channel 30b, or may be formed over whole or substantially whole of the second water guide channel 30b.
The first convex part 51 includes a first guide part 51a, a straightening part 51b, and a second guide part 51c. Similarly, the second convex part 52 includes a first guide part 52a, a straightening part 52b, and a second guide part 52c.
Hereinafter, the first convex part 51 will be specifically explained; note that a configuration of the first convex part 51 and that of the second convex part 52 are similar to each other, and thus the following explanation of the first convex part 51 may be basically applied to the second convex part 52.
Specifically, the above-mentioned first guide part 51a of the first convex part 51 erects upward from the bottom surface 30a1 of the first water guide channel 30a. In other words, the first guide part 51a is a wall part that erects from the bottom surface 30a1 of the first water guide channel 30a. Specifically, the first guide part 51a includes a slope 51a1 so as to guide upward, along the slope 51a1, flush water flowing through the first water guide channel 30a.
The second guide part 51c is arranged on a downstream side of the first guide part 51a. The second guide part 51c also erects upward from the bottom surface 30a1 of the first water guide channel 30a. In other words, the second guide part 51c is a wall part that erects from the bottom surface 30a1 of the first water guide channel 30a. The second guide part 51c includes a slope 51c1 so as to guide downward, along the slope 51c1, flush water flowing through the first water guide channel 30a.
As described above, in the present embodiment, the first water guide channel 30a is configured to therein raise flush water by using the first guide part 51a and then fall the raised flush water by using the second guide part 51c, so that a pressure loss is generated in the flush water caused by the raise and the fall. When such a pressure loss is generated, flush water easily disperses when being spouted from the first water spout port 31a of the first water guide channel 30a, so as to form, in the bowl part 10, the fall flow Da2 (see
In the first water guide channel 30a, the first convex part 51 is arranged in a periphery of the first water spout port 31a, and thus flush water having fallen in the second guide part 51c is generated at a position near the first water spout port 31a. Thus, flush water more easily disperses when being spouted from the first water spout port 31a, so that it is possible to reliably generate the fall flow Da2.
The first convex part 51 will be explained more specifically. As described above, the first guide part 51a erects upward from the bottom surface 30a1 of the first water guide channel 30a. Thus, as indicated by using an arrow A1, a part of flush water flowing from the common water guide channel 21a collides with the first guide part 51a to be guided upward (see arrow A2). Specifically, a part of flush water collides with the slope 51a1 to be guided upward along the slope 51a1.
In this case, most of flush water guided upward by the first guide part 51a collides with a top surface 30a2 of the first water guide channel 30a. In other words, the first guide part 51a is configured to guide upward flush water to form rise flow flowing toward the top surface 30a2 of the first water guide channel 30a.
As described above, in the present embodiment, a pressure loss is generated in flush water by its collision with the first guide part 51a, and thus the flush water disperses when being spouted from the first water spout port 31a, so that the fall flow Da2 is easily formed. Moreover, the first guide part 51a generates rise flow flowing toward the top surface 30a2 so as to reliably form fall flow generated by collision with the top surface 30a2, which will be mentioned later.
As described above, when the rise flow collides with the top surface 30a2, fall flow flowing downward is generated, which is indicated by an arrow A3. The second guide part 51c is provided at a position where the above-mentioned fall flow is generated. The slope 51c1 of the second guide part 51c slopes down to be along the fall flow that is generated when rise flow having collided with the top surface 30a2 falls.
Thus, fall flow falling from the top surface 30a2 easily collides with the bottom surface 30a1 of the first water guide channel 30a, so that it is possible to easily generate a pressure loss in the flush water. The flush water in which the pressure loss is generated easily disperses when being spouted from the first water spout port 31a, and thus the fall flow Da2 is easily formed.
The straightening part 51b is arranged between the first guide part 51a and the second guide part 51c. The straightening part 51b straightens flush water flowing on an upper surface 51b1 so as to form straight flow (see arrow A4).
The straight flow formed in the straightening part 51b is to join with fall flow that is falling down from the top surface 30a2. Thus, it is possible to direct the above-mentioned fall flow toward the first water spout port 31a. Thus, it is possible to cause a large amount of fall flow to collide with the bottom surface 30a1 on a side of the first water spout port 31a so as to generate therein a pressure loss, and thus it is further possible to generate a flow flowing toward the water retaining part 13 just after flush water is spouted from the first water spout port 31a, in other words, the fall flow Da2.
For example, if the first convex part 51 is not provided with the straightening part 51b, flush water having gotten over the first convex part 51 becomes flow flowing along a wall surface so as to form turbulent flow, and thus formation of the desired fall flow Da2 is difficult.
Next, a size of the first convex part 51 will be explained. In the first convex part 51, the straightening part 51b is formed such that a length D of the straightening part 51b in a flowing direction of flush water is larger than a height H of the straightening part 51b (namely, D>H).
For example, if the height H of the straightening part 51b is too large, there presents possibility that turbulent flow is generated on an upstream side of the straightening part 51b; however, when the height H is set as described above, flush water is raised by the first guide part 51a and then sufficiently straightened by the straightening part 51b, so that it is possible to reliably generate fall flow in the first water guide channel 30a.
The straightening part 51b is configured such that the length D in a flowing direction of flush water is larger than a distance W from the upper surface 51b1 of the straightening part 51b to the top surface 30a2 of the first water guide channel 30a (namely, D>W).
As described above, in the straightening part 51b, the length D in a flowing direction of flush water is longer than the distance W up to the top surface 30a2, and thus fall flow in the first water guide channel 30a easily reaches the straightening part 51b or the slope 51c1, moreover, it is possible to prevent occurrence of turbulent flow.
For example, a slope angle of the slope 51a1 in the first guide part 51a is set to larger than a slope angle of a slope 52c1 in the second guide part 51c. In other words, the slope 51a1 is configured such that a slope thereof is steeper than that of the slope 52c1. Thus, a part of flush water easily collides with the slope 51a1 so as to generate a pressure loss in the flush water, and thus the flush water disperses when being spouted from the first water spout port 31a so as to facilitate formation of the fall flow Da2.
In the above description, the case has been exemplified in which a slope angle of the slope 51a1 is set to larger than a slope angle of the slope 52c1; however, this is merely one example and not limited thereto, for example, a slope angle of the slope 51a1 may be set to equal to a slope angle of the slope 52c1, or may be set to smaller than a slope angle of the slope 52c1.
As illustrated in
Thus, fall flow is able to be generated in each of the first water guide channel 30a and the second water guide channel 30b, so that it is possible to reliably generate the fall flows Da2 and Db2 flowing toward the water retaining part 13.
Note that the first convex part 51 and the second convex part 52 are formed such that shapes thereof are different from each other, not limited thereto, may be formed such that shapes thereof are the same to each other. In other words, between the first convex part 51 and the second convex part 52, for example, any of slope angles of the first guide parts 51a and 52a, slope angles of the second guide part 51c and 52c, the lengths D, the heights H, and the distances W up to the top surface 30a2 of the straightening parts 51b and 52b, etc. may be set to different values, or may be set to the same value.
Next, relation between heights of the convex part 50 and the common water guide channel 21a will be explained with reference to
In accordance therewith, there remains remaining water B in a downstream-side portion of the common water guide channel 21a. Therefore, flush water having flowed from the main water guide channel 20a (see
As described above, the flush toilet 1 according to the embodiment includes the main water guide channel 20a, the downstream-side water guide channel 30, and the convex part 50. Through the main water guide channel 20a, flush water supplied from a water supply source flows. The downstream-side water guide channel 30 on a downstream side of the main water guide channel 20a spouts the flush water from the water spout port 31. The convex part 50 is formed in the downstream-side water guide channel 30. The convex part 50 includes the first guide part 51a or 52a that guides upward the flush water flowing through the downstream-side water guide channel 30, and the second guide part 51c or 52c on a downstream side of the first guide part 51a or 52a which guides downward the flush water. Thus, it is possible to generate, regardless of a shape the water spout port 31, the fall flows Da2 or Db2 that flows toward the water retaining part 13.
Thus, in the downstream-side water guide channel, flush water is raised by the first guide part and then is fallen by the second guide part, and thus a pressure loss is generated in the flush water by the rise and the fall. When such a pressure loss is generated, flush water easily disperses when being spouted from a water spout port of the downstream-side water guide channel, so that fall flow flowing toward a water retaining part is formed in a bowl part. In other words, it is possible to generate fall flow regardless of a shape of the water spout port.
The first guide part is formed such that the first guide part guides upward the flush water to generate rise flow flowing toward a top surface of the downstream-side water guide channel.
As described above, in the first guide part, rise flow flowing toward the top surface is generated, so that it is possible to reliably generate fall flow that is caused by collision with the top surface.
The second guide part includes a slope that slopes down to be along fall flow that is generated when the rise flow having collided with the top surface falls.
Thus, fall flow falling down from the top surface easily collides with a bottom surface of the downstream-side water guide channel, so that it is possible to generate a pressure loss in the flush water. The flush water in which the pressure loss is generated easily disperses when being spouted from the water spout port, so that it is possible to easily generate fall flow that flows toward a water retaining part.
The convex part includes a straightening part between the first guide part and the second guide part. The straightening part straightens the flush water flowing on an upper surface of the straightening part to form straight flow.
As described above, straight flow formed in the straightening part joins with fall flow falling from the top surface. Thus, it is possible to direct the above-mentioned fall flow toward the water spout port. Thus, it is possible to cause a large amount of fall flow to collide with a bottom surface of the downstream-side water guide channel on a side of the water spout port so as to generate therein a pressure loss, and thus it is further possible to generate a flow toward the water retaining part just after flush water is spouted from the water spout port, in other words, the fall flow.
The straightening part is formed such that a length of the straightening part in a flowing direction of the flush water is larger than a height of the straightening part.
Thus, fall flow in the downstream-side water guide channel is able to be reliably generated. In other words, if the height of the straightening part is too large, there presents possibility that turbulent flow is generated on an upstream side of the straightening part; however, when the height is set as described above, flush water is sufficiently straightened by the straightening part after being raised by the first guide part, so that it is possible to reliably generate fall flow in the first water guide channel.
The straightening part is formed such that a length of the straightening part in a flowing direction of the flush water is larger than a distance from the upper surface of the straightening part to a top surface of the downstream-side water guide channel.
Therefore, in the straightening part, a length in a flowing direction of flush water is larger than a distance up to the top surface, and thus fall flow in the downstream-side water guide channel easily reaches the straightening part or the slope, moreover, it is possible to prevent occurrence of turbulent flow.
The downstream-side water guide channel includes: a first water guide channel that spouts the flush water from a first water spout port of the first water guide channel; and a second water guide channel that spouts the flush water from a second water spout port of the second water guide channel, and the convex part is formed in each of the first water guide channel and the second water guide channel.
Thus, fall flow is able to be generated in each of the first water guide channel and the second water guide channel, so that it is possible to reliably generate fall flow flowing toward a water retaining part.
The flush toilet further includes: a common water guide channel between the first water guide channel and the second water guide channel, the common water guide channel supplying the flush water from the main water guide channel to the first water guide channel and the second water guide channel, wherein the common water guide channel is formed such that a bottom surface of the common water guide channel is lower than an upper surface of the convex part of each of the first water guide channel and the second water guide channel.
In accordance therewith, there remains remaining water in a downstream-side portion of the common water guide channel. Therefore, flush water having flowed from the main water guide channel collides with a puddle of the remaining water. Thus, a pressure loss is generated in flush water, and the flush water in which the pressure loss is generated easily disperses when being spouted from the first water spout port, so that it is possible to easily generate, in a bowl part, the fall flow flowing toward the water retaining part.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Number | Date | Country | Kind |
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2020-034299 | Feb 2020 | JP | national |