JP7300085B2 - Drainage device - Google Patents

Description

TECHNICAL FIELD The present invention relates to a drainage device, and more particularly to a drainage device provided at the bottom of a water receiving portion for receiving water.

2. Description of the Related Art Conventionally, as shown in Patent Literature 1, a drainage device is known in which an ultrasonic transmitter is provided in a pipe between a bowl portion and an elbow pipe.

Also, as shown in Patent Document 2, a drainage device is known that is provided on the bottom surface of a sink and has an ultrasonic transmitter. In this drainage device, when the user wants to clean the drainage section of the drainage device, the user turns on the switch of the operation section. When the operation unit is turned on, the drain valve of the drain unit is closed and the water supply valve is opened to supply water into the drain unit. Ultrasonic cleaning is performed in a state in which water is stored up to the inlet in the drain, and dirt in the drain is cleaned.

U.S. Pat. No. 4,893,361 Japanese Patent Application Laid-Open No. 2004-324108

However, in the drainage device as shown in Patent Document 1, the water level of the pipe between the bowl portion and the elbow pipe is basically kept at the seal water level, so dirt adheres to the inner wall surface near the seal water level. Cheap. In such a drainage device, since the part to which the dirt adheres is not submerged in water during normal ultrasonic cleaning, there is a problem that the part to which the dirt adheres cannot be sufficiently subjected to ultrasonic cleaning. rice field.

On the other hand, as shown in Patent Document 2, when ultrasonic cleaning is performed in a state in which water is stored up to the inlet portion in the drainage portion above the sealing water level, if further water is supplied into the sink, Since the water overflows from the drain into the sink, the water cannot be drained during ultrasonic cleaning, and the drain device is inconvenient to use.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-described problems of the prior art. To provide a drainage device capable of facilitating raising to a higher ultrasonic cleaning water level and suppressing water in a main body from exceeding the ultrasonic cleaning water level and overflowing into a water receiving part.

In order to solve the above-described problems, the present invention provides a drainage device provided at the bottom of a water receiving portion for receiving water, wherein a main body portion provided downstream of the water receiving portion is provided to seal water. The main body having a sealing water forming portion forming a trap-shaped flow path, an ultrasonic oscillator for oscillating ultrasonic waves to the water in the main body, and the water flowing into the main body, the above A flow rate adjusting unit formed so that the water level in the main body can easily rise from the sealing water level in the sealing water forming part to the ultrasonic cleaning water level higher than the sealing water level in the sealing water forming part, The flow rate adjusting unit adjusts the amount of water discharged downstream per unit time until the water level in the main body reaches the ultrasonic cleaning water level from the sealing water level. It is characterized by comprising the above-described flow rate adjusting portion formed so as to be less than the amount of water discharged per unit time to the downstream side in the reached state.
In the present invention configured as described above, the flow rate adjusting portion changes the water level in the main body portion from the sealing water level in the sealing water forming portion to the sealing water level in the sealing water forming portion by the water flowing into the main body portion. It is formed so that it can be easily raised to a higher ultrasonic cleaning water level. Further, the flow rate adjusting unit adjusts the amount of water discharged downstream per unit time until the water level in the main body reaches the ultrasonic cleaning water level from the sealing water level. is formed so as to be less than the amount of drainage per unit time to the downstream side in the state of reaching . As a result, the water level inside the main unit rises to the ultrasonic cleaning water level, making it easier to perform ultrasonic cleaning to an ultrasonic cleaning water level higher than the sealing water level, and the water level inside the main unit rises beyond the ultrasonic cleaning water level. It can be done easily. Therefore, water can flow to the main body even during ultrasonic cleaning. Therefore, according to the configuration as described above, the water level in the main body can be easily raised to the ultrasonic cleaning water level higher than the sealing water level in order to clean dirt in the vicinity of the sealing water level in the main body by ultrasonic cleaning. It is possible to suppress the water in the main body portion from exceeding the ultrasonic cleaning water level and overflowing into the water receiving portion.

In the present invention, preferably, the flow regulating portion has a wall that narrows the flow path in the sealing water forming portion.
In the present invention configured as described above, the water level in the main body is raised to the ultrasonic cleaning water level by the wall that narrows the flow path in the sealing water forming part, and ultrasonic cleaning is performed up to the ultrasonic cleaning water level higher than the sealing water level. The cleaning can be easily performed, and the water level inside the main body can be made difficult to rise beyond the ultrasonic cleaning water level. Therefore, according to the configuration as described above, the water level in the main body can be set to a higher ultrasonic cleaning water level than the sealing water level in order to clean dirt in the vicinity of the sealing water level in the main body by ultrasonic cleaning, using a relatively simple structure. In addition, it is possible to prevent the water in the main body from exceeding the ultrasonic cleaning water level and overflowing into the water receiving part.

In the present invention, preferably, the wall of the flow rate adjusting unit is formed so as to rise upward from the sealing water level regulating portion that defines the sealing water level, and in the lateral direction with respect to the main water flow direction. and the wall is formed with a notch extending downward from the top edge thereof.
In the present invention configured as described above, the wall of the flow rate adjusting section is formed so as to rise upward from the sealing water level regulating section that defines the sealing water level, and is opposed to the main water flow direction. Further, the wall has a notch extending downward from the upper end thereof. As a result, when the water level inside the main unit rises from the sealing water level to the ultrasonic cleaning water level, the continuity of the rate of change in water level rise is improved compared to the case where the notch is formed in the wall at a position spaced apart from the upper end of the wall. The water level can be raised at a relatively constant rate of change for a relatively constant inflow by suppressing damage (abrupt fluctuations in the rate of rise).

In the present invention, preferably, the width of the notch formed in the wall of the flow rate adjusting unit in the horizontal direction is substantially constant in the vertical direction.
In the present invention configured as described above, when the water level in the main body drops to the sealing water level, it is possible to suppress the decrease in the flow rate of the discharged water as the water level drops. Therefore, when the water level in the main body drops to the vicinity of the sealing water level, the dirt floating on the water surface can be discharged downstream from the notch, and the deterioration of the discharge performance of the dirt floating on the water surface can be suppressed. . Furthermore, since the notch in the wall is formed with a relatively simple structure, it is possible to suppress clogging caused by dirt adhering to the notch in the wall.
If the width of the notch in the left-right direction becomes narrower as it goes downward, although there is a certain effect in suppressing the rise in the water level and the overflow of water as described above, the water level decreased to the vicinity of the sealing water level. In some cases, as the water level drops, the flow rate of waste water decreases, and there is a risk that the discharge performance of dirt floating on the water surface will decrease.

In the present invention, preferably, the lateral width of the notch formed in the wall of the flow rate adjusting unit increases downward in the vertical direction.
In the present invention configured as described above, the lateral width of the notch formed in the wall of the flow rate adjusting portion increases downward in the vertical direction. This will
When the water level inside the main body drops to the sealing water level, it is possible to suppress the decrease in the flow rate of the discharged water as the water level drops. Therefore, when the water level in the main body drops to the vicinity of the sealing water level, the dirt floating on the water surface can be discharged downstream from the notch, and the deterioration of the discharge performance of the dirt floating on the water surface can be suppressed. .

In the present invention, preferably, the mesh basket is provided in the main body and has a mesh, and the flow rate adjusting unit is in a state in which the ultrasonic cleaning water level is arranged in the main body. It is formed so as to be positioned below the bottom of the mesh basket.
In the present invention configured as described above, the flow rate adjusting portion is formed so as to be positioned below the bottom portion of the mesh basket in which the ultrasonic cleaning water level is arranged in the main body portion. be. As a result, when the ultrasonic cleaning water level is located below the bottom of the mesh basket, the main body during ultrasonic cleaning is more effective than when the ultrasonic cleaning water level is located above the bottom of the mesh basket. The amount of water per unit time inside the unit decreases, and the sound pressure of the ultrasonic waves acting on the walls near the sealing water level, where dirt tends to remain, can be made relatively high, and the ultrasonic cleaning performance near the sealing water level can be improved. .

According to the drainage system of the present invention, the water level in the main body can be easily raised to an ultrasonic cleaning water level higher than the sealing water level in order to clean the dirt in the vicinity of the sealing water level in the main body by ultrasonic cleaning. It is possible to suppress the water from exceeding the ultrasonic cleaning water level and overflowing into the water receiving part.

1 is a front view of a drainage system provided with a drainage device according to a first embodiment of the present invention; FIG. 1 is a side view of a drainage system provided with a drainage device according to a first embodiment of the invention; FIG. 1 is an exploded perspective view showing a state in which a lid, a mesh basket, and an inner trap are disassembled from a drain main body, viewed obliquely from above the sink with the drain device according to the first embodiment of the present invention attached to the sink. FIG. 2 is a cross-sectional view taken along line IV-IV of FIG. 1; FIG. FIG. 2 is a cross-sectional view taken along line VV of FIG. 1; 1 is a block diagram schematically showing the structure of a drainage system with a drainage device according to a first embodiment of the present invention; FIG. FIG. 5 is a cross-sectional view taken along line VII-VII of FIG. 4; FIG. 4 is a partially enlarged cross-sectional view showing a standby state of the drainage body of the drainage device according to the first embodiment of the present invention; FIG. 4 is a partially enlarged cross-sectional view showing a state in which water starts to flow into the drainage body of the drainage device according to the first embodiment of the present invention; Water further flows into the drainage main body of the drainage device according to the first embodiment of the present invention, and the water that has flowed in flows out to the outlet flow path through the water level adjustment section. is a partially enlarged cross-sectional view showing a state in which the is raised. FIG. 4 is a partially enlarged cross-sectional view showing a state in which water further flows into the drainage main body of the drainage device according to the first embodiment of the present invention, and the water level in the drainage main body reaches the ultrasonic cleaning water level; FIG. 4 is a partially enlarged cross-sectional view showing a state in which water stops flowing into the drainage main body of the drainage device according to the first embodiment of the present invention and the water level in the drainage main body gradually decreases. FIG. 4 is a partially enlarged cross-sectional view showing a state in which the drainage device according to the first embodiment of the present invention returns to a standby state after a series of cleaning operations are completed; FIG. 8 is a cross-sectional view showing the water level adjusting portion of the drainage device of the first modified example according to the first embodiment of the present invention in a cross-sectional view at the same position as in FIG. 7; FIG. 8 is a cross-sectional view similar to FIG. 7 showing the water level adjusting portion of the drainage device of the second modified example according to the first embodiment of the present invention; FIG. 8 is a cross-sectional view similar to FIG. 7 showing the water level adjusting portion of the drainage device of the third modified example according to the first embodiment of the present invention; FIG. 8 is a cross-sectional view similar to FIG. 7 showing the water level adjusting portion of the drainage device of the fourth modified example according to the first embodiment of the present invention; FIG. 4 is a central cross-sectional view of a drainage device according to a second embodiment of the present invention; FIG. 19 is a cross-sectional view taken along line XIX-XIX in FIG. 18; FIG. 10 is a perspective view of a bathroom equipped with a drainage device according to a third embodiment and a drainage device according to a fourth embodiment of the present invention; 21 is a partially enlarged cross-sectional view of the vicinity of the floor surface of the bathroom as viewed along line XXI-XXI of FIG. 20; FIG. FIG. 22 is a partially enlarged cross-sectional view of the XXII portion of FIG. 21; FIG. 11 is a perspective view of a washbasin faucet device provided with a drainage device according to a fifth embodiment of the present invention; FIG. 25 is a partially enlarged cross-sectional view of the vicinity of the floor surface of the washbowl of the washbasin faucet device as viewed along line XXIV-XXIV in FIG. 24; 25 is a partially enlarged cross-sectional view of the XXV portion of FIG. 24; FIG.

Hereinafter, embodiments of the present invention disclosed in this specification will be described in detail with reference to the drawings. Many modifications and other embodiments of the invention will be apparent to those skilled in the art from the following description. Accordingly, the following description is to be construed as illustrative only and is provided for the purpose of teaching those skilled in the art the best mode of carrying out the invention. Substantial details of construction and/or function may be changed without departing from the spirit of the invention.

A drainage system having a drainage device according to a first embodiment of the present invention will now be described with reference to the accompanying drawings.
FIG. 1 is a front view of a drainage system equipped with a drainage device according to a first embodiment of the present invention, and FIG. 2 is a side view of a drainage system equipped with a drainage device according to the first embodiment of the present invention. is a side view.
As shown in FIGS. 1 and 2, a drainage system 2 equipped with a drainage device 1 according to the first embodiment of the present invention is installed in a kitchen to perform ultrasonic cleaning. The drainage system 2 is a system provided with a drainage device with an ultrasonic cleaning function. The drainage system 2 may be a system other than the kitchen system.

The drainage system 2 includes a sink 4 which is a water receiving part for receiving water provided in the kitchen 3; A drainage device 1 provided at the bottom of a sink 4 of a kitchen 3 and a drainage channel 8 provided downstream of the drainage device 1 are provided.

The sink 4 is formed to discharge water discharged from the kitchen faucet device 6 downstream. The kitchen faucet device 6 is connected on the upstream side to a water supply channel 9 to which water is supplied from a water supply source (not shown) and a hot water supply channel 11 to which hot water is supplied. The kitchen faucet device 6 includes a hot and cold water mixing faucet 6a, mixes water from the cold water supply channel 9 and hot water from the hot water supply channel 11, and discharges water from the water discharge part 6b. The water supply channel 9 and the hot water supply channel 11 once extend upward and are connected to the hot and cold water mixing valve 6a. It rises again and extends to 6b.

The drainage channel 8 is connected to the downstream end of the drainage device 1 and extends downward in the vertical direction. The drainage channel 8 is further connected to a downstream drainage pipe (not shown). A portion of the drainage channel 8 may be formed by the drainage body portion 10 .

Next, a drainage device according to a first embodiment of the present invention will be described with reference to FIGS. 3 to 6. FIG.
FIG. 3 is an exploded perspective view showing a state in which the lid, the mesh basket, and the inner trap are disassembled from the main body of the drain when the drain device according to the first embodiment of the present invention is attached to the sink, viewed obliquely from above the sink. 4 is a sectional view taken along line IV-IV of FIG. 1, FIG. 5 is a sectional view taken along line VV of FIG. 1, and FIG. 6 is a first embodiment of the present invention. 1 is a block diagram that schematically illustrates the structure of a drainage system with a drainage device according to one embodiment; FIG.

First, the drainage device 1 includes a drainage main body 10 which is a main body connected to the downstream end of the bottom 4a of the sink 4. As shown in FIG. A water supply channel other than the channel from the sink 4 may be connected to the drain main body 10 . Another water supply channel is connected to another water supply (not shown) or to the same water supply. The water flowing into the drainage body 10 includes water flowing into the drainage body 10 from a water supply channel other than the channel from the sink 4 . The water that flows into the drainage main body 10 also includes water containing any of detergent, shampoo, body soap, stains on tableware, stains on the water receiving portion, and the like, such as domestic wastewater.

The drain main body 10 is provided downstream of the sink 4, and includes a mesh basket storage portion 12 in which a mesh basket is stored, and a mesh basket storage portion 12 that is provided downstream of the mesh basket storage portion 12 and forms a water seal. and a water forming part 14 . The mesh basket housing portion 12 and the water seal forming portion 14 of the drainage body portion 10 are made of resin.
Hereinafter, in the description of the first embodiment of the present invention, the upstream side with respect to the main flow direction of water reaching the water level adjustment portion 26 is the front side, the side opposite to the upstream side is the rear side, and the water level adjustment portion 26 The right side is defined as the right side when viewed from the front, and the left side is defined as the left side when viewed from the front.

The mesh basket storage part 12 is formed in a size such that the mesh basket 18 can be arranged inside. The mesh basket housing portion 12 has a hollow shape in which the mesh basket 18 can be arranged. The mesh basket storage portion 12 includes an inlet portion 12a that opens toward the sink 4, an intermediate portion 12b that stores the mesh basket, and an outlet portion 12c that has a reduced flow path diameter from the intermediate portion toward the water seal forming portion 14. and

As shown in FIG. 5 , the entrance 12 a of the mesh basket housing portion 12 is opened in a rectangular shape and forms a drain port portion of the sink 4 . The inlet portion 12a is formed by partially recessing the bottom portion 4a further downward. The inlet portion 12 a has a flow path diameter larger than that of the water seal forming portion 14 . The inlet portion 12a forms an opening that is larger than or substantially the same size as the outer diameter of the mesh basket 18 so that the mesh basket 18 can be arranged up to the intermediate portion 12b. The inlet portion 12a may form a relatively large opening extending outward beyond the intermediate portion 12b. That is, the opening may be narrowed stepwise from the sink 4 to the intermediate portion 12b via the inlet portion 12a. An intermediate portion 12b of the mesh basket housing portion 12 is formed in a rectangular tubular shape. The intermediate portion 12b has a channel diameter larger than that of the sealing water forming portion 14. As shown in FIG. An outlet portion 12 c of the mesh basket storage portion 12 is formed at the lower end portion of the mesh basket storage portion 12 . The exit portion 12c forms an inward flat portion. The outlet portion 12 c is connected to the water seal forming portion 14 . The outlet portion 12c has a channel diameter larger than that of the water seal forming portion 14, and is formed so as to narrow the channel from the intermediate portion 12b to the water seal forming portion 14. As shown in FIG. The inlet section 12a, the intermediate section 12b and the outlet section 12c form vertical walls. The mesh basket storage part 12 has a channel diameter larger than that of the water seal forming part 14, so that it is easy for the user to visually recognize the inside of the mesh basket storage part 12, and it is easy for the user to insert his/her fingers to clean the inside. Here, the mesh basket housing portion 12 is configured such that the mesh basket 18 can be removed from the mesh basket housing portion 12 by the user in order to dispose of the garbage collected in the mesh basket 18 . Further, the mesh basket housing portion 12 is configured such that the mesh basket 18 after the trash has been thrown away by the user is attached to the mesh basket storage portion 12 . In other words, the mesh basket housing portion 12 is configured so that the user can relatively easily insert his or her fingers into the mesh basket 18 to remove or attach the mesh basket 18 . In this way, the mesh basket storage portion 12 is configured to allow the user's fingers to be easily inserted therein, so that the interior of the mesh basket storage portion 12 can be relatively easily cleaned by the user's fingers. Note that the outlet portion 12c of the mesh basket housing portion 12 may not be formed so that the channel diameter is reduced, and the channel diameter may be reduced by another member on the downstream side.

The water seal forming part 14 has a function of draining the water discharged to the sink 4 and storing a part of the water that has flowed therein to form a normal water seal at a water seal level W0. Here, the term "sealed water" refers to a portion filled with water by a trap, which is provided in the drainage body or the water receiving portion to block off odors and the like. The term “normal water sealing” refers to water sealing when a water discharger, such as a kitchen faucet, does not discharge water when it is not in use (standby state).

As shown in FIG. 5, the sealing water forming part 14 forms a trap-shaped flow path that forms a sealing water at the sealing water level W0.
The water seal forming portion 14 includes a connecting portion 14a connected to the outlet portion 12c of the mesh basket housing portion 12, and an ascending portion 14b, which is an ascending passage ascending obliquely upward toward the downstream side so as to form a drainage trap. A top portion 14c, which is a folded portion connecting the rising portion 14b of the drain trap between the rising portion 14b and the falling portion 14d, and a descending flow path provided downstream of the rising portion 14b and descending from the top portion 14c. and a descending portion 14d. Therefore, the sealing water forming portion 14 forms a trap-shaped flow path that folds back from the ascending portion 14b toward the descending portion 14d. The top portion 14c defines the sealing water level W0. The descending portion 14 d extends substantially vertically downward and is connected to the drainage channel 8 . The sealing water forming part 14 forms a channel of a drainage trap as a channel on the side of the drainage channel 8, and the inner diameter of the channel is small, the shape of the channel is complicated, and the depth of the channel is large. By having any of the elements such as depth, or at least a combination of some of these elements, etc., compared to the mesh basket storage portion 12, it is difficult for the user to insert his or her fingers to clean.

The drainage device 1 further includes a lid 16 arranged so as to cover the upper part of the inlet 12a of the mesh basket housing part 12, and a mesh basket 18 which is arranged on the flow path in the mesh basket housing part 12 and has a mesh. , a flow rate sensor 20 which is a detection unit for detecting water spouted from the kitchen faucet device 6, an ultrasonic oscillator 22 for oscillating ultrasonic waves to the water in the drain body 10, and the operation of the ultrasonic oscillator 22 is controlled. The water level in the drainage body 10 is increased from the sealing water level W0 in the sealing water forming part 14 to the sealing water level W0 in the sealing water forming part 14 by the control device 24 and the water flowing into the drainage body 10. A water level adjusting part 26, which is a flow rate adjusting part, is formed so that the ultrasonic cleaning water level W2 can be easily raised, and a dirt trapping part 28 is formed at the bottom of the mesh basket storage part 12. - 特許庁

The lid 16 is attached to the top of the mesh basket 18 so that the mesh basket 18 is difficult to see from above. Between the lid 16 and the inlet 12a of the mesh basket housing portion 12, a hole (not shown) is formed through which small objects such as water and dust flow.

The mesh basket 18 is arranged inside the intermediate portion 12 b of the mesh basket storage portion 12 . The mesh basket 18 is formed such that its upper end is disposed inside the inlet portion 12a and its upper end substantially coincides with the inlet portion 12a. Therefore, the mesh basket 18 is formed so as to cover the entire flow path on the lower side of the inlet portion 12a. The mesh basket 18 is formed with a plurality of openings so that the water flowing from the sink 4 can pass through, while the small objects such as garbage contained in the water flowing from the sink 4 cannot pass through and are caught in the mesh basket 18 . It is designed to be collected. The mesh basket 18 is formed in a square shape when viewed from above. The mesh basket 18 can be changed to any shape of dust trapping member having a function of trapping dust and the like. The mesh basket 18 is curved so as to protrude downward when the mesh basket 18 is arranged in the mesh basket housing portion 12 . Therefore, the apex 18 a of the bottom of the mesh basket 18 is formed as the top of the curved portion at a position spaced apart from the wall surface of the mesh basket housing portion 12 . Therefore, the mesh basket 18 is formed so that the water flowing out from the top part 18a of the bottom part of the mesh basket 18 can easily flow down in the air spaced apart from the wall surface of the mesh basket storage part 12. - 特許庁When an inner catching portion 36, which will be described later, is provided, the opening of the mesh basket 18 is preferably formed to have a size smaller than that of the opening 36a of the inner catching portion 36. As shown in FIG.

The flow rate sensor 20 is provided between the hot and cold water mixer tap 6a and the water discharger 6b of the kitchen faucet device 6. As shown in FIG. The flow rate sensor 20 can detect the flow rate per unit time of water spouted from the water spouting portion 6b of the kitchen faucet device 6 . Further, the flow rate sensor 20 can detect that water is spouted from the water spouting portion 6b by detecting the flow rate per unit time. Flow sensor 20 is electrically connected to control device 24 .

The ultrasonic oscillator 22 is provided below the mesh basket housing portion 12 of the drainage body portion 10 . The ultrasonic oscillator 22 is provided at the bottom of the drainage main body 10 and arranged so as to emit ultrasonic waves upward. The ultrasonic oscillator 22 is electrically connected with the controller 24 .

The control device 24 incorporates a CPU, memory, etc., has a function of receiving a detection signal transmitted from the flow rate sensor 20, and controls the operation of the ultrasonic oscillator 22 based on a predetermined control program or the like stored in the memory. do. The control device 24 controls the oscillation of ultrasonic waves by the ultrasonic oscillator 22 and the stoppage of the oscillation. The control device 24 has an ultrasonic cleaning mode in which the ultrasonic oscillator 22 starts oscillating in conjunction with the detection of spouted water by the flow rate sensor 20 . The start of water discharge and the start of ultrasonic cleaning can be interlocked. As a modification, the flow rate sensor 20 is arranged at another position to detect the water flowing into the drainage main body 10, and the control device 24 generates ultrasonic waves from the ultrasonic oscillator 22 based on such detection. may be controlled to start oscillation. Further, as a further modification, the flow rate sensor 20 detects the water discharged from the drainage body 10, and the control device 24 controls the ultrasonic oscillator 22 to start oscillating ultrasonic waves based on such detection. you can go

Next, the water level adjusting section of the drainage device according to the first embodiment of the present invention will be described with reference to FIGS. 3 to 5 and 7. FIG.
FIG. 7 is a cross-sectional view taken along line VII--VII of FIG.
For example, when the water flowing into the drainage body 10 is at a predetermined flow rate or more, the water level adjustment part 26 adjusts the water level in the drainage body 10 to the level within the sealing water forming part 14 by the water flowing into the drainage body 10. from the sealing water level W0 in the sealing water forming portion 14 to the ultrasonic cleaning water level W2 higher than the sealing water level W0 in the sealing water forming portion 14. The water level adjusting part 26 is arranged in the sealing water forming part 14 that forms a single flow path from the inlet (inlet part 12a) to the outlet (connecting part with the drainage flow path 8) in the drainage body part 10. Adjust the water level by
The water level adjustment unit 26 adjusts the amount of water discharged to the downstream side when the water level in the drainage body 10 is between the sealing water level W0 and the ultrasonic cleaning water level W2. It is formed so as to be less than the amount of water discharged to the downstream side when reaching W2. The water level adjustment unit 26 has a function of adjusting the water level by the structure of the flow path without depending on opening and closing of the flow path by an electric electromagnetic valve or the like. The water level can be automatically adjusted according to the inflow to the

The water level adjusting portion 26 is formed in the top portion 14c, which is a sealing water level regulating portion that regulates the sealing water level of the drainage trap of the sealing water forming portion 14. As shown in FIG. More specifically, the water level adjusting portion 26 is formed to protrude upward from the top portion 14c. As shown in FIG. 7 , the water level adjusting portion 26 includes a wall 30 that narrows the flow path inside the sealing water forming portion 14 . The wall 30 forms a narrowed portion that narrows the lower side of the flow path in the sealing water forming portion 14 . The wall 30 is formed to rise upward from the bottom surface of the top portion 14c of the flow path in the sealing water forming portion 14 when viewed from the front. The wall 30 is formed so as to rise obliquely rearward and upward from the bottom surface of the top portion 14c of the channel in the sealing water forming portion 14 . The angle of inclination of the front surface 30a of this wall 30 approximates, more preferably substantially coincides with, the angle of inclination of the bottom surface of the raised portion 14b immediately before the top portion 14c. A rear surface 30b of wall 30 extends downward. Therefore, the wall 30 is formed in a triangular shape in cross section in the front-rear direction. In addition, the wall 30 may be formed in a shape other than a triangular shape in the cross section in the front-rear direction. For example, the wall 30 may be formed by narrowing the wall itself of the water seal forming portion 14 inward and forming the wall 30 formed to rise upward from the top portion 14c.

The wall 30 extends in the left-right direction with respect to the main flow direction of water reaching the water level adjusting portion 26, and the wall 30 is formed with a notch 32 extending downward from its upper end 30c. The lateral width A1 of the notch 32 is substantially constant in the vertical direction. A lower portion of the notch 32 is formed by the top portion 14c. The notch 32 extends from the front surface 30a to the rear surface 30b in the front-rear direction. As shown in FIG. 7, the flow path in the sealing water forming portion 14 is formed in a T-shape in a lateral cross section.

The amount of water discharged from the water discharge portion 6b in a normal usage mode (the amount of water flowing into the drainage body 10 per unit time), and the water that cannot pass through the notch 32 is the water level in the drainage body 10. and forms a flow over the top 30c of the wall 30 portion when the water level is above the top 30c. The wall 30 limits the amount of drainage per unit time passing through the notch 32 when the water level is below the upper end 30c, and restricts the flow above the upper end 30c when the water level is above the upper end 30c. It forms a special weir that forms a The amount of water discharged per unit time passing through the first area B1 of the notch 32 (the area cut out by the notch 32) (water discharge flow rate) is determined by the width A1 of the notch 32 and the height h1 of the water level (from the top 14c). determined by the actual height of the water level). In addition, the amount of water discharged per unit time passing through the second area B2 (the amount of water discharged) is determined by the width A2 of the flow path of the sealing water forming portion 14 and the height h2 of the water level above the upper end 30c (the actual water level from the upper end 30c). height). The second region B2 is a region above the upper end 30c of the wall 30. As shown in FIG.

When the water level exceeds the upper end 30c, the amount of water spouted from the water spouting portion 6b (the amount of inflow per unit time flowing into the drainage body portion 10) cannot pass through the first region B1 of the notch 32. Since the remaining water forms a flow over the upper end 30c of the wall 30 portion, the rise of the water level is suppressed.
When the water level exceeds the upper end 30c, the water level adjustment unit 26 controls the amount of water flowing into the drainage body 10 per unit time, and the amount of water passing through the first region B1 of the notch 32 per unit time. A second amount of wastewater, which is the sum of the amount of wastewater passing through the second region B2 per unit time, is discharged. The amount of inflow per unit time flowing into the drainage main body 10 is the same as the second amount of drainage, which is the sum of the amount of drainage per unit time passing through the first region B1 and the amount of drainage per unit time passing through the second region B2. , the water level almost stops rising, and the water level reaches the ultrasonic cleaning water level W2.

The ultrasonic cleaning water level W2 is set to a height higher than the upper end 30c of the wall 30 and lower than the ceiling portion 14e of the top portion 14c of the sealing water forming portion 14. As shown in FIG. Thus, the ultrasonic cleaning water level W2 is defined by the relationship between the first area B1 and the second area B2.

The water level adjuster 26 is formed so that the ultrasonic cleaning water level W2 is positioned within the mesh basket storage part 12 . More preferably, the water level adjusting portion 26 may be formed so as to be located below the entrance portion 12 a of the mesh basket housing portion 12 . Further, the water level adjustment unit 26 may be formed so that the ultrasonic cleaning water level W2 is positioned below the bottom of the mesh basket 18 arranged in the mesh basket housing part 12 . Furthermore, the water level adjusting portion 26 may be formed so that the ultrasonic cleaning water level W2 is at a position equal to or higher than the dirt trapping portion 28 . Furthermore, the water level adjusting portion 26 may be formed so that the ultrasonic cleaning water level W2 is positioned above the inclined portion 34a described later. Also, as a modification, the water level adjusting section 26 can be formed by means different from the wall 30, such as an electrically operated electromagnetic valve, a flow path adjusting valve, or the like. At this time, the control device 24 closes the electromagnetic valve or the like based on the fact that the control device 24 has determined the start of the water discharge, and raises the water level in the water seal forming portion 14 to the ultrasonic cleaning water level W2. It may be controlled to rise. Furthermore, for example, when the water level rises to the ultrasonic cleaning water level W2, the control device 24 performs control such as opening and closing the electromagnetic valve so that the water does not flow back to the sink 4 side. You may suppress a water level rise.

Next, the dirt trapping section 28 of the drainage device 1 according to the first embodiment of the present invention will be described with reference to FIGS. 3 to 5. FIG.
The dirt trapping portion 28 is formed so that dirt tends to adhere to the surface when the water level drops above the dirt trapping portion 28 . The dirt catcher 28 includes a rim 34 projecting inwardly from the side wall of the drain body 10 in a stepped manner, and an inner catcher 36 forming a plurality of openings 36a inside the rim 34 .

The edge portion 34 has a square outer shape, a hollow inside, and an inclined portion 34a that slopes downward toward the inside. The inclined portion 34a forms a flat surface that descends inward. The rim 34 further includes a cylindrical portion 34b extending vertically downward from the inner peripheral end. The cylindrical portion 34b extends below the sealing water level W0. The inclined portion 34 a of the dirt trapping portion 28 and the inner trapping portion 36 form the bottom portion of the mesh basket housing portion 12 . All or part of the bottom of the mesh basket housing portion 12 may not be inclined. The edge portion 34 is a metal member such as a stainless member. Therefore, the cylindrical portion 34a of the edge portion 34, which is a metal member, is arranged on the inner wall surface of the drainage body portion 10 at the sealing water level W0. The edge portion 34 preferably extends below the sealing water level W0 in order to improve the ultrasonic cleaning performance at the sealing water level W0, but the edge portion 34 extends below the sealing water level W0. Even if it is not, if it extends to the vicinity of the seal water level W0, it has a function of improving the constant ultrasonic cleaning performance of the position of the seal water level W0. Further, the edge portion 34 has a function of improving a constant ultrasonic cleaning performance even if it does not extend below the sealing water level W0. Furthermore, the cylindrical portion 34b may be arranged on a part of the entire circumference of the inner wall surface of the drainage body 10 at the sealing water level W0. The outer peripheral portion of the edge portion 34 may be made of the same material as the sink 4, and the inner peripheral portion thereof may be made of a stainless member.

The inner trapping portion 36 forms a circular outer peripheral shape. The outer circumference of the inner trapping portion 36 is connected to the inner circumference of the edge portion 34 so that the upper surface of the edge portion 34 and the upper surface of the inner trapping portion 36 form a continuous, substantially flush upper surface. The inner trapping portion 36 forms a downward slope that is concave toward the central portion. A plurality of openings 36a of the inner capturing portion 36 are formed in a circumferential shape around the central portion. The inner trapping portion 36 may form, for example, a cross-like structure so as to form a plurality of openings 36a, or may form, for example, a mesh-like structure. The inner trapping portion 36 is a metal member such as a stainless member. The inner capturing portion 36 may be made of resin.

Next, the operation (action) of the drainage system including the drainage device 1 according to the first embodiment of the present invention described above will be described with reference to FIGS. 8 to 13. FIG.
FIG. 8 is a partially enlarged cross-sectional view showing the standby state of the drainage body of the drainage device according to the first embodiment of the present invention, and FIG. FIG. 10 is a partially enlarged cross-sectional view showing a state in which water is started, and FIG. 10 shows that water further flows into the drainage main body of the drainage device according to the first embodiment of the present invention, and the water level in the sealing water forming part rises by the water level adjustment part. FIG. 11 is a partially enlarged cross-sectional view showing a state in which water is further introduced into the drainage body of the drainage device according to the first embodiment of the present invention, and the water level in the drainage body reaches the ultrasonic cleaning water level. FIG. 12 is a partially enlarged cross-sectional view showing a state in which the inflow of water into the drainage main body of the drainage device according to the first embodiment of the present invention stops and the water level in the drainage main body gradually decreases FIG. 13 is a cross-sectional view, and FIG. 13 is a partially enlarged cross-sectional view showing how the drainage device according to the first embodiment of the present invention returns to a standby state after a series of cleaning operations are completed;

FIG. 8 shows a standby state before water is spouted from the kitchen faucet device 6 . In the standby state, the water level in the drainage main body 10 is the sealing water level W0 at the top portion 14c of the sealing water forming portion 14. As shown in FIG. When the water level in the drainage main body 10 reaches the sealing water level W0, the drainage channel 8 and the inlet 12a side of the mesh basket storage part 12 and the drainage channel 8 side are pneumatically blocked in the standby state, Odor is reliably prevented from rising from the drainage channel 8 to the inlet portion 12a. In the standby state, the kitchen faucet device 6 is in a state where the water is stopped, and the ultrasonic oscillator 22 is also in a stopped state.

For example, when the user pours water containing dirt E into the sink 4 in the standby state, this water flows into the drainage body 10 . For example, as shown in FIG. 8, dirt E adheres to the mesh basket 18, the mesh basket housing portion 12, the water sealing portion 14, and the like.

As shown in FIG. 9, when water is discharged from the kitchen faucet device 6, water flows from the bottom surface 4b of the sink 4 through the gap between the bottom surface 4b and the lid 16 and into the mesh basket as indicated by an arrow F1. It flows into the inlet portion 12 a of the storage portion 12 . As indicated by an arrow F2, the water that has flowed into the inlet portion 12a passes through the mesh basket 18 and further flows down. At this time, since the apex 18a of the bottom of the mesh basket 18 is positioned away from the wall surface of the mesh basket housing portion 12 as indicated by the arrow F3, the water flowing out from the top 18a of the lower part of the mesh basket 18 However, it becomes easy to flow down in the air spaced apart from the wall surface of the mesh basket storage part 12.例文帳に追加As indicated by arrows F2 and F3, water flowing down from the mesh basket 18 passes through the plurality of openings 36a of the inner trapping portion 36 of the dirt trapping portion 28 and is supplied into the connecting portion 14a of the water seal forming portion 14. As shown in FIG.

Since water flows into the drainage body 10, the water level starts to rise from the sealing water level W0, and as indicated by the arrow F4, the water exceeding the top portion 14a of the sealing water forming portion 14 is turned off by the water level adjusting portion 26. It is discharged to the drainage channel 8 side through the notch 32 .

Here, the amount of inflow per unit time (or the total amount of Inflow amount) of water flows into the drainage main body 10, the water cannot completely flow out from the notch 32, and the water level in the drainage main body 10 is automatically raised. . At this time, the water flowing out from the notch 32 of the water level adjusting portion 26 flows out to the drainage channel 8 as indicated by the arrow F4. In this manner, the water level automatically rises without user intervention to raise the water level. Therefore, it is unnecessary for the user to close the drain valve or the like provided in the conventional drain channel, and the water is supplied into the drain main body 10, so that the drain main body is The water level in the unit 10 automatically reaches the ultrasonic cleaning water level W2, and ultrasonic cleaning can be automatically performed up to the inner wall surface near the sealing water level W0, the dirt trapping section 28, and the like.

Since the water level adjusting section 26 has a wall 30 that narrows a part of its flow path, the first drainage amount per unit time can be relatively small, and the water level in the rising section 14b can be controlled by a relatively small amount of water. can be raised. Thereafter, until FIG. 11, water continues to flow into the drainage body 10 as indicated by an arrow F1.

As shown in FIG. 10, the water level adjuster 26 relatively easily raises the water level in the drainage main body 10 to the height of the upper end 30c higher than the sealing water level W0 by the water flowing into the drainage main body 10. be able to. Since the first drainage amount per unit time that can pass through the notch 32 is a relatively small flow rate, the water level in the drainage body 10 rises to the upper end 30c due to the inflow of relatively small amount of water. For example, when water is spouted from the water spouting portion 6b in a normal usage mode, the water level in the drainage main body 10 rises relatively easily to the upper end 30c due to the inflow of water due to the water spouting in such a normal usage mode. .

As shown in FIG. 11, the water level adjuster 26 raises the water level in the drainage body 10 by the water flowing into the drainage body 10 to an ultrasonic cleaning water level W2 higher than the upper end 30c. When the water level in the drainage body 10 becomes higher than the upper end 30c of the wall 30, a second drainage amount per unit time is discharged downstream from the first area B1 and the second area B2. That is, at a height lower than the upper ends 30c of the walls 30, water is discharged downstream through the cutouts 32 between the walls 30. As shown in FIG. At a height higher than the upper end 30c of the wall 30, water is discharged downstream from the entire lateral width of the water seal forming portion 14 so as to overcome the upper end 30c. When the water level exceeds the upper end 30c, the inflow amount per unit time flowing into the drainage main body 10 is more than the first drainage amount per unit time that can be discharged before reaching the upper end 30c. Since the second drainage volume increases, further rise in the water level is suppressed. For example, when water is spouted from the water spouting portion 6b in a normal usage mode, the water level in the drainage main body 10 does not rise to the ultrasonic cleaning water level W2 due to the inflow of water due to the water spouting in such a normal usage mode. suppressed. A normal usage mode is, for example, 2.5 to 15 L/min. It is preferable that the normal use mode includes water discharge at the maximum flow rate defined by the water discharger 6b (water discharge when the water discharge opening is 100%). That is, even if water is discharged from the water discharger 6b in the maximum flow rate, it is preferable to prevent the water level in the drainage main body 10 from overflowing into the water receiving part. For example, even if water is spouted from the water discharger 6b in the maximum flow rate usage mode (spouting opening), the water level in the drainage main body 10 will rise even with the inflow of water due to the maximum flow rate usage mode. , the height of which is lower than that of the ceiling portion 14e. When the water level in the drainage body 10 rises to the ultrasonic cleaning water level W2 on the side of the water level adjusting part 26, the water level in the drainage body 10 rises from the inner trapping part 36 to the edge 34 on the side of the mesh basket storage part 12. rise to

The control device 24 causes the ultrasonic oscillator 22 to oscillate while the water level in the drainage body 10 has reached the ultrasonic cleaning water level W2. As a result, ultrasonic cleaning can be performed in a state in which the vicinity of the sealing water level W0, to which dirt easily adheres, is submerged. It can be washed by washing. In addition, since the ultrasonic cleaning water level W2 is located above the dirt trapping part 28, the dirt adhering to the dirt trapping part 28 will increase the water level in the drainage body 10 to near the ultrasonic cleaning water level W2 from the next time onwards. It is more reliably cleaned by ultrasonic cleaning when cleaning. The control device 24 causes the ultrasonic oscillator 22 to oscillate in a state assumed to reach the ultrasonic cleaning water level W2.

Even if water further flows into the drainage body 10 after the water level in the drainage body 10 has reached the ultrasonic cleaning water level W2, the water level in the drainage body 10 is maintained near the ultrasonic cleaning water level W2. be. At this time, the water discharge from the water level adjusting section 26 continues. The ultrasonic cleaning water level W2 is positioned above the water level adjusting section 26 on the side of the water level adjusting section 26 in the drainage body 10 . The ultrasonic cleaning water level W2 is positioned inside the mesh basket storage portion 12 and below the entrance portion 12a of the mesh basket storage portion 12. As shown in FIG. As a result, when the water level rises and the water level drops after ultrasonic cleaning is performed, even if some dirt that cannot be cleaned only by ultrasonic cleaning remains in the drain main body 10, it will be removed from the water surface, for example. The net allows the user to easily clean the range in which the dirt that floats on the wall surface adheres to the wall surface of the drainage body 10 and remains on the wall surface. It can be controlled inside the car storage section 12 .

The ultrasonic cleaning water level W2 has an inward inclined portion 34a at the edge portion 34, and is positioned above the inclined portion 34a on the side of the mesh basket storage portion 12 in the drainage body portion 10. As shown in FIG. Since the inclined portion 34a is formed so as to incline toward the inner side, dirt such as dust that has flowed into the drainage device 1 is less likely to stay on the edge portion 34, and a decrease in drainage performance due to the edge portion 34 can be suppressed. , the ultrasonic cleaning water level is positioned above the inclined portion 34a, so that dirt can be effectively adhered to the inclined portion 34a.

The ultrasonic cleaning water level W2 is positioned below the bottom of the mesh basket 18 arranged in the mesh basket storage portion 12 on the side of the mesh basket storage portion 12 in the drainage body portion 10 . Therefore, since the bottom of the mesh basket 18 is less likely to be flooded, deterioration of the cleanability of the mesh basket 18 can be suppressed.

As shown in FIG. 12, when the inflow of water into the drainage main body 10 ends, the second drainage amount per unit time is discharged downstream from the first region B1 and the second region B2, and the drainage main body 10 The water level inside automatically starts to descend from the ultrasonic cleaning water level W2. Therefore, the water level on the side of the mesh basket housing portion 12 in the drainage body portion 10 gradually descends from the inclined portion 34 a of the edge portion 34 of the dirt trapping portion 28 . The dirt trapping portion 28 is formed so that when the water level is lowered along the surface of the inclined portion 34a of the edge portion 34 of the dirt trapping portion 28, dirt is likely to adhere (adsorb) to the surface. As a result, at least part of the dirt that is difficult to remove by ultrasonic cleaning (for example, it floats on water after ultrasonic cleaning) is removed from the dirt trapping section 28 when the water level drops along the surface of the dirt trapping section 28. It can be deposited on the surface of the ramp 34a.

When the water level in the drainage body 10 further drops, the water level in the drainage body 10 on the side of the mesh basket storage part 12 gradually drops from the edge 34 of the dirt trapping part 28 to the inner trapping part 36 . As the water level drops along the surface of the inner trapping portion 36 of the dirt trapping portion 28, more dirt floating on the water surface can adhere to the inner trapping portion 36. Therefore, more dirt can adhere to the dirt trapping portion 28 than when the dirt trapping portion 28 has only the edge portion 34 . Dirt floating on the surface of the water tends to come closer to the inner wall surface inside the drainage main body 10 due to surface tension or the like, and the dirt that has come closer to the inner wall surface side adheres from the edge portion 34 to the inner trapping portion 36 . Therefore, it is possible to reduce the amount of dirt that flows downstream of the dirt trapping section 28 and prevent dirt from remaining on the wall surface of the drainage body 10 on the downstream side of the dirt trapping section 28 . As a result, dirt in the entire drainage device 1 can be efficiently reduced.

As shown in FIG. 13, when the water level in the drainage main body 10 drops to the sealing water level W0, the outflow of water from the notch 32 ends, and the drainage device 1 returns to the standby state.

Next, with reference to FIG. 14, a first modified example of the water level adjusting section of the drainage device according to the first embodiment of the present invention will be described. Regarding the first modified example of the water level adjusting section 126 of the drainage device 1 according to the first embodiment of the present invention, only the differences from the water level adjusting section 26 of the drainage device 1 according to the first embodiment will be described, and the same parts will be denoted by the same reference numerals. , and the description is omitted. The operation (action) of the first modified example of the water level adjustment portion 126 of the drainage device 1 according to the first embodiment of the present invention is the same as the operation (action) of the water level adjustment portion 26 of the drainage device 1 according to the first embodiment. Therefore, the explanation is omitted.
FIG. 14 is a cross-sectional view showing the water level adjusting portion of the first modified example of the drainage device according to the first embodiment of the present invention in a cross-sectional view at the same position as in FIG.

The structure of the water level adjusting portion of the drainage device of the first modified example is different from that of the water level adjusting portion of the drainage device according to the first embodiment of the present invention.
In the drainage device 1, the water level in the drainage main body 10 rises from the sealing water level W0 in the sealing water forming part 14 to a level higher than the sealing water level W0 in the sealing water forming part 14 by the water flowing into the drainage main body 10. A water level adjuster 126, which is a flow rate adjuster, is provided so that the water level can easily rise up to the sonic cleaning water level W2.
The water level adjusting unit 126 adjusts the amount of water discharged to the downstream side when the water level in the drainage body 10 is between the sealing water level W0 and the ultrasonic cleaning water level W2. It is formed so as to be less than the amount of water discharged to the downstream side when reaching W2.
The water level adjustment unit 126 adjusts the amount of water discharged downstream when the water level in the drainage body 10 is between the sealing water level W0 and the upper end 30c of the wall 130, which will be described later. It is formed so as to be smaller than the amount of drainage to the downstream side when reaching the ultrasonic cleaning water level W2.

The water level adjusting portion 126 includes a wall 130 that narrows the flow path within the seal forming portion 14 . The wall 130 forms a narrowed portion that narrows the lower side of the flow path in the sealing water forming portion 14 . The wall 130 is formed so as to rise upward from the bottom surface of the top portion 14c of the flow path in the sealing water forming portion 14 when viewed from the front. The wall 130 is formed so as to rise obliquely rearward and upward from the bottom surface of the top portion 14c of the channel in the sealing water forming portion 14 .

As shown in FIG. 14, the wall 130 extends in the horizontal direction with respect to the main flow direction of water reaching the water level adjusting portion 126, and the wall 130 is formed with a notch 132 extending downward from the upper end 30c thereof. ing. A lateral width A1 of the notch 132 increases downward in the vertical direction. The notch 132 forms a structure in which the top of a triangle is cut off along a line parallel to the base in a front view, for example, a trapezoidal first region B1. A lower portion of the notch 132 is formed by the top portion 14c. The notch 132 extends from the front surface 30a to the rear surface 30b in the front-rear direction.

The amount of water discharged from the water discharge portion 6b in a normal usage mode (the amount of water flowing into the drainage body 10 per unit time), the water that cannot pass through the notch 132 is the water level in the drainage body 10. and form a flow above the top 30c when the water level exceeds the top 30c. The wall 130 limits the amount of drainage per unit time passing through the notch 32 when the water level is below the upper end 30c, and restricts the flow above the upper end 30c when the water level is above the upper end 30c. It forms a special weir that forms a The amount of water discharged per unit time passing through the first area B1 of the notch 132 (the area cut out by the notch 32) (water discharge flow rate) is determined by the width A1 of the notch 32 and the height h1 of the water level (from the top 14c). determined by the actual height of the water level). In addition, the amount of water discharged per unit time passing through the second area B2 (the amount of water discharged) is determined by the width A2 of the flow path of the sealing water forming portion 14 and the height h2 of the water level above the upper end 30c (the actual water level from the upper end 30c). height). The second region B2 is a region above the upper end 30c of the wall 30. As shown in FIG.

When the water level exceeds the upper end 30c, the amount of water spouted from the water spouting portion 6b (the amount of inflow per unit time flowing into the drainage body portion 10) cannot pass through the first region B1 of the notch 132. Since the remaining water forms a flow over the upper end 30c of the wall 130 portion, the rise of the water level is suppressed.
When the water level exceeds the upper end 30c, the water level adjustment unit 126 controls the amount of water flowing into the drainage body 10 per unit time, and the amount of water passing through the first region B1 of the notch 132 per unit time. A second amount of wastewater, which is the sum of the amount of wastewater passing through the second region B2 per unit time, is discharged. The amount of inflow per unit time flowing into the drainage main body 10 is the same as the second amount of drainage, which is the sum of the amount of drainage per unit time passing through the first region B1 and the amount of drainage per unit time passing through the second region B2. , the water level almost stops rising, and the water level reaches the ultrasonic cleaning water level W2.

The ultrasonic cleaning water level W2 is set to a height higher than the upper end 30c of the wall 130 and lower than the ceiling portion 14e of the top portion 14c of the sealing water forming portion 14. FIG. Thus, the ultrasonic cleaning water level W2 is defined by the relationship between the first area B1 and the second area B2.

Next, with reference to FIG. 15, a second modification of the water level adjusting section of the drainage device according to the first embodiment of the present invention will be described. Regarding the water level adjusting section 226 of the second modified example of the drainage device 1 according to the first embodiment of the present invention, only points different from the water level adjusting section 26 of the drainage device 1 according to the first embodiment will be described, and the same parts will be denoted by the same reference numerals. , and the description is omitted. The operation (action) of the water level adjustment section 226 of the second modification of the drainage device 1 according to the first embodiment of the present invention is the same as the operation (action) of the water level adjustment section 26 of the drainage device 1 according to the first embodiment. Therefore, the explanation is omitted.
FIG. 15 is a cross-sectional view similar to FIG. 7 showing the water level adjusting portion of the second modified example of the drainage device according to the first embodiment of the present invention.

The structure of the water level adjusting portion of the drainage device of the first modified example is different from that of the water level adjusting portion of the drainage device according to the first embodiment of the present invention.
In the drainage device 1, the water level in the drainage main body 10 rises from the sealing water level W0 in the sealing water forming part 14 to a level higher than the sealing water level W0 in the sealing water forming part 14 by the water flowing into the drainage main body 10. A water level adjuster 226, which is a flow rate adjuster, is provided so that the water level can easily rise up to the sonic cleaning water level W2.
The water level adjustment unit 226 adjusts the amount of water discharged to the downstream side when the water level in the drainage body 10 is between the sealing water level W0 and the ultrasonic cleaning water level W2. It is formed so as to be less than the amount of water discharged to the downstream side when reaching W2.

The water level adjusting portion 226 includes a wall 230 that narrows the flow path within the seal forming portion 14 . The wall 230 forms a narrowed portion that narrows the lower side of the flow path in the sealing water forming portion 14 . The wall 230 is formed to rise upward from the bottom surface of the top portion 14c of the flow path in the sealing water forming portion 14 when viewed from the front. The wall 230 is formed to rise obliquely rearward and upward from the bottom surface of the top portion 14c of the flow path in the sealing water forming portion 14 .

As shown in FIG. 15, the wall 230 extends in the horizontal direction with respect to the main flow direction of water reaching the water level adjusting portion 226, and the wall 230 is formed with a notch 232 extending downward from its upper end 30c. ing. The lateral width A1 of the notch 232 narrows downward in the vertical direction. The notch 232 forms an inverted triangular first region B1 when viewed from the front. A lower portion of the notch 232 is formed by the top portion 14c. The notch 232 extends from the front surface 30a to the rear surface 30b in the front-rear direction.

The amount of water discharged from the water discharge portion 6b in a normal usage mode (the amount of water flowing into the drainage main body 10 per unit time), the water that cannot pass through the notch 232 is the water level in the drainage main body 10. and form a flow above the top 30c when the water level exceeds the top 30c. The wall 230 limits the amount of drainage per unit time passing through the notch 232 when the water level is below the upper end 30c, and restricts the flow above the upper end 30c when the water level is above the upper end 30c. It forms a special weir that forms a The amount of water discharged per unit time passing through the first region B1 of the notch 232 (the region cut out by the notch 232) (water discharge flow rate) is determined by the width A1 of the notch 232 and the height h1 of the water level (from the top 14c). determined by the actual height of the water level). In addition, the amount of water discharged per unit time passing through the second area B2 (the amount of water discharged) is determined by the width A2 of the flow path of the sealing water forming portion 14 and the height h2 of the water level above the upper end 30c (the actual water level from the upper end 30c). height). The second region B2 is a region above the upper end 30c of the wall 230. As shown in FIG.

When the water level exceeds the upper end 30c, the amount of water spouted from the water spouting portion 6b (the inflow amount per unit time flowing into the drainage body portion 10) does not pass through the first region B1 of the notch 232. Since the remaining water forms a flow over the upper end 30c of the wall 230 portion, the rise of the water level is suppressed.
When the water level exceeds the upper end 30c, the water level adjustment unit 226 adjusts the amount of drainage per unit time passing through the first region B1 of the notch 232 with respect to the amount of water flowing into the drainage body 10 per unit time. A second amount of wastewater, which is the sum of the amount of wastewater passing through the second region B2 per unit time, is discharged. The amount of inflow per unit time flowing into the drainage main body 10 is the same as the second amount of drainage, which is the sum of the amount of drainage per unit time passing through the first region B1 and the amount of drainage per unit time passing through the second region B2. , the water level almost stops rising, and the water level reaches the ultrasonic cleaning water level W2.

Next, with reference to FIG. 16, a third modification of the water level adjusting section of the drainage device according to the first embodiment of the present invention will be described. Regarding the water level adjusting section 326 of the third modified example of the drainage device 1 according to the first embodiment of the present invention, only differences from the water level adjusting section 26 of the drainage device 1 according to the first embodiment will be described, and the same parts will be denoted by the same reference numerals. , and the description is omitted. The operation (action) of the water level adjustment unit 326 of the drainage device 1 of the third modification according to the first embodiment of the present invention is the same as the operation (action) of the water level adjustment unit 26 of the drainage device 1 according to the first embodiment. Therefore, the explanation is omitted.
FIG. 16 is a cross-sectional view similar to FIG. 7 showing the water level adjusting portion of the drainage device of the third modification according to the first embodiment of the present invention.

The structure of the water level adjusting portion of the drainage device of the third modified example is different from that of the water level adjusting portion of the drainage device according to the first embodiment of the present invention.
In the drainage device 1, the water level in the drainage main body 10 rises from the sealing water level W0 in the sealing water forming part 14 to a level higher than the sealing water level W0 in the sealing water forming part 14 by the water flowing into the drainage main body 10. A water level adjuster 326, which is a flow rate adjuster, is provided so that it can easily rise to the sonic cleaning water level W2.
The water level adjustment unit 326 adjusts the amount of water discharged to the downstream side when the water level in the drainage body 10 is between the sealing water level W0 and the ultrasonic cleaning water level W2. It is formed so as to be less than the amount of water discharged to the downstream side when reaching W2.

The water level adjusting portion 326 includes a wall 330 that narrows the flow path within the seal forming portion 14 . The wall 330 forms a narrowed portion that narrows the lower side of the flow path in the sealing water forming portion 14 . The wall 330 is formed to rise upward from the bottom surface of the top portion 14c of the flow path in the sealing water forming portion 14 when viewed from the front. The wall 330 is formed so as to rise obliquely rearward and upward from the bottom surface of the top portion 14c of the channel in the sealing water forming portion 14 .

As shown in FIG. 16, the wall 330 extends in the horizontal direction with respect to the main flow direction of the water reaching the water level adjusting portion 326, and further extends upward from the lower end of the wall 330 and forms a rectangular opening. A notch 332 is formed to accommodate. The lateral width A1 of the notch 332 is substantially constant in the vertical direction. The notch 332 forms a square-shaped first region B1 when viewed from the front. A lower portion of the notch 332 is formed by the top portion 14c. The notch 332 extends from the front surface 30a to the rear surface 30b in the front-rear direction. Note that the notch 332 may be an opening formed in the wall 330 in a circular shape, an elliptical shape, or the like.

The amount of water discharged from the water discharge portion 6b in a normal usage mode (the amount of water flowing into the drainage body 10 per unit time), and the water that cannot pass through the notch 332 is the water level in the drainage body 10. and form a flow above the top 30c when the water level exceeds the top 30c. The wall 330 limits the amount of drainage per unit time passing through the notch 332 when the water level is below the upper end 30c, and restricts the flow above the upper end 30c when the water level is above the upper end 30c. It forms a special weir that forms a The amount of water discharged per unit time passing through the first area B1 of the notch 332 (the area cut out by the notch 332) (water discharge flow rate) is determined by the width A1 of the notch 332 and the height h1 of the water level (from the top 14c). determined by the actual height of the water level). In addition, the amount of water discharged per unit time passing through the second area B2 (the amount of water discharged) is determined by the width A2 of the flow path of the sealing water forming portion 14 and the height h2 of the water level above the upper end 30c (the actual water level from the upper end 30c). height). The second region B2 is a region above the upper end 30c of the wall 330. As shown in FIG.

When the water level exceeds the upper end 30c, the amount of water spouted from the water spouting portion 6b (the inflow amount per unit time flowing into the drainage body portion 10) does not pass through the first region B1 of the notch 332. Since the remaining water forms a flow over the upper end 30c of the wall 330 portion, the rise of the water level is suppressed.
When the water level exceeds the upper end 30c, the water level adjustment unit 326 adjusts the amount of drainage per unit time passing through the first region B1 of the notch 332 to the amount of water flowing into the drainage body 10 per unit time. A second amount of wastewater, which is the sum of the amount of wastewater passing through the second region B2 per unit time, is discharged. The amount of inflow per unit time flowing into the drainage main body 10 is the same as the second amount of drainage, which is the sum of the amount of drainage per unit time passing through the first region B1 and the amount of drainage per unit time passing through the second region B2. , the water level almost stops rising, and the water level reaches the ultrasonic cleaning water level W2.

Next, with reference to FIG. 17, a fourth modified example of the water level adjusting section of the drainage device according to the first embodiment of the present invention will be described. Regarding the water level adjusting section 426 of the fourth modified example of the drainage device 1 according to the first embodiment of the present invention, only differences from the water level adjusting section 26 of the drainage device 1 according to the first embodiment will be described, and the same parts will be denoted by the same reference numerals. , and the description is omitted. The operation (action) of the water level adjustment unit 426 of the drainage device 1 of the fourth modification according to the first embodiment of the present invention is the same as the operation (action) of the water level adjustment unit 26 of the drainage device 1 according to the first embodiment. Therefore, the explanation is omitted.
FIG. 17 is a cross-sectional view similar to FIG. 7 showing the water level adjusting portion of the drainage device of the fourth modification according to the first embodiment of the present invention.

The structure of the water level adjusting portion of the drainage device of the fourth modified example is different from that of the water level adjusting portion of the drainage device according to the first embodiment of the present invention.
In the drainage device 1, the water level in the drainage main body 10 rises from the sealing water level W0 in the sealing water forming part 14 to a level higher than the sealing water level W0 in the sealing water forming part 14 by the water flowing into the drainage main body 10. A water level adjuster 426, which is a flow rate adjuster, is provided so that it can easily rise to the sonic cleaning water level W2.
The water level adjustment unit 426 adjusts the amount of water discharged to the downstream side when the water level in the drainage body 10 is between the sealing water level W0 and the ultrasonic cleaning water level W2. It is formed so as to be less than the amount of water discharged to the downstream side when reaching W2.

The water level adjusting portion 426 includes a wall 430 that narrows the flow path within the seal forming portion 14 . The wall 430 forms a narrowed portion that narrows the lower side of the flow path in the sealing water forming portion 14 . The wall 430 is formed to rise upward from the bottom surface of the top portion 14c of the flow path in the water seal forming portion 14 when viewed from the front. The wall 430 is formed so as to rise obliquely rearward and upward from the bottom surface of the top portion 14c of the channel in the sealing water forming portion 14 .

As shown in FIG. 17, the wall 430 extends in the left-right direction with respect to the main flow direction of the water reaching the water level adjustment portion 426, and the wall 430 has rectangular openings extending up and down on the left and right sides thereof. A forming notch 432 is formed. The width A1 represented by the sum of the lateral widths of the cutouts 432 on both the left and right sides is substantially constant in the vertical direction. The cutouts 432 form first regions B1, which are rectangular first regions, on the left and right sides of the wall 430 when viewed from the front. A lower portion of the notch 432 is formed by the top portion 14c. The notch 432 extends from the front surface 30a to the rear surface 30b in the front-rear direction.

The amount of water spouted from the water spouting portion 6b in a normal usage mode (the amount of inflow per unit time flowing into the drainage body 10), the water that cannot pass through the notch 432 is the water level in the drainage body 10. and form a flow above the top 30c when the water level exceeds the top 30c. The wall 430 limits the amount of drainage per unit time passing through the notch 432 when the water level is below the upper end 30c, and restricts the flow above the upper end 30c when the water level is above the upper end 30c. It forms a special weir that forms a The amount of water discharged per unit time passing through the first region B1 of the notch 432 (the region cut out by the notch 432) is determined by the width A1 of the notch 432 and the height h1 of the water level (from the top 14c). determined by the actual height of the water level). In addition, the amount of water discharged per unit time passing through the second area B2 (the amount of water discharged) is determined by the width A2 of the flow path of the sealing water forming portion 14 and the height h2 of the water level above the upper end 30c (the actual water level from the upper end 30c). height). The second region B2 is a region above the upper end 30c of the wall 430. As shown in FIG.

When the water level exceeds the upper end 30c, the amount of water spouted from the water spouting portion 6b (the inflow amount per unit time flowing into the drainage body portion 10) does not pass through the first region B1 of the notch 432. Since the remaining water forms a flow over the upper end 30c of the wall 430 portion, the rise of the water level is suppressed.
When the water level exceeds the upper end 30c, the water level adjustment unit 426 controls the amount of water flowing into the drainage main body 10 per unit time and the amount of water passing through the first region B1 of the notch 432 per unit time. A second amount of wastewater, which is the sum of the amount of wastewater passing through the second region B2 per unit time, is discharged. The amount of inflow per unit time flowing into the drainage main body 10 is the same as the second amount of drainage, which is the sum of the amount of drainage per unit time passing through the first region B1 and the amount of drainage per unit time passing through the second region B2. , the water level almost stops rising, and the water level reaches the ultrasonic cleaning water level W2.

According to the drainage device 1 according to the first embodiment of the present invention described above, the water level adjusting portion 26 is configured such that the water level in the drainage body portion 10 is adjusted to the level in the water seal forming portion 14 by the water flowing into the drainage body portion 10 . It is formed so as to easily rise from the water level W0 to the ultrasonic cleaning water level W2 higher than the sealing water level W0 in the sealing water forming portion 14 . Further, the water level adjusting unit 26 determines the amount of water discharged downstream per unit time until the water level in the drainage main body 10 reaches from the sealing water level W0 to the ultrasonic cleaning water level W2. It is formed so as to be less than the amount of water discharged downstream per unit time when the ultrasonic cleaning water level W2 is reached. As a result, the water level in the drainage body 10 rises to the ultrasonic cleaning water level W2, and ultrasonic cleaning can be easily performed to the ultrasonic cleaning water level W2 higher than the sealing water level W0, and the water level in the drainage body 10 rises. It can be made difficult to rise beyond the ultrasonic cleaning water level W2. Furthermore, water can flow into the drainage body 10 even during ultrasonic cleaning. Therefore, according to the configuration as described above, in order to clean dirt in the vicinity of the sealing water level W0 in the drainage body 10 by ultrasonic cleaning, the water level in the drainage body 10 is ultrasonically cleaned higher than the sealing water level W0. It is possible to easily raise the water level to W2 and prevent the water in the drain main body 10 from exceeding the ultrasonic cleaning water level W2 and overflowing into the sink 4. - 特許庁

Furthermore, according to the drainage device 1 according to the first embodiment of the present invention, the water level in the drainage main body 10 is raised to the ultrasonic cleaning water level W2 by the wall 30 that narrows the flow path in the sealing water forming part 14, and the sealing is performed. The ultrasonic cleaning can be easily performed up to the ultrasonic cleaning water level W2 higher than the water level W0, and the water level in the drainage body 10 can be made difficult to rise beyond the ultrasonic cleaning water level W2. Therefore, according to the configuration as described above, the water level in the drainage main body 10 is sealed in order to clean the dirt in the vicinity of the sealing water level W0 in the drainage main body 10 by ultrasonic cleaning with a relatively simple structure. It is possible to easily raise the water level W0 to an ultrasonic cleaning water level W2 higher than the water level W0, and prevent the water in the drain main body 10 from exceeding the ultrasonic cleaning water level W2 and overflowing into the sink 4. - 特許庁

Furthermore, according to the drainage device 1 according to the first embodiment of the present invention, the wall 30 of the water level adjusting portion 26 is formed to rise upward from the seal water level regulating portion that regulates the seal water level. The wall 30 is formed with a notch 32 extending in the horizontal direction with respect to the main water flow direction and extending downward from the upper end 30c. As a result, when the water level in the drainage body 10 rises from the sealing water level W0 to the ultrasonic cleaning water level W2, compared to the case where the notch 32 is formed in the wall 30 at a position spaced apart from the upper end 30c. It is possible to prevent the continuity of the rate of change in water level rise from being impaired (rapidly fluctuating the rate of rise), and to raise the water level at a relatively constant rate of change in water level rise with respect to a relatively constant amount of inflow.

Furthermore, according to the drainage device 1 according to the first embodiment of the present invention, the notch 32 formed in the wall 30 of the water level adjusting section 26 is formed so that the width in the horizontal direction is substantially constant in the vertical direction. ing. As a result, when the water level in the drainage main body 10 drops to the sealing water level W0, it is possible to suppress the decrease in the drainage flow rate as the water level drops. Therefore, when the water level in the drainage main body 10 drops to the vicinity of the sealing water level W0, the dirt floating on the water surface can be discharged downstream from the notch 32, and the discharge performance of the dirt floating on the water surface is lowered. can be suppressed. Furthermore, since the notch 32 of the wall 30 is formed with a relatively simple structure, it is possible to suppress clogging due to adhesion of dirt to the notch 32 of the wall 30 .
If the width of the notch 32 in the left-right direction becomes narrower as it goes downward, although there is a certain effect in suppressing the rise in the water level and the overflow of water as described above, the water level does not reach the sealing water level W0. If the water level drops, the flow rate of the wastewater will decrease, and there is a risk that the discharge performance of dirt floating on the water surface will decrease.

Furthermore, according to the drainage device 1 according to the first embodiment of the present invention, the lateral width A1 of the notch 32 formed in the wall 30 of the water level adjusting portion 26 increases downward in the vertical direction. As a result, when the water level in the drainage main body 10 drops to the sealing water level W0, it is possible to suppress the decrease in the drainage flow rate as the water level drops. Therefore, when the water level in the drainage main body 10 drops to the vicinity of the sealing water level W0, the dirt floating on the water surface can be discharged downstream from the notch 32, and the discharge performance of the dirt floating on the water surface is lowered. can be suppressed.

Furthermore, according to the drainage device 1 according to the first embodiment of the present invention, the water level adjustment part 26 is set so that the ultrasonic cleaning water level W2 is higher than the bottom part of the mesh basket 18 in the state of being arranged in the drainage body part 10 It is formed so as to be located on the lower side. As a result, when the ultrasonic cleaning water level W2 is located below the bottom of the mesh basket 18, the ultrasonic cleaning water level W2 is lower than when the ultrasonic cleaning water level W2 is located above the bottom of the mesh basket 18. The amount of water per unit time in the drainage main body 10 during cleaning is reduced, and the sound pressure of the ultrasonic waves acting on the surface of the wall 30 near the sealing water level W0, where dirt tends to remain, can be made relatively high, and the vicinity of the sealing water level W0 can be made relatively high. can improve the ultrasonic cleaning ability of

Next, a drainage device according to a second embodiment of the present invention will be described with reference to FIG. 2nd Embodiment is an example which formed the drainage apparatus by what is called a bottle trap by this invention. 18 is a central cross-sectional view of a drainage device according to a second embodiment of the present invention, and FIG. 19 is a cross-sectional view along line XIX-XIX of FIG.

Since the drainage device 501 according to the second embodiment has a basic structure similar to that of the drainage device 1 according to the first embodiment described above, only the differences from the first embodiment of the second embodiment of the present invention will be described. , and similar parts are denoted by the same reference numerals in the drawings, and descriptions thereof are omitted. The operation (action) of the drainage device 501 according to the second embodiment of the present invention is the same as the operation (action) of the drainage system 2 according to the first embodiment, so the explanation is omitted.

The drain main body 510 is provided downstream of the sink 4 and includes a mesh basket storage portion 12 in which a mesh basket is stored, and a water seal forming portion provided downstream of the mesh basket storage portion 12 and forming a water seal. 514.
Hereinafter, in the description of the first embodiment of the present invention, the upstream side with respect to the main flow direction of water reaching the water level adjustment portion 526 is the front side, the side opposite to the upstream side is the rear side, and the water level adjustment portion 526 The right side is defined as the right side when viewed from the front, and the left side is defined as the left side when viewed from the front.

As shown in FIG. 18 , the inlet portion 12 a and the intermediate portion 12 b of the mesh basket housing portion 12 have a channel diameter larger than that of the sealing water forming portion 514 .

The water seal forming part 514 has a function of draining the water discharged to the sink 4 and storing a part of the water that has flowed thereinto to form a normal water seal at the seal water level W0.

The sealing water forming part 514 forms a trap-shaped flow path that forms a sealing water at the sealing water level W0. The water sealing forming portion 514 includes a connecting portion 514a connected to the outlet portion 12c of the mesh basket housing portion 12, and an ascending portion 514b, which is an ascending passage ascending obliquely upward toward the downstream side so as to form a drainage trap. , a top portion 514c that is a folded portion between the rising portion 514b and the descending portion 514d, and a descending portion 514d that is provided downstream of the ascending portion 514b and descending from the top portion 514c. . The connecting portion 514a forms a tubular descending flow path extending downward from the top portion 514c. Therefore, the sealing water forming portion 514 forms a trap-shaped flow path that folds upward from the connecting portion 514a extending downward toward the ascending portion 514b, and the top portion 514c defines the sealing water level W0. In this manner, the water seal forming portion 514 forms a so-called bottle trap. The descending portion 514 d extends substantially vertically downward and is connected to the drainage channel 8 . The sealing water forming part 514 forms a channel of a drainage trap as a channel on the side of the drainage channel 8, and the inner diameter of the channel is small, the shape of the channel is complicated, and the depth of the channel is large. By having any of the elements such as depth, or at least a combination of some of these elements, etc., compared to the mesh basket storage portion 12, it is difficult for the user to insert his or her fingers to clean.

In the drainage device 501, the water level in the drainage main body 510 is further lowered from the sealing water level W0 in the sealing water forming part 514 to the sealing water level W0 in the sealing water forming part 514 by the water flowing into the drainage main body 510. A water level adjusting portion 526, which is a flow rate adjusting portion formed so as to be easily raised to a high ultrasonic cleaning water level W2, and a dirt trapping portion 28 formed at the bottom of the mesh basket housing portion 512 are provided.

Next, with reference to FIGS. 18 and 19, the water level adjusting section of the drainage device according to the first embodiment of the present invention will be described.
For example, when the water flowing into the drainage main body 510 is at a predetermined flow rate or more, the water level adjusting section 526 adjusts the water level inside the drainage main body 510 to the level within the sealing water forming section 514 due to the water flowing into the drainage main body 510. from the sealing water level W0 in the sealing water forming portion 514 to the ultrasonic cleaning water level W2 higher than the sealing water level W0 in the sealing water forming portion 514. The water level adjusting portion 526 is arranged in a sealing water forming portion 514 that forms a single flow path from the inlet portion (the inlet portion 12a) to the outlet portion (the connection portion with the drainage flow path 8) in the drainage body portion 510. Adjust the water level by
The water level adjustment unit 526 adjusts the amount of water discharged to the downstream side when the water level in the drainage body 510 is between the sealing water level W0 and the ultrasonic cleaning water level W2. It is formed so as to be less than the amount of water discharged to the downstream side when reaching W2.

The water level adjusting portion 526 is formed on the top portion 514 c that is a sealing water level regulating portion that regulates the sealing water level of the drain trap of the sealing water forming portion 514 . More specifically, the water level adjusting portion 526 is formed to protrude upward from the top portion 514c.
The water level adjusting portion 526 includes a wall 530 that narrows the flow path within the seal forming portion 514 . The wall 530 forms a narrowed portion that narrows the lower side of the flow path in the sealing water forming portion 514 . The wall 530 is formed to rise upward from the bottom surface of the top portion 514c of the flow path in the sealing water forming portion 514 when viewed from the front. The wall 530 is formed to rise obliquely rearward and upward from the bottom surface of the top portion 514c of the flow path in the sealing water forming portion 514 . The wall 530 is formed from the sealing water level W0 to near the ultrasonic cleaning water level W2. The inclination angle of the front surface 530a of the wall 530 is larger than the inclination angle of the bottom surface of the ascending portion 514b immediately before the top portion 514c. A rear surface 530b of wall 530 extends downward. Therefore, the wall 530 is formed in a triangular shape in cross section in the front-rear direction. Note that the wall 530 may be formed in a shape other than the triangular shape in the cross section in the front-rear direction. Note that, for example, the wall 530 may be formed by narrowing the wall itself of the water seal forming portion 514 inward and forming the wall 530 formed to rise upward from the top portion 514c.

As shown in FIG. 19, the wall 530 extends in the horizontal direction with respect to the main flow direction of the water reaching the water level adjusting portion 526, and the wall 530 is formed with a notch 532 extending downward from its upper end 530c. ing. The lateral width A1 of the notch 532 is substantially constant in the vertical direction. The lower portion of the notch 532 is formed by the top portion 514c. The notch 532 extends from the front surface 530a to the rear surface 530b in the front-rear direction.

The amount of water discharged from the water discharge portion 6b in a normal usage mode (the amount of water flowing into the drainage body 510 per unit time), the water that cannot pass through the notch 532 is the water level in the drainage body 510. , forming a flow that also exceeds the upper edge 530c of the wall 530 portion when the water level exceeds the upper edge 530c. The wall 530 limits the amount of drainage per unit time passing through the notch 532 when the water level is below the upper end 530c, and restricts the flow above the upper end 530c when the water level is above the upper end 530c. It forms a special weir that forms a The amount of drainage per unit time passing through the first area B1 of the notch 532 (the area cut out by the notch 32) (water discharge flow rate) is determined by the width A1 of the notch 532 and the height h1 of the water level (from the top 14c). determined by the actual height of the water level). In addition, the amount of water discharged per unit time passing through the second region B2 (water discharge flow rate) is determined by the width A2 of the flow path of the sealing water forming portion 514 and the height h2 of the water level above the upper end 30c (the actual water level from the upper end 30c). height). The second region B2 is a region above the upper end 30c of the wall 30. As shown in FIG.

When the water level exceeds the upper end 530c, the amount of water spouted from the water spouting portion 6b (the inflow amount per unit time flowing into the drainage body portion 10) cannot pass through the first region B1 of the notch 532. Since the remaining water forms a flow over the upper end 530c of the wall 530 portion, the rise of the water level is suppressed.
When the water level exceeds the upper end 530c, the water level adjustment unit 526 controls the amount of water flowing into the drainage main body 510 per unit time, and the amount of water passing through the first region B1 of the notch 532 per unit time. A second amount of wastewater, which is the sum of the amount of wastewater passing through the second region B2 per unit time, is discharged. The inflow amount per unit time flowing into the drainage main body 510 is the same as the second drainage amount, which is the sum of the amount of drainage per unit time passing through the first region B1 and the amount of drainage per unit time passing through the second region B2. , the water level almost stops rising, and the water level reaches the ultrasonic cleaning water level W2.

The ultrasonic cleaning water level W2 is set to a height higher than the upper end 530c of the wall 530 and lower than the ceiling portion 514e of the sealing water forming portion 514. As shown in FIG. Thus, the ultrasonic cleaning water level W2 is defined by the relationship between the first area B1 and the second area B2.

The water level adjustment part 526 is formed so that the ultrasonic cleaning water level W2 is positioned within the mesh basket storage part 12 . More preferably, the water level adjustment part 526 may be formed so as to be located below the entrance part 12 a of the mesh basket storage part 12 . Further, the water level adjustment portion 526 is formed so that the ultrasonic cleaning water level W2 is positioned below the bottom portion of the mesh basket 18 arranged in the mesh basket housing portion 12 . Furthermore, the water level adjusting portion 526 may be formed so that the ultrasonic cleaning water level W2 is at a position equal to or higher than the dirt trapping portion 28 . Furthermore, the water level adjusting portion 526 may be formed so that the ultrasonic cleaning water level W2 is positioned above the inclined portion 34a. As a modification, the water level adjusting section 526 can be formed by a means different from the wall 530, such as an electrically operated solenoid valve, a flow path adjusting valve, or the like. At this time, based on the fact that the control device 24 has determined that water is to be spouted, the control device 24 closes the electromagnetic valve or the like to raise the water level in the sealing water forming portion 514, and the water level reaches the ultrasonic cleaning water level W2. may be controlled to rise to Furthermore, for example, when the water level rises to the ultrasonic cleaning water level W2, the control device 24 performs control such as opening and closing the electromagnetic valve so that the water does not flow back to the sink 4 side. You may suppress a water level rise.

As a further modification, the drainage device 1 according to the present invention may be formed in a so-called one-trap structure. In this one trap, a water level adjusting portion is formed at the upper end of the drain pipe connected to the drain channel 8 and rising upward. A bowl-shaped body (cap) is arranged so as to cover the drainage pipeline and the water level adjusting section above, and a drainage trap is formed between the drainage pipeline and the bowl-shaped body. For example, the water level adjusting portion is formed by a recessed notch formed downward from the circumferential upper end of the drain pipe. The seal water level W0 is defined by the lower end of the recessed notch of the water level adjusting portion.

Next, a drainage device according to a third embodiment of the present invention will be described with reference to FIGS. 20 to 22. FIG. The third embodiment is an example in which the drainage device according to the present invention is applied to the washing floor of a bathroom. FIG. 20 is a perspective view of a bathroom equipped with a drainage device according to a third embodiment and a drainage device according to a fourth embodiment of the present invention. 21 is a partially enlarged cross-sectional view of the vicinity of the floor surface of the bathroom viewed along line XXI-XXI of FIG. 20, and FIG. 22 is a partially enlarged cross-sectional view of the XXII portion of FIG.

Since the drainage device 601 according to the third embodiment has a basic structure similar to that of the drainage device 1 according to the first embodiment described above, the third embodiment of the present invention differs only from the first embodiment. Similar parts are given the same reference numerals in the drawings, and the description thereof is omitted. The operation (action) of the drainage device 601 according to the third embodiment of the present invention is the same as the operation (action) of the drainage device 1 according to the first embodiment, so the explanation is omitted.

The drainage device 601 includes a washing space floor 604 that is a water receiving portion provided in the bathroom 602, a bathtub 605 that is a water receiving portion provided in the bathroom 602, and a bathroom faucet that discharges water (hot water) to the washing space floor 604. A washing place side faucet device (water discharge part) 606 which is a device (bathroom faucet), and a shower faucet device (bathroom faucet) which is a bathroom faucet device (bathroom faucet) that spouts water (hot water) to the washing place floor 604 or the bathtub 605 607, a bathtub side faucet device 709 which is a supply device for spouting water (hot water) to the bathtub 605, and a drain body 610 connected to the downstream end of the bottom 604a of the floor 604 of the washing place. ing. The washing place floor 604 is formed to discharge water discharged from the washing place side faucet device 606 and/or the shower faucet device 607 to the downstream side.

The washing place side faucet device 606 and the shower faucet device 607 are connected on the upstream side to a water supply channel 9 to which water is supplied from a water supply source (not shown) and to a hot water supply channel 11 to which hot water is supplied. . The washing place side faucet device 606 and the shower faucet device 607 are provided with a hot and cold water mixing faucet 6a, mix water from the cold water supply channel 9 and hot water from the hot water supply channel 11, and discharge water from water discharge parts 606b and 607b. . The water supply channel 9 and the hot water supply channel 11 are connected to the hot and cold water mixing valve 6a, and the water discharge side channel 6c extends downward from the hot and cold water mixing valve 6a, passes through the flow rate sensor 20 described later, and extends to the water discharge portions 606b and 607b. ing.

As shown in FIG. 21, the drain body 610 is provided downstream of the wash area floor 604 and is configured to form a water seal.
The drain main body 610 is provided downstream of the floor 604 of the washing area, and a mesh basket storage portion 612 in which a mesh basket is stored, and a water seal that is provided downstream of the mesh basket storage portion 612 and forms a water seal. and a forming portion 614 .
Hereinafter, in the description of the third embodiment of the present invention, the upstream side with respect to the main flow direction of water reaching the water level adjustment portion 626 is the front side, the side opposite to the upstream side is the rear side, and the water level adjustment portion 626 The right side is defined as the right side when viewed from the front, and the left side is defined as the left side when viewed from the front.

The mesh basket housing portion 612 is formed to have a size such that the mesh basket 18, which is a hair catcher, can be stored. The mesh basket storage part 612 has an inlet part 612a that opens toward the floor 604 of the washing place, an intermediate part 612b that stores the mesh basket, and an outlet part that has a reduced flow path diameter from the intermediate part toward the sealing water forming part 614. 612c.

An entrance portion 612a of the mesh basket housing portion 612 is opened in a rectangular shape and forms a drain port portion of the floor 604 of the washing space. The inlet portion 612a is formed by partially recessing the bottom portion 604a below the bottom surface. The inlet portion 612 a has a flow path diameter larger than that of the water seal forming portion 614 . An intermediate portion 612b of the mesh basket housing portion 612 is formed in a circular tubular shape so that a mesh basket can be placed therein. The intermediate portion 612b has a channel diameter larger than that of the sealing water forming portion 614. As shown in FIG. An outlet portion 612 c of the mesh basket storage portion 612 is formed at the lower end portion of the mesh basket storage portion 612 . Outlet portion 612c forms an inward flat portion. The outlet portion 612 c is connected to the water seal forming portion 614 . The outlet portion 612c has a channel diameter larger than that of the water seal forming portion 614, and is formed so as to narrow the channel from the intermediate portion 612b to the water seal forming portion 614. As shown in FIG. The inlet portion 612a, intermediate portion 612b and outlet portion 612c form vertical walls. The mesh basket housing portion 12 has a flow path diameter larger than that of the water seal forming portion 614, so that the user can easily visually recognize the inside of the mesh basket housing portion 12, and the user can easily insert his or her fingers into the inside to clean. Here, the mesh basket storage portion 612 is configured such that the mesh basket 18 can be removed from the mesh basket storage portion 612 by the user in order to dispose of the garbage collected in the mesh basket 18 . Further, the mesh basket storage portion 612 is configured such that the mesh basket 18 after the trash has been thrown away by the user can be attached to the mesh basket storage portion 612 . In other words, the mesh basket housing portion 612 is configured so that the user can relatively easily insert his or her fingers into the mesh basket 18 to remove or attach the mesh basket 18 . As described above, the mesh basket storage portion 612 is configured so that the user's fingers can be easily inserted therein, so that the interior of the mesh basket storage portion 612 can be relatively easily cleaned by the user's fingers. Note that the outlet portion 612c of the mesh basket housing portion 612 may not be formed so that the flow path diameter is reduced, and furthermore, the flow path diameter may be reduced by another member on the downstream side.

The water seal forming part 614 has a function of draining the water spouted onto the floor 604 of the washing place, storing part of the water that has flowed in, and forming a normal water seal at the water seal water level W0 inside it. .

The sealing water forming part 614 forms a trap-shaped flow path that forms a sealing water at the sealing water level W0. The water sealing forming portion 614 includes a connecting portion 614a connected to an outlet portion 612c of the mesh basket housing portion 612, and an ascending portion 614b, which is an ascending passage ascending obliquely upward toward the downstream side so as to form a drainage trap. A top portion 614c, which is a folded portion connecting the rising portion 614b of the drain trap between the rising portion 614b and the descending portion 614d, and a descending flow path provided downstream of the ascending portion 614b and descending from the top portion 614c. and a descending portion 614d. Therefore, the sealing water forming portion 614 forms a trap-shaped flow path that folds back from the ascending portion 614b toward the descending portion 614d. The top portion 614c defines the sealing water level W0. The descending portion 614 d extends substantially vertically downward and is connected to the drainage channel 8 . The sealing water forming part 614 forms a channel of a drainage trap as a channel on the side of the drainage channel 8, and the inner diameter of the channel is small, the shape of the channel is complicated, and the depth of the channel is large. By having any of the elements such as depth, or at least a combination of some of these elements, etc., compared to the mesh basket storage portion 12, it is difficult for the user to insert his or her fingers to clean.

In the drainage device 1, the water level in the drainage main body 610 is further lowered from the sealing water level W0 in the sealing water forming part 614 to the sealing water level W0 in the sealing water forming part 614 by the water flowing into the drainage main body 610. Equipped with a water level adjusting portion 626 which is a flow rate adjusting portion formed so that the ultrasonic cleaning water level W2 can be easily increased, and a dirt trapping portion 628 formed at the bottom of the mesh basket housing portion 612.

For example, when the water flowing into the drainage main body 610 is at a predetermined flow rate or more, the water level adjustment part 626 adjusts the water level inside the drainage main body 610 to the level within the sealing water forming part 614 due to the water flowing into the drainage main body 610. from the sealing water level W0 in the sealing water forming portion 614 to the ultrasonic cleaning water level W2 higher than the sealing water level W0 in the sealing water forming portion 614. The water level adjusting part 626 is arranged in the water seal forming part 614 that forms a single flow path from the inlet (connecting part 614a) to the outlet (connecting part with the drainage flow path 8) in the drainage body part 610. Adjust the water level by The water level adjustment unit 626 adjusts the amount of water discharged to the downstream side when the water level in the drainage body 610 is between the sealing water level W0 and the ultrasonic cleaning water level W2. It is formed so as to be less than the amount of water discharged to the downstream side when reaching W2.

The water level adjusting portion 626 is formed at the top portion 614 c which is a sealing water level regulating portion that regulates the sealing water level of the sealing water forming portion 614 . More specifically, the water level adjusting portion 626 is formed to protrude upward from the top portion 614c. The water level adjusting portion 626 includes a wall 630 that narrows the flow path within the seal forming portion 614 . The wall 630 forms a narrowed portion that narrows the lower side of the flow path in the sealing water forming portion 614 . The wall 630 is formed to rise upward from the bottom surface of the top portion 614c of the flow path in the sealing water forming portion 614 when viewed from the front. Note that, for example, the wall 630 may be formed by narrowing the wall itself of the water seal forming portion 614 inward and forming the wall 630 formed to rise upward from the top portion 614c.

The wall 630 extends in the horizontal direction with respect to the main flow direction of water reaching the water level adjusting portion 526, and the wall 630 is formed with a notch 632 extending downward from its upper end 630c. The lateral width A1 of the notch 632 is substantially constant in the vertical direction. The lower portion of the notch 632 is formed by the top portion 614c. The notch 632 extends from the front surface 630a to the rear surface 630b in the front-rear direction.

The amount of water spouted from the water spouting portion 606b in a normal usage mode (the amount of water flowing into the drainage body 10 per unit time), the water that cannot pass through the notch 632 is the water level in the drainage body 610. , forming a flow over the upper edge 630c of the wall 630 portion when the water level exceeds the upper edge 630c. The wall 630 limits the amount of drainage per unit time passing through the notch 632 when the water level is below the upper end 630c, and restricts the flow above the upper end 630c when the water level is above the upper end 630c. It forms a special weir that forms a The amount of drainage per unit time passing through the first area B1 of the notch 632 (the area cut out by the notch 32) (water discharge flow rate) is determined by the width A1 of the notch 632 and the height h1 of the water level (from the top 14c). determined by the actual height of the water level). In addition, the amount of water discharged per unit time passing through the second region B2 (water discharge flow rate) is determined by the width A2 of the flow path of the sealing water forming portion 614 and the height h2 of the water level above the upper end 630c (the actual water level from the upper end 30c). height). The second region B2 is a region above the upper end 30c of the wall 30. As shown in FIG.

When the water level exceeds the upper end 530c, the amount of water spouted from the water spouting portion 6b (the inflow amount per unit time flowing into the drainage body portion 10) cannot pass through the first region B1 of the notch 532. Since the remaining water forms a flow over the upper end 530c of the wall 530 portion, the rise of the water level is suppressed.
When the water level exceeds the upper end 530c, the water level adjustment unit 526 controls the amount of water flowing into the drainage main body 510 per unit time, and the amount of water passing through the first region B1 of the notch 532 per unit time. A second amount of wastewater, which is the sum of the amount of wastewater passing through the second region B2 per unit time, is discharged. The inflow amount per unit time flowing into the drainage main body 510 is the same as the second drainage amount, which is the sum of the amount of drainage per unit time passing through the first region B1 and the amount of drainage per unit time passing through the second region B2. , the water level almost stops rising, and the water level reaches the ultrasonic cleaning water level W2.

The ultrasonic cleaning water level W2 is set to a height higher than the upper end 630c of the wall 630 and lower than the ceiling portion 614e of the sealing water forming portion 614. As shown in FIG. Thus, the ultrasonic cleaning water level W2 is defined by the relationship between the first area B1 and the second area B2.

The water level adjuster 626 is formed so that the ultrasonic cleaning water level W2 is positioned within the mesh basket storage part 612 . More preferably, the water level adjustment part 626 is formed so as to be located below the entrance part 612 a of the mesh basket housing part 612 . Further, the water level adjustment part 626 is formed so that the ultrasonic cleaning water level W2 is positioned below the bottom of the mesh basket 18 arranged in the mesh basket storage part 612 .
Furthermore, the water level adjusting portion 626 is formed so that the ultrasonic cleaning water level W2 is at a position equal to or higher than the dirt trapping portion 628 . Further, the water level adjusting portion 626 is formed so that the ultrasonic cleaning water level W2 is positioned above the inclined portion 634a described later. As a modification, the water level adjustment part 626 can be formed by a means different from the wall 630, such as an electric electromagnetic valve, a flow path adjustment valve, or the like. At this time, based on the fact that the control device 24 has determined that water is to be spouted, the control device 24 closes the electromagnetic valve or the like to raise the water level in the water seal forming portion 614, and the water level reaches the ultrasonic cleaning water level W2. may be controlled to rise to Further, for example, when the water level rises to the ultrasonic cleaning water level W2, the control device 24 performs control such as opening and closing the electromagnetic valve so that the water does not flow back to the washing place floor 604 and/or the bathtub 605 side. A rise in the water level in the water forming part 614 may be suppressed.

Next, the dirt trapping section 628 of the drainage device 601 according to the third embodiment of the present invention will be described.
The dirt trapping portion 628 is shaped to facilitate the adherence of dirt onto the surface as the water level drops along the surface of the dirt trapping portion 628 . Dirt catcher 628 includes a rim 634 that projects inwardly from the side wall of drain body 610 in a stepped manner.

The edge portion 634 is formed in an annular shape and has an inclined portion 634a that slopes downward toward the inside. The sloping portion 634a forms a flat surface that descends inward.

Next, a drainage device according to a fourth embodiment of the present invention will be described with reference to FIGS. 20 to 22. FIG. 4th Embodiment is the example which applied the drainage apparatus by this invention to the bathtub of a bathroom.

Since the drainage device 701 according to the fourth embodiment has a part having substantially the same structure as the drainage device 601 according to the third embodiment described above, the drainage device 601 according to the third embodiment and the first embodiment of the present invention are different. Only different points will be explained, and the same reference numerals will be given to the same parts, and the explanation will be omitted. The operation (action) of the drainage device 701 according to the third embodiment of the present invention is the same as the operation (action) of the drainage device 1 according to the first embodiment, so the explanation is omitted.

A drainage device 701 is provided in a bathtub system 702 . The drainage device 701 further comprises a drainage main body 710 connected to the downstream end of the bottom 705a of the bathtub 705 .

The bathtub-side faucet device 709 is connected on the upstream side to a water supply channel 9 to which water is supplied from a water supply source (not shown) and to a hot water supply channel 11 to which hot water is supplied. The bathtub-side faucet device 709 includes a hot and cold water mixing faucet 6a which is a hot and cold water mixing portion, mixes water from the cold water supply path 9 and hot water from the hot water supply path 11 at the hot and cold water mixing faucet 6a, and discharges the water to the bathtub 705. Water is discharged from the water discharging portion 706b. The water supply channel 9 and the hot water supply channel 11 are connected to the hot and cold water mixing valve 6a, and the water discharge side channel 6c extends from the hot and cold water mixing valve 6a, passes through the flow rate sensor 20 described later, and extends to the water discharge portion 706b. A water discharger 706 b of the bathtub-side faucet device 709 and a water discharger 607 b of the shower faucet device 607 discharge water into the bathtub 705 . The bathtub-side faucet device 709 and the shower faucet device 607 each supply water to the drainage body 710 via the bathtub 705 . The bathtub 705 is formed to discharge water discharged from the bathtub-side faucet device 709 and/or the shower faucet device 607 downstream.

As shown in FIG. 21, the drain body 710 is provided downstream of the bathtub 705 and configured to form a water seal.
The drain body 710 is provided downstream of the bathtub 705 and includes a bathtub drain port 712 that can be cleaned relatively easily, and a seal water forming portion that is provided downstream of the bathtub drain port 712 and forms a seal. 614.
Hereinafter, in the description of the fourth embodiment of the present invention, the upstream side with respect to the main flow direction of water reaching the water level adjustment portion 626 is the front side, and the side opposite to the upstream side is the rear side, and the water level adjustment portion 626 The right side is defined as the right side when viewed from the front, and the left side is defined as the left side when viewed from the front.

The bathtub drain port portion 712 is formed in a size that accommodates the drain plug 713 that opens and closes the bathtub drain port portion 712 and the mesh basket 18 that is a hair catcher. The bathtub drain port part 712 also functions as a mesh basket storage part for storing the mesh basket 18 . Bathtub drain 712 is formed as a relatively easily accessible and maintainable part for the user.
The bathtub drain port portion 712 has an inlet portion 712a that opens to the bathtub 705 side, an intermediate portion 712b in which the drain plug 713 is housed, and a channel diameter that is reduced from the intermediate portion toward the sealing water forming portion 614. and an outlet portion 712c.

An inlet portion 712 a of the bathtub drain port portion 712 is opened in a circular shape and forms a drain port portion of the bathtub 705 . The inlet portion 712a is formed by partially recessing the bottom portion 705a below the bottom surface. The inlet portion 712 a has a flow path diameter larger than that of the water seal forming portion 614 . The intermediate portion 712b is formed in a circular tubular shape. The intermediate portion 712b has a channel diameter larger than that of the inlet of the sealing water forming portion 614. As shown in FIG. An outlet portion 712 c of the bathtub drain port portion 712 is formed at the lower end portion of the bathtub drain port portion 712 . Outlet portion 712c forms an inward flat portion. The outlet portion 712 c is connected to the water seal forming portion 614 . The bathtub drain port part 712 has a channel diameter larger than that of the water seal forming part 614, so that it is easy for the user to visually recognize the inside of the bathtub drain port part 712, and the user can easily insert his/her fingers into the bathtub drain port part 712 to clean it. Here, the bathtub drain portion 712 is configured such that the mesh basket 18 can be removed from the bathtub drain portion 712 by the user in order to dispose of the garbage collected in the mesh basket 18 . Further, the bathtub drain port portion 712 is configured such that the mesh basket 18 after the trash has been thrown away by the user is attached to the bathtub drain port portion 712 . In other words, the bathtub drain port 712 is configured so that the user can relatively easily put his/her fingers into it to perform work such as removal and attachment of the mesh basket 18 . As described above, the bathtub drain port 712 is configured so that the user's finger can be easily inserted therein, so that the user's finger can clean the inside of the bathtub drain port 712 relatively easily. Note that the outlet portion 712c of the bathtub drain port portion 712 may not be formed so as to reduce the flow channel diameter, and furthermore, the flow channel diameter may be reduced by another member on the downstream side.

The mesh basket 18 is arranged inside the intermediate portion 712 b of the bathtub drain port portion 712 . The mesh basket 18 is formed such that its upper end is disposed inside the inlet portion 712a and its upper end substantially matches the inlet portion 712a. Therefore, the mesh basket 18 is formed so as to cover the entire flow path on the lower side of the inlet portion 712a.

Sealing water forming part 614 has a function of draining the water discharged into bathtub 705 and storing part of the water that has flowed therein to form a normal water seal at seal water level W0. The sealing water forming portion 614 of the drainage device 701 is substantially the same as the sealing water forming portion 614 of the drainage device 601 described above, so the same reference numerals are given in the drawings and the description thereof is omitted.

In the drainage device 1, the water level in the drainage main body 710 is further lowered from the sealing water level W0 in the sealing water forming part 614 to the sealing water level W0 in the sealing water forming part 614 by the water flowing into the drainage main body 710. A water level adjustment portion 626, which is a flow rate adjustment portion formed so that the ultrasonic cleaning water level W2 can be easily increased, and a dirt capture portion 728 formed at the bottom of the bathtub drain port portion 712 are provided. The water level adjusting portion 626 of the drainage device 701 is substantially the same as the water level adjusting portion 626 of the drainage device 601 described above, so the same reference numerals are given to the drawings and the description thereof is omitted.

The water level adjusting portion 626 is formed so that the ultrasonic cleaning water level W2 is positioned within the bathtub drain port portion 712 . Also, the water level adjusting portion 626 is formed so as to be positioned below the entrance portion 712 a of the bathtub drain port portion 712 . Further, the water level adjusting portion 626 is formed so that the ultrasonic cleaning water level W2 is positioned below the bottom portion of the mesh basket 18 arranged in the bathtub drain port portion 712 . Furthermore, the water level adjusting portion 626 is formed so that the ultrasonic cleaning water level W2 is at a position equal to or higher than the dirt trapping portion 728 .

Next, the dirt trapping section 728 of the drainage device 701 according to the third embodiment of the present invention will be described.
The dirt trapping portion 728 is shaped to facilitate the adherence of dirt onto the surface as the water level drops along the surface of the dirt trapping portion 728 . The dirt catcher 728 includes an edge 734 that arcs inwardly from the side wall of the drainage body 710 .

Edge 734 is formed in an annular shape and extends inward. Edge 734 may include a ramp that slopes downward toward the inside.

The drainage device 701 further includes a flow rate sensor 20 which is a detection unit for detecting water spouted from the bathtub side faucet device 709 and/or the shower faucet device 707, and an ultrasonic wave to the water in the drainage body 710. and a controller 24 for controlling the operation of the ultrasonic oscillator 722 .

The ultrasonic oscillator 722 is provided below the bathtub drain port portion 712 in the drain body portion 710 . The ultrasonic oscillator 722 is provided at the bottom of the drainage body 710 and arranged to oscillate radio waves upward.

Next, a drainage device according to a fifth embodiment of the present invention will be described with reference to FIG. 5th Embodiment is the example which applied the drainage apparatus by this invention to the washbowl of the faucet apparatus for a washbasin. FIG. 24 is a perspective view of a washbasin faucet device equipped with a drainage device according to a fifth embodiment of the present invention. 25 is a partially enlarged cross-sectional view of the vicinity of the floor surface of the washbowl of the washbasin faucet device as viewed along line XXIV-XXIV of FIG. 24. FIG. In addition, in FIG. 25, for explanation of the internal structure, the internal structure of the flow path, which is not shown in the cross section of the drainage main body, is schematically illustrated by imaginary lines.

Since the drainage device 801 according to the fifth embodiment has a basic structure similar to that of the drainage device 1 according to the first embodiment described above, only the differences from the first embodiment will be described for the fourth embodiment of the present invention. , and similar parts are denoted by the same reference numerals in the drawings, and descriptions thereof are omitted. The operation (action) of the drainage device 801 according to the fourth embodiment of the present invention is the same as the operation (action) of the drainage device 1 according to the first embodiment, so the explanation is omitted.

The drainage device 801 includes a washbowl 804 that is a water receiving portion provided in the washstand 802 , a washbasin faucet device (discharging portion) 806 that is a washbasin faucet that spouts water to the washbowl 804 , and the washbowl 804 . and a drainage body 810 connected to the downstream end of the bottom 804a of the. The washbowl 804 is not limited to a washstand bowl, and includes a washbowl of a size that enables handwashing.

The washbasin faucet device 806 is connected on the upstream side to a water supply channel 9 to which water is supplied from a water supply source (not shown) and to a hot water supply channel 11 to which hot water is supplied. The washbasin faucet device 806 includes a hot and cold water mixing faucet 6a, mixes water from the cold water supply channel 9 and hot water from the hot water supply channel 11, and discharges water from a water discharge portion 806b. The water supply channel 9 and the hot water supply channel 11 are connected to the hot and cold water mixing valve 6a, and the discharge side channel 6c extends from the hot and cold water mixing valve 6a through the flow rate sensor 20, which will be described later, to the water discharging portion 806b. Washbowl 804 is formed to discharge water spouted from washbasin faucet device 806 downstream.

Next, with reference to FIG. 25, the drainage body of the drainage device according to the fifth embodiment of the present invention will be described.
A drain body 810 is provided downstream of the basin 804 and configured to form a water seal. The drain main body 810 is provided downstream of the washbowl 804 and includes a mesh basket storage portion 812 in which a mesh basket is stored, and a water seal that is provided downstream of the mesh basket storage portion 812 and forms a water seal. and a forming portion 814 .
Hereinafter, in the description of the fifth embodiment of the present invention, the upstream side with respect to the main flow direction of water reaching the water level adjustment portion 626 is the front side, the side opposite to the upstream side is the rear side, and the water level adjustment portion 626 The right side is defined as the right side when viewed from the front, and the left side is defined as the left side when viewed from the front.

The mesh basket storage portion 812 is formed to have a size such that a mesh basket 818, which is a hair catcher, can be stored. The mesh basket storage portion 812 has an inlet portion 812a that opens toward the washbowl 804 side, an intermediate portion 812b that stores the mesh basket 818, and an outlet portion that has a reduced flow path diameter from the intermediate portion toward the water sealing forming portion 814. and a portion 812c. An inlet portion 812 a and an intermediate portion 812 b of the mesh basket housing portion 812 have a channel diameter larger than that of the water seal forming portion 814 .

An entrance portion 812 a of the mesh basket housing portion 812 is opened in a circular shape and forms a drain port portion of the washbowl 804 . The inlet portion 812a is formed by partially recessing the bottom portion 804a below the bottom surface. The inlet portion 812 a has a flow path diameter larger than that of the sealing water forming portion 814 . An intermediate portion 812b of the mesh basket housing portion 812 is formed in a circular cylindrical shape so that a mesh basket 818 can be placed therein. The intermediate portion 812b has a channel diameter larger than that of the sealing water forming portion 614. As shown in FIG. An outlet portion 812 c of the mesh basket storage portion 812 is formed at the lower end portion of the mesh basket storage portion 812 . Outlet portion 812c forms an inward flat portion. The outlet portion 812 c is connected to the water seal forming portion 814 . Here, the mesh basket storage portion 812 is configured such that the mesh basket 818 can be removed from the mesh basket storage portion 812 by the user to dispose of the debris that has been collected within the mesh basket 818 . Further, the mesh basket storage portion 812 is configured such that the mesh basket 818 after the user has thrown away the garbage can be attached to the mesh basket storage portion 812 . In other words, the net basket housing portion 812 is configured so that the user can relatively easily insert his or her fingers into the net basket housing portion 812 to perform operations such as removal and attachment of the net basket 818 . In this way, the mesh basket storage portion 812 is configured so that the user's fingers can be easily inserted therein, so that the interior of the mesh basket storage portion 812 can be relatively easily cleaned by the user's fingers. Note that the outlet portion 812c of the mesh basket housing portion 812 may not be formed so that the flow channel diameter is reduced, and furthermore, the flow channel diameter may be reduced by another member on the downstream side.

The water seal forming part 814 has a function of draining the water discharged to the washbowl 804 and storing a part of the water that has flowed in to form a normal water seal at the water seal level W0. .

The sealing water forming part 814 forms a trap-shaped flow path that forms a sealing water at the sealing water level W0. The water sealing forming portion 814 includes a connecting portion 814a connected to an outlet portion 812c of the mesh basket housing portion 812, and an ascending portion 814b which is an ascending flow path that ascends obliquely upward toward the downstream side so as to form a drainage trap. , a top portion 814c, which is a folded portion connecting the rising portion 814b of the drain trap between the rising portion 814b and the falling portion 814d, and a descending flow path provided downstream of the rising portion 814b and descending from the top portion 814c. and a descending portion 814d. Therefore, the sealing water forming portion 814 forms a trap-shaped flow path that folds back from the ascending portion 814b toward the descending portion 814d. The top portion 814c defines the sealing water level W0. The descending portion 814 d extends substantially vertically downward and is connected to the drainage channel 8 . The sealing water forming part 814 forms a channel of a drainage trap as a channel on the side of the drainage channel 8, and the inner diameter of the channel is small, the shape of the channel is complicated, and the depth of the channel is large. By having any of the elements such as depth, or at least some combination of these elements, etc., compared to the mesh basket storage 812, it is more difficult for the user to insert his/her fingers to clean.

In the drainage device 801, the water level in the drainage main body 810 is further lowered from the sealing water level W0 in the sealing water forming part 814 to the sealing water level W0 in the sealing water forming part 814 by the water flowing into the drainage main body 810. Equipped with a water level adjusting portion 826 which is a flow rate adjusting portion formed so that the ultrasonic cleaning water level W2 can be easily increased, and a dirt trapping portion 828 formed at the bottom of the mesh basket housing portion 812.

For example, when the water flowing into the drainage body 810 is at a predetermined flow rate or more, the water level adjustment part 826 adjusts the water level in the drainage body 810 to the level within the sealing water forming part 814 due to the water flowing into the drainage body 810. from the sealing water level W0 in the sealing water forming portion 814 to the ultrasonic cleaning water level W2 higher than the sealing water level W0 in the sealing water forming portion 814. The water level adjusting part 826 is arranged in a sealing water forming part 814 that forms a single flow path from the inlet (connecting part 814a) to the outlet (connecting part with the drainage flow path 8) in the drainage body part 810. Adjust the water level by The water level adjuster 826 adjusts the amount of water discharged to the downstream side when the water level in the drainage body 810 is between the sealing water level W0 and the ultrasonic cleaning water level W2. It is formed so as to be less than the amount of water discharged to the downstream side when reaching W2.

The water level adjusting portion 826 is formed on the top portion 814 c which is a sealing water level regulating portion for regulating the sealing water level of the drainage trap of the sealing water forming portion 814 . More specifically, the water level adjusting portion 826 is formed to protrude upward from the top portion 814c. The water level adjustment portion 826 includes a wall 830 that narrows the flow path within the seal forming portion 814 . The wall 830 forms a narrowed portion that narrows the lower side of the flow path in the sealing water forming portion 814 . The wall 830 is formed to rise upward from the bottom surface of the top portion 814c of the flow path in the sealing water forming portion 814 when viewed from the front. The wall 830 is formed to rise obliquely rearward and upward from the bottom surface of the top portion 814c of the flow path in the sealing water forming portion 814 . Note that, for example, the wall 830 may be formed by narrowing the wall itself of the water seal forming portion 14 inward and forming the wall 830 formed to rise upward from the top portion 814c.

The wall 830 extends in the left-right direction with respect to the main flow direction of water reaching the water level adjusting portion 826, and the wall 830 is formed with a notch 832 extending downward from its upper end 830c. The notch 832 is formed in a concave shape downward from the center of the upper end 830c. The lateral width A1 of the notch 832 is substantially constant in the vertical direction. The lower portion of the notch 832 is formed by the top portion 814c. The notch 832 extends from the front surface 830a to the rear surface 830b in the front-rear direction.

The amount of water discharged from the water discharge portion 6b in a normal usage mode (the amount of water flowing into the drainage body 10 per unit time), the water that cannot pass through the notch 832 is the water level in the drainage body 810. and form a flow above the top 830c when the water level exceeds the top 830c. The wall 830 limits the amount of drainage per unit time passing through the notch 832 when the water level is below the upper end 830c, and restricts the flow above the upper end 830c when the water level is above the upper end 830c. It forms a special weir that forms a The amount of water discharged per unit time passing through the first region B1 of the notch 832 (the region cut out by the notch 832) (the amount of water discharged) is the width A1 of the notch 832 and the height h1 of the water level (from the top 814c). determined by the actual height of the water level). In addition, the amount of water discharged per unit time passing through the second region B2 (water discharge flow rate) is determined by the width A2 of the channel of the sealing water forming portion 814 and the height h2 of the water level above the upper end 830c (the actual water level from the upper end 830c). height). The second region B2 is the region above the upper end 830c of the wall 830. As shown in FIG.

When the water level exceeds the upper end 830c, the amount of water spouted from the water spouting portion 6b (the amount of inflow per unit time flowing into the drainage body portion 10) cannot pass through the first region B1 of the notch 832. Since the remaining water forms a flow over the upper end 830c of the wall 830 portion, the rise of the water level is suppressed.
When the water level exceeds the upper end 830c, the water level adjustment unit 826 adjusts the amount of water flowing through the first region B1 of the notch 832 per unit time to the amount of water flowing into the drainage body 810 per unit time. A second amount of wastewater, which is the sum of the amount of wastewater passing through the second region B2 per unit time, is discharged. The amount of inflow per unit time flowing into the drainage main body 810 is the same as the second amount of waste water, which is the sum of the amount of waste water passing through the first region B1 per unit time and the amount of waste water passing through the second region B2 per unit time. , the water level almost stops rising, and the water level reaches the ultrasonic cleaning water level W2.

The ultrasonic cleaning water level W2 is set to a height higher than the upper end 830c of the wall 830 and lower than the ceiling portion 814e of the sealing water forming portion 814. As shown in FIG. Thus, the ultrasonic cleaning water level W2 is defined by the relationship between the first area B1 and the second area B2.

The water level adjusting portion 826 is formed so that the ultrasonic cleaning water level W2 is positioned within the mesh basket housing portion 812 . More preferably, the water level adjustment part 826 may be formed so as to be located below the entrance part 812 a of the mesh basket housing part 812 . Further, the water level adjustment part 826 is formed so that the ultrasonic cleaning water level W2 is positioned below the bottom of the mesh basket 818 arranged in the mesh basket storage part 812 .
Furthermore, the water level adjusting portion 826 may be formed so that the ultrasonic cleaning water level W2 is at a position equal to or higher than the dirt trapping portion 828 . Furthermore, the water level adjusting portion 826 may be formed so that the ultrasonic cleaning water level W2 is positioned above the inclined portion 834a described later. As a modification, the water level adjustment part 826 can be formed by means different from the wall 830, such as an electrically operated electromagnetic valve, a flow path adjustment valve, or the like. At this time, based on the fact that the control device 24 has determined the start of water spouting, the control device 24 closes the electromagnetic valve or the like to raise the water level in the sealing water forming portion 814 to the ultrasonic cleaning water level W2. may be controlled to rise to Furthermore, for example, when the water level rises to the ultrasonic cleaning water level W2, the control device 24 performs control such as opening and closing the electromagnetic valve so that the water does not flow back to the washbowl 804 side. water level rise may be suppressed.

Next, the dirt trapping section 828 of the drainage device 801 according to the fifth embodiment of the present invention will be described.
The dirt trapping portion 828 is shaped such that dirt tends to adhere to the surface as the water level drops along the surface of the dirt trapping portion 828 . Dirt catcher 828 includes a rim 834 that projects inwardly from the side wall of drain body 810 in a stepped manner.

The edge portion 834 is formed in an annular shape and has a sloped portion 834a that slopes downward toward the inside. The sloping portion 834a forms a flat surface that descends inward.

1 Drainage Device 4 Sink 4a Bottom 4b Bottom 10 Drain Main Body 12 Mesh Basket Storage Part 14 Water Seal Forming Part 18 Mesh Basket 22 Ultrasonic Oscillator 26 Water Level Adjusting Part 30 Wall 30c Upper End 32 Notch 34 Edge 34a Inclined Part 36 Inner Capture Part 126 Water level adjusting part 130 Wall 132 Notch 226 Water level adjusting part 230 Wall 232 Notch 326 Water level adjusting part 330 Wall 332 Notch 426 Water level adjusting part 430 Wall 432 Notch 501 Drainage device 510 Drainage body part 512 Mesh basket storage part 514 Water seal formation part 526 Water level adjustment part 530 Wall 530c Upper end 532 Notch 601 Drainage device 602 Bathroom 604 Washing place floor 604a Bottom part 605 Bathtub 610 Drainage body part 612 Net basket storage part 614 Water seal formation part 626 Water level adjustment part 630 Wall 630c Upper end 632 Notch 634 Edge 634a Slanted portion 701 Drainage device 705 Bathtub 705a Bottom 710 Drainage main body 712 Bathtub drainage port 722 Ultrasonic oscillator 728 Capture unit 734 Edge 801 Drainage device 804 Washbowl 804a Bottom 810 Drainage main body 812 Mesh basket storage Part 814 Water sealing forming part 818 Net basket 826 Water level adjusting part 828 Catching part 830 Wall 830c Upper end 832 Notch 834 Edge 834a Inclined part A1 Width A2 Width B1 First area B2 Second area W0 Sealing water level W2 Ultrasonic cleaning water level

Claims (6)

A drainage device provided at the bottom of a water receiving part that receives water,
a main body portion provided downstream of the water receiving portion, the main body portion including a sealing water forming portion forming a trap-shaped flow path for forming a water sealing;
an ultrasonic oscillator that oscillates ultrasonic waves in the water in the main body;
Water flowing into the main body facilitates raising the water level in the main body from the sealing water level in the sealing water forming part to the ultrasonic cleaning water level higher than the sealing water level in the sealing water forming part. wherein the flow rate adjusting unit adjusts the amount of water discharged downstream per unit time until the water level in the main body reaches the water level from the sealing water level to the ultrasonic cleaning water level. and a drainage device, comprising: the flow rate adjusting section formed so as to be smaller than the amount of drainage per unit time to the downstream side when the water level in the section reaches the ultrasonic cleaning water level. 2. The drainage device according to claim 1, wherein the flow rate adjusting portion includes a wall that narrows the flow path in the sealing water forming portion. The wall of the flow rate adjusting unit is formed to rise upward from a sealing water level regulating portion that defines the sealing water level and extends in the left-right direction with respect to the main water flow direction. is formed with a notch extending downwardly from its upper end. 4. The drainage device according to claim 3, wherein the width of the notch formed in the wall of the flow rate adjusting portion in the horizontal direction is substantially constant in the vertical direction. 4. The drainage device according to claim 3, wherein the width of the notch formed in the wall of the flow rate adjusting portion in the left-right direction increases downward in the vertical direction. Furthermore, a mesh basket provided in the main body and having a mesh,
6. The flow rate adjusting unit according to claim 1, wherein the ultrasonic cleaning water level is positioned below the bottom of the mesh basket arranged in the main body. Drainage device.

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