JP2023034031A - vacuum breaker - Google Patents

Abstract

To suppress occurrence of water leakage.SOLUTION: A vacuum breaker comprises: a body part including a first atmosphere introduction port communicating with a first water passage connecting a first water inlet port and a first water outlet port and a second atmosphere introduction port communicating with a second water passage connecting a second water inlet port and a second water outlet port; and a valve body for opening/closing the first atmosphere introduction port and the second atmosphere introduction port. The valve body closes the first atmosphere introduction port when the first water passage is a water passing state and opens the first atmosphere introduction port when the first water passage is a non-water passing state; and closes the second atmosphere introduction port when the second water passage is a water passing state and opens the second atmosphere introduction port when the second water passage is a non-water passing state. The body part comprises: a water reception part for receiving washing water overflowing from the first atmosphere introduction port and the second atmosphere introduction port; a discharge part for discharging washing water overflowing at the water reception part; and a guide part for guiding washing water overflowing from the first atmosphere introduction port to the second atmosphere introduction port.SELECTED DRAWING: Figure 2

Description

The disclosed embodiments relate to vacuum breakers.

Conventionally, there has been known a vacuum breaker having a water receiver for receiving cleaning water overflowing from an air inlet (see, for example, Patent Document 1). Washing water overflowing into the water receiving portion is discharged from the water receiving portion to the water storage tank through the drain port.

JP 2014-190489 A

However, when the wash water overflowing into the water receiving portion is discharged from the discharge port, the wash water may overflow from the water receiving portion and leak.

One aspect of the embodiments aims to suppress the occurrence of water leakage.

A vacuum breaker according to one aspect of an embodiment connects a first air inlet that communicates with a first water passage that connects a first water inlet and a first water outlet, and a second water inlet and a second water outlet. and a valve element for opening and closing the first atmosphere introduction port and the second atmosphere introduction port. The valve body closes the first atmosphere introduction port when the first water passage is in a water-conducting state, and opens the first atmosphere introduction port when the first water passage is in a non-water-conducting state. and closing the second atmosphere introduction port when the second water conduit is in a water-conducting state, and opening the second atmosphere introduction port when the second water conduit is in a non-water-conducting state. The main body includes a water receiving portion for receiving wash water overflowing from the first atmosphere introduction port and the second atmosphere introduction port, a discharge portion for discharging wash water overflowing the water receiving portion, and the first atmosphere introduction. and a guiding part for guiding the wash water overflowing from the mouth to the second atmosphere introduction port.

As a result, the vacuum breaker can discharge the cleaning water overflowing from the first atmosphere introduction port from the second atmosphere introduction port. Therefore, the vacuum breaker can prevent the wash water overflowing the water receiving portion from overflowing the water receiving portion, thereby suppressing the occurrence of water leakage.

The valve body includes a first valve body that opens and closes the first atmosphere introduction port, and a second valve body that opens and closes the second atmosphere introduction port.

Thereby, the vacuum breaker can open and close the first atmosphere introduction port and the second atmosphere introduction port by each valve element.

The guide portion is a wall portion protruding from the bottom surface of the water receiving portion. The wall portion is provided so as to surround the first atmosphere introduction port, and has an opening formed on the second atmosphere introduction port side.

As a result, the vacuum breaker can prevent the wash water overflowing from the first atmosphere introduction port from flowing to the discharge part, and guide the wash water overflowing from the first atmosphere introduction port to the second atmosphere introduction port.

The height of the wall portion is lower than the height of the outer peripheral wall portion of the water receiving portion.

As a result, when the flow rate per unit time of the cleaning water overflowing from the first atmosphere introduction port is large, the vacuum breaker causes part of the cleaning water overflowing from the first atmosphere introduction port to climb over the wall and flow to the discharge section. It can be flowed toward and discharged from the discharge port of the discharge part. In addition, even when the washing water overflows from the first atmosphere introduction port and the second atmosphere introduction port, the vacuum breaker can discharge it from the discharge port of the discharge unit. In addition, the vacuum breaker can prevent the cover attached above the main body from being pushed up by the wash water overflowing from the first atmosphere introduction port, for example, thereby suppressing the occurrence of water leakage from the vacuum breaker.

The height of the bottom surface of the main body where the second air introduction port is formed is lower than the height of the bottom surface of the main body where the first air introduction port is formed.

As a result, the vacuum breaker can prevent the wash water overflowing from the second atmosphere introduction port from flowing toward the first atmosphere introduction port.

The discharge part discharges the wash water overflowing the water receiving part to the flow path on the side of the first water outlet.

As a result, the vacuum breaker can store the wash water overflowing the water receiver in the tank.

The discharge part discharges the wash water overflowing the water receiving part to a tank that stores the wash water flowing out from the first water outlet.

As a result, the vacuum breaker can store the wash water overflowing the water receiver in the tank.

The second water passage is connected to the rim-side water supply passage.

As a result, the vacuum breaker can discharge the overflowing cleansing water from the rim spout to the bowl portion when cleansing water overflows from the first atmosphere inlet. Therefore, the vacuum breaker can suppress insufficient overflow in the tank, and can suppress the occurrence of water leakage.

According to one aspect of the embodiment, occurrence of water leakage can be suppressed.

FIG. 1 is an overall configuration diagram showing a flush toilet provided with a flush water supply device according to an embodiment. FIG. 2 is a perspective view around a vacuum breaker in the cleaning water supply device. FIG. 3 is a plan view around a vacuum breaker in the cleaning water supply device. FIG. 4 is a schematic diagram in the IV-IV section of FIG. FIG. 5 is a diagram for explaining the flow of washing water overflowing from the first air inlet. FIG. 6 is a diagram for explaining the flow of washing water overflowing from the second air inlet. FIG. 7 is a diagram for explaining the flow of cleansing water when the flow rate of cleansing water overflowing from the first air inlet is large.

Hereinafter, embodiments of the vacuum breaker disclosed in the present application will be described in detail with reference to the accompanying drawings. In addition, this invention is not limited by embodiment shown below. Also, it should be noted that the drawings are schematic, and the relationship of dimensions of each element, the ratio of each element, and the like may differ from reality. Even between the drawings, there are cases where portions with different dimensional relationships and ratios are included.

<Structure of flush toilet provided with flush water supply device>
First, the configuration of a flush toilet 100 including the flush water supply device 1 will be described with reference to FIG. FIG. 1 is an overall configuration diagram showing a flush toilet 100 including a flush water supply device 1 according to an embodiment.

As shown in FIG. 1, the flush toilet 100 includes, for example, a toilet body 200 that is placed on the floor of a toilet room, and a cleaning device that is disposed behind the toilet body 200 and supplies flush water to the toilet body 200 . A water supply device 1 is provided.

Toilet bowl body 200 includes a bowl portion 210 for receiving waste and a drain trap line 220 extending rearwardly from the bottom of bowl portion 210 . The bowl portion 210 is formed with a rim spout 212 for spouting rim water and a jet spout 214 for spouting jet water. The rim spout 212 is formed in the upper rear portion of the bowl portion 210 and spouts cleansing water along the upper edge of the bowl portion 210 .

A jet spout 214 is formed at the bottom of the bowl portion 210 and spouts wash water toward the drain trap line 220 . By ejecting cleansing water from the jet water outlet 214, the inside of the drainage trap pipe line 220 can be rapidly filled with cleansing water, and the siphon action can be generated early. The drain trap line 220 forms a water seal and communicates with a sewage pipe (not shown).

The cleansing water supply apparatus 1 includes a valve unit 600 controlled by a control unit (not shown), a tank 800 provided downstream of the valve unit 600 to store cleansing water, and a tank 800 provided downstream of the tank 800 to pressurize the cleansing water. A pressure pump 900 is provided.

The upstream side of the valve unit 600 is connected with a water supply passage 310 for supplying cleaning water from a water supply source (not shown). A rim-side water supply passage 320 for supplying wash water to the rim spout 212 and a tank-side water supply passage 330 for supplying wash water to the tank 800 are connected to the downstream side of the valve unit 600 .

The valve unit 600 includes a constant flow valve 620, a diaphragm-type water supply valve 640 provided downstream of the constant flow valve 620, a switching valve 660 provided downstream of the water supply valve 640, and a vacuum valve provided downstream of the switching valve 660. and a breaker 680 .

The constant flow valve 620 maintains a constant flow rate of washing water that flows downstream from the water supply path 310 into the constant flow valve 620 . The water supply valve 640 includes, for example, a diaphragm, and by opening and closing the water supply valve 640 switches between spouting and stopping cleansing water from the rim spout 212 and the jet spout 214 .

The switching valve 660 switches the flush water supply destination from the water supply source, for example, between the rim spout 212 of the toilet body 200 and the tank 800 . That is, the switching valve 660 supplies wash water toward the rim-side water supply passage 320 or the tank-side water supply passage 330 .

A vacuum breaker 680 prevents backflow of wash water. A specific configuration of the vacuum breaker 680 will be described later. In vacuum breaker 680, cleaning water may overflow into water receiving portion 686 due to malfunction of valve body 683, but the cleaning water overflowing into water receiving portion 686 is collected by water receiving portion 686. , for example, via discharge 687 into tank 800 . The discharge of the wash water overflowing the water receiving portion 686 will be described later.

The tank 800 stores flush water supplied to the jet spout 214 of the toilet body 200 . A pump-side water supply passage 340 is connected to the lower portion of the tank 800 , and a pressure pump 900 is connected to the downstream end of the pump-side water supply passage 340 .

Also, an overflow channel 342 is connected to the top of the tank 800 . The overflow channel 342 causes the flush water to flow out to the toilet body 200 when flush water of a specified water level WL or higher is supplied in the tank 800, for example. Specifically, the overflow flow path 342 causes flush water that has reached the specified water level WL or higher to flow out to the jet water outlet 214 of the toilet body 200 via the jet-side water supply path 350 without passing through the pressure pump 900 .

The pressurizing pump 900 is connected to the jet water outlet 214 via the jet-side water supply path 350 , pressurizes the wash water stored in the tank 800 , and supplies it to the jet water outlet 214 via the jet-side water supply path 350 .

<Structure of vacuum breaker>
Next, a specific configuration of the vacuum breaker 680 according to the embodiment will be described with reference to FIGS. 2 to 4. FIG. FIG. 2 is a perspective view around the vacuum breaker 680 in the cleaning water supply apparatus 1. FIG. FIG. 3 is a plan view around the vacuum breaker 680 in the cleaning water supply apparatus 1. FIG. FIG. 4 is a schematic diagram in the IV-IV section of FIG. FIG. 3 shows vacuum breaker 680 with cover 682 removed.

The vacuum breaker 680 includes a body portion 681 , a cover 682 and a valve body 683 . The body portion 681 includes a water passage portion 685 , a water receiving portion 686 , a discharge portion 687 and a guide portion 688 . The body portion 681 is formed with a first atmosphere introduction port 690a and a second atmosphere introduction port 690b.

The water passage portion 685 is formed with a first water passage 691a and a second water passage 691b. The first water passage 691 a is a passage that connects one outlet of the switching valve 660 and the tank-side water supply passage 330 . Specifically, the first water passage 691 a has a first water inlet 692 a into which wash water flows from one outlet of the switching valve 660 and a first water outlet 693 a through which the wash water flows out to the tank-side water supply passage 330 . to connect.

The second water passage 691 b is a passage that connects the other outlet of the switching valve 660 and the rim-side water supply passage 320 . Specifically, the second water passage 691b has a second water inlet 692b into which cleansing water flows from the other outlet of the switching valve 660, and a second water outlet 693b from which cleansing water flows out to the rim-side water supply channel 320. to connect.

The water passage portion 685 is formed with a first hole 695a communicating with the first water passage 691a and a second hole 695b communicating with the second water passage 691b. A first hole 695 a and a second hole 695 b are formed above the water passage portion 685 . A first projecting portion 696a of the water receiving portion 686 is inserted into the first hole 695a. The second projecting portion 696b of the water receiving portion 686 is inserted into the second hole 695b.

The water receiving portion 686 is provided above the water passing portion 685 . An upper end of the water receiving portion 686 is open and a cover 682 is attached thereto.

The water receiving portion 686 includes a first projecting portion 696a and a second projecting portion 696b. The first projecting portion 696a projects downward from the lower surface of the water receiving portion 686 . A first atmosphere introduction port 690a is formed in the first protrusion 696a. The first atmosphere introduction port 690a is formed to penetrate the first projecting portion 696a in the vertical direction. That is, the first air introduction port 690a is formed to penetrate the bottom portion 697 of the water receiving portion 686 in the vertical direction. The first atmosphere introduction port 690a communicates with the first water passage 691a.

The second projecting portion 696b projects downward from the lower surface of the water receiving portion 686 . A second atmosphere introduction port 690b is formed in the second protrusion 696b. The second air introduction port 690b is formed to vertically penetrate the second projecting portion 696b. That is, the second air introduction port 690b is formed to penetrate the bottom portion 697 of the water receiving portion 686 in the vertical direction. The second atmosphere introduction port 690b communicates with the second water passage 691b.

A bottom portion 697 of the water receiving portion 686 includes multiple regions of varying heights. Specifically, the bottom portion 697 of the water receiving portion 686 includes a first bottom portion 697a, a second bottom portion 697b, a third bottom portion 697c, and a fourth bottom portion 697d.

The first bottom portion 697a has the highest bottom surface height among the bottom portions 697, and the first atmosphere introduction port 690a is formed thereon. The bottom surface of the second bottom portion 697b is lower than the bottom surface of the first bottom portion 697a. A second atmosphere introduction port 690b is formed in the second bottom portion 697b. The bottom surface of the third bottom portion 697c is lower than the bottom surface of the second bottom portion 697b. The bottom surface of the fourth bottom portion 697d is lower in height than the third bottom portion 697c. In other words, the height of the bottom surface decreases in the order of the first bottom portion 697a, the second bottom portion 697b, the third bottom portion 697c, and the fourth bottom portion 697d. A discharge portion 687 is provided on the fourth bottom portion 697d. The bottom surface of the third bottom portion 697c may be the same height as the bottom surface of the second bottom portion 697b.

The water receiver 686 receives wash water overflowing from the first atmosphere introduction port 690a and the second atmosphere introduction port 690b. An outer peripheral wall portion 698 is formed around the periphery of the water receiving portion 686 .

The guiding part 688 guides the wash water overflowing from the first atmosphere introduction port 690a to the second atmosphere introduction port 690b. The guide portion 688 is a wall portion that protrudes upward from the bottom surface of the water receiving portion 686 . In the following description, the guiding portion 688 is referred to as a "wall portion 688". The wall portion 688 is provided inside the outer peripheral wall portion 698 . The wall portion 688 guides the wash water overflowing from the first atmosphere introduction port 690a to the second atmosphere introduction port 690b. The wall portion 688 is provided so as to surround the first atmosphere introduction port 690a. The wall portion 688 protrudes upward from the peripheral edge of the first bottom portion 697a.

Wall portion 688 includes a first wall portion 688a and a second wall portion 688b. The second wall portion 688b is lower in height than the first wall portion 688a. The second wall portion 688b is provided closer to the discharge portion 687 than the first wall portion 688a, or closer to the second atmosphere inlet 690b than the first wall portion 688a.

The wall portion 688 is formed with an opening 688c. The opening 688c is provided on the side of the second atmosphere introduction port 690b. The opening 688c is formed by discontinuing the wall 688 around the second atmosphere introduction port 690b, and opens toward the second atmosphere introduction port 690b. For example, the opening 688c is formed by not connecting the end of the first wall 688a on the side of the second air inlet 690b and the end of the second wall 688b on the side of the second air inlet 690b. .

The height of the wall portion 688 is lower than the height of the outer peripheral wall portion 698 . Specifically, the height of the wall portion 688 is lower than the height of the outer peripheral wall portion 698 that protrudes upward from the first bottom portion 697a, the second bottom portion 697b, and the third bottom portion 697c.

The discharge portion 687 discharges the wash water overflowing the water receiving portion 686 . The discharge portion 687 discharges the wash water overflowing the water receiving portion 686 to the tank 800 . Specifically, the discharge portion 687 discharges the wash water overflowing the water receiving portion 686 to the tank joint 702 . The tank joint 702 is provided above the tank 800 and allows the wash water discharged from the water receiving portion 686 to flow into the tank 800 .

The discharge portion 687 protrudes downward from the fourth bottom portion 697d of the water receiving portion 686 . The discharge portion 687 is formed with a discharge port 687a. The discharge port 687a is formed along the vertical direction. The outlet 687a is formed to penetrate the fourth bottom portion 697d of the water receiving portion 686. As shown in FIG.

The valve body 683 opens and closes the first atmosphere introduction port 690a and the second atmosphere introduction port 690b to change the state of communication between the first water passage 691a and the outside and the state of communication between the second water passage 691b and the outside. switch. The valve body 683 includes a first valve body 683a and a second valve body 683b.

The first valve body 683a moves up and down due to the water pressure of the wash water flowing through the first water passage 691a. When wash water flows through the first water passage 691a, that is, the tank-side water supply passage 330, and the water is flowing, the first valve body 683a rises due to the water pressure of the wash water and reaches the lower end of the first projecting portion 696a. take a seat. As a result, the first valve body 683a closes the lower end of the first atmosphere introduction port 690a to close the first atmosphere introduction port 690a. The first valve body 683a closes the first atmosphere introduction port 690a to prevent communication between the first water passage 691a and the outside when the first water passage 691a is in a state of water flow.

When the first water passage 691a is in a water non-conducting state, the first valve body 683a descends due to its own weight, separates from the lower end of the first projecting portion 696a, and opens the lower end of the first air inlet 690a. , open the first atmosphere inlet 690a. When the first water passage 691a is in a water-non-conducting state, the first valve body 683a opens the first atmosphere introduction port 690a to allow communication between the first water passage 691a and the outside, thereby introducing external air into the first water passage. It is introduced into the water passage 691a. This prevents the inside of the first water passage 691a from becoming negative pressure, and prevents the wash water from flowing back in the first water passage 691a, that is, the tank-side water supply passage 330. FIG.

The second valve body 683b moves up and down due to the water pressure of the wash water flowing through the second water passage 691b. When wash water flows through the second water passage 691b, that is, the rim-side water supply passage 320, the second valve body 683b rises due to the water pressure of the wash water and reaches the lower end of the second projecting portion 696b. take a seat. As a result, the second valve body 683b closes the lower end of the second atmosphere introduction port 690b to close the second atmosphere introduction port 690b. The second valve body 683b closes the second atmosphere introduction port 690b to prevent communication between the second water passage 691b and the outside when the second water passage 691b is in the water passing state.

When the second water passage 691b is in a water-non-permeable state, the second valve body 683b descends due to its own weight, separates from the lower end of the second projecting portion 696b, and opens the lower end of the second air inlet 690b. , open the second air inlet 690b. The second valve body 683b opens the second atmosphere introduction port 690b to communicate the second water passage 691b with the outside when the second water passage 691b is in a water non-conducting state, thereby introducing external air into the second air passage. It is introduced into the water passage 691b. This prevents the inside of the second water passage 691b from becoming negative pressure, and prevents the wash water from flowing backward in the second water passage 691b, that is, in the rim-side water supply passage 320. FIG.

<Discharge of washing water overflowing to the water receiving part>
In the vacuum breaker 680, the first valve body 683a and the second valve body 683b move up and down according to the state of the wash water in the first water passage 691a and the second water passage 691b. When wash water is flowing through each water passage, the first atmosphere introduction port 690a and the second atmosphere introduction port 690b are closed by the first valve body 683a and the second valve body 683b, respectively.

However, when the first water passage 691a (the tank-side water supply passage 330) is in the water-passing state, for example, dust may be caught between the first valve body 683a and the lower end of the first projecting portion 696a. In such a case, malfunction of the first valve body 683a may occur, and the first atmosphere introduction port 690a may not be blocked by the first valve body 683a.

In such a case, the wash water flows from the first water passage 691a to the first atmosphere introduction port 690a, and the wash water overflows from the first atmosphere introduction port 690a to the water receiving portion 686. FIG.

As shown in FIG. 5, the wash water overflowing from the first atmosphere introduction port 690a into the water receiving portion 686 is guided by the wall portion 688 toward the second atmosphere introduction port 690b. FIG. 5 is a diagram for explaining the flow of wash water overflowing from the first atmosphere introduction port 690a.

When the second water passage 691b is in a water-non-conducting state, the second atmosphere introduction port 690b is open, so that the wash water flowing into the second atmosphere introduction port 690b flows through the second atmosphere introduction port 690b. It flows into the rim-side water supply channel 320 via the water channel 691b. The cleansing water that has flowed into the second atmosphere inlet 690b is discharged from the rim spout 212 into the bowl portion 210 .

For example, if the wash water overflowing the water receiving portion 686 is drained into the tank 800 while water is being supplied to the tank 800, there is a risk that insufficient overflow will occur in the tank 800, and water leakage may occur. The vacuum breaker 680 directs the wash water overflowing from the first atmosphere introduction port 690a communicating with the first water passage 691a (the tank-side water supply passage 330) from the second atmosphere introduction port 690b to the bowl portion 210 via the rim water discharge port 212. Discharge.

As a result, when the wash water overflows from the first atmosphere inlet port 690a, the vacuum breaker 680 discharges the overflowing wash water from the rim spout 212 to the bowl portion 210, suppresses insufficient overflow in the tank 800, and causes water leakage. suppress

Also, when the second water passage 691b is in a water-flowing state, for example, dust may be caught between the second valve body 683b and the lower end of the second projecting portion 696b. In such a case, malfunction of the second valve body 683b occurs, and the second valve body 683b may not be able to close the second atmosphere introduction port 690b.

As shown in FIG. 6, the wash water overflowing from the second atmosphere inlet 690b into the water receiving portion 686 flows along the second bottom portion 697b, the third bottom portion 697c, and the fourth bottom portion 697d to the discharge port 687a of the discharge portion 687. flow toward The wash water overflowing from the second atmosphere inlet 690b into the water receiving portion 686 is discharged from the discharge port 687a of the discharge portion 687 into the tank 800 via the tank joint 702 and stored in the tank 800 . FIG. 6 is a diagram for explaining the flow of wash water overflowing from the second atmosphere introduction port 690b.

When the flow rate of wash water per unit time overflowing from the first atmosphere introduction port 690a to the water receiver 686 is large, as shown in FIG. flow. Part of the cleansing water that has flowed around the second atmosphere introduction port 690b flows from the second atmosphere introduction port 690b into the second water passage 691b and is discharged from the rim spout 212 into the bowl portion 210 . FIG. 7 is a diagram for explaining the flow of cleansing water when the flow rate of cleansing water overflowing from the first atmosphere introduction port 690a is large.

When the flow rate of wash water per unit time overflowing from the first atmosphere introduction port 690a to the water receiving portion 686 is large, part of the wash water that has flowed around the second atmosphere introduction port 690b flows into the second atmosphere introduction port. 690b cannot flow. The wash water that does not flow into the second air inlet 690b is discharged from the outlet 687a of the outlet 687 along the second bottom 697b, the third bottom 697c, and the fourth bottom 697d to the tank 800 via the tank joint 702. be done. Furthermore, part of the wash water overflowing from the first air inlet port 690a climbs over the second wall portion 688b, flows toward the fourth bottom portion 697d, and flows from the discharge port 687a of the discharge portion 687 through the tank joint 702. It is discharged into tank 800 .

When washing water overflows from the first atmosphere introduction port 690a and the second atmosphere introduction port 690b, the washing water overflowing from the first atmosphere introduction port 690a flows toward the second atmosphere introduction port 690b. The wash water overflowing from the first atmosphere introduction port 690a is discharged from the discharge port 687a of the discharge portion 687 into the tank 800 through the tank joint 702 together with the wash water overflowing from the second atmosphere introduction port 690b. In addition, when the flow rate of wash water per unit time overflowing from the first atmosphere introduction port 690a to the water receiving portion 686 is large, part of the wash water overflowing from the first atmosphere introduction port 690a flows through the second wall portion 688b. It climbs over and flows toward the fourth bottom portion 697d. A portion of the wash water overflowing from the first air inlet port 690 a is discharged from the discharge port 687 a of the discharge portion 687 to the tank 800 via the tank joint 702 .

The supply destination of the cleansing water from the water supply source is switched by the switching valve 660 to the rim side water supply channel 320 or the tank side water supply channel 330, but immediately after switching by the switching valve 660, the rim side water supply channel 320 and the tank side water supply Channel 330 may become water-permeable. In such a case, the washing water may overflow from the first atmosphere introduction port 690a and the second atmosphere introduction port 690b as described above. Even in such a case, the vacuum breaker 680 can discharge the wash water overflowing from the first atmosphere introduction port 690a and the second atmosphere introduction port 690b from the discharge port 687a to the tank 800 via the tank joint 702. can.

<effect>
The vacuum breaker 680 has a body portion 681 and a valve body 683 . The body portion 681 has a first atmosphere introduction port 690a and a second atmosphere introduction port 690b. The first atmosphere introduction port 690a communicates with a first water passage 691a that connects the first water inlet 692a and the first water outlet 693a. The second air inlet 690b communicates with a second water passage 691b that connects the second water inlet 692b and the second water outlet 693b. The valve body 683 opens and closes the first atmosphere introduction port 690a and the second atmosphere introduction port 690b. The valve body 683 closes the first atmosphere introduction port 690a when the first water conduit 691a is in a water-conducting state, and closes the first atmosphere introduction port 690a when the first water conduit 691a is in a non-conducting state. open. The valve body 683 closes the second atmosphere introduction port 690b when the second water passage 691b is in a water-passing state, and opens the second atmosphere introduction port 690b when the second water passage 691b is in a non-water-passing state. . The body portion 681 includes a water receiving portion 686 , a discharge portion 687 and a guide portion 688 . The water receiver 686 receives wash water overflowing from the first atmosphere introduction port 690a and the second atmosphere introduction port 690b. The discharge portion 687 discharges the wash water overflowing the water receiving portion 686 . The guiding portion 688 guides the wash water overflowing from the first atmosphere introduction port 690a to the second atmosphere introduction port 690b.

As a result, the vacuum breaker 680 can discharge the cleaning water overflowing from the first atmosphere introduction port 690a from the second atmosphere introduction port 690b. Therefore, the vacuum breaker 680 can prevent the wash water overflowing the water receiving portion 686 from overflowing from the water receiving portion 686, thereby suppressing the occurrence of water leakage.

The valve body 683 includes a first valve body 683a and a second valve body 683b. The first valve body 683a opens and closes the first atmosphere introduction port 690a. The second valve body 683b opens and closes the second atmosphere introduction port 690b.

Thereby, the vacuum breaker 680 can open and close the first atmosphere introduction port 690a and the second atmosphere introduction port 690b by the valve bodies 683, respectively.

The guiding portion 688 is a wall portion 688 protruding from the bottom surface of the water receiving portion 686 . The wall portion 688 is provided so as to surround the first atmosphere introduction port 690a, and an opening portion 688c is formed on the second atmosphere introduction port 690b side.

As a result, the vacuum breaker 680 prevents the wash water overflowing from the first atmosphere introduction port 690a from flowing to the discharge portion 687, and guides the wash water overflowing from the first atmosphere introduction port 690a to the second atmosphere introduction port 690b. be able to.

The height of the wall portion 688 is lower than the height of the outer peripheral wall portion 698 of the water receiving portion 686 .

As a result, when the flow rate per unit time of the cleaning water overflowing from the first atmosphere introduction port 690a is high, the vacuum breaker 680 causes part of the cleaning water overflowing from the first atmosphere introduction port 690a to climb over the wall portion 688. to flow toward the discharge portion 687 and discharged from the discharge port 687 a of the discharge portion 687 . In addition, the vacuum breaker 680 can discharge the cleaning water from the discharge port 687a of the discharge portion 687 even when the cleaning water overflows from the first atmosphere introduction port 690a and the second atmosphere introduction port 690b. In addition, the vacuum breaker 680 can prevent the cover 682 from being pushed up by the wash water overflowing from the first air introduction port 690a, for example, so that water leakage from the vacuum breaker 680 can be suppressed.

The height of the bottom surface of the main body portion 681 where the second air introduction port 690b is formed is lower than the height of the bottom surface of the main body portion 681 where the first air introduction port 690a is formed.

As a result, the vacuum breaker 680 can prevent the wash water overflowing from the second atmosphere introduction port 690b from flowing toward the first atmosphere introduction port 690a.

The second water passage 691 b is connected to the rim-side water supply passage 320 .

As a result, the vacuum breaker 680 can discharge the overflowing cleansing water from the rim spout 212 to the bowl portion 210 when the cleansing water overflows from the first atmosphere inlet 690a. Therefore, the vacuum breaker 680 can suppress insufficient overflow in the tank 800, and can suppress the occurrence of water leakage.

<Modification>
Alternatively, the vacuum breaker 680 may tilt the first bottom portion 697a of the water receiving portion 686 as the guide portion 688 that guides the wash water overflowing from the first atmosphere introduction port 690a to the second atmosphere introduction port 690b. In this case, the first bottom portion 697a of the water receiving portion 686 slopes downward toward the second atmospheric air introduction port 690b. Also, the guide portion 688 may be a groove formed in the first bottom portion 697a. The groove is formed so as to flow the wash water overflowing from the first atmosphere introduction port 690a toward the second atmosphere introduction port 690b. The guiding portion 688 may be a combination of two or more of the wall portion 688, the inclination of the first bottom portion 697a, and the groove formed in the first bottom portion 697a.

In the vacuum breaker 680 according to the modification, the first bottom portion 697a of the water receiving portion 686 and the second bottom portion 697b of the water receiving portion 686 may have the same height. As a result, the vacuum breaker 680 can flow part of the wash water overflowing from the second atmosphere introduction port 690b to the tank-side water supply path 330 via the first atmosphere introduction port 690a. Therefore, for example, when the flow rate per unit time of the wash water overflowing from the second atmosphere introduction port 690b is high, part of the wash water overflowing from the second atmosphere introduction port 690b can be discharged from the first atmosphere introduction port 690a. can be done. Therefore, when the flow rate per unit time of the cleaning water overflowing from the second atmosphere introduction port 690b is large, the vacuum breaker 680 can increase the amount of drainage from the water receiver 686. For example, the main body 681 and the cover 682 It is possible to suppress the washing water from overflowing from between.

The vacuum breaker 680 according to the modification may discharge the wash water overflowing the water receiving portion 686 to the flow path on the first water outlet 693 a side, for example, the tank side water supply path 330 . As a result, the vacuum breaker 680 can store the wash water overflowing the water receiving portion 686 in the tank 800 .

Further effects and modifications can be easily derived by those skilled in the art. Therefore, the broader aspects of the invention are not limited to the specific details and representative embodiments so shown and described. Accordingly, various changes may be made without departing from the spirit or scope of the general inventive concept defined by the appended claims and equivalents thereof.

1 washing water supply device 210 bowl portion 320 rim side water supply passage 330 tank side water supply passage 600 valve unit 660 switching valve 680 vacuum breaker 681 body portion 682 cover 683 valve body 683a first valve body 683b second valve body 685 water passage portion 686 Water receiving portion 687 Discharge portion 687a Discharge port 688 Guide portion (wall portion)
690a First air inlet 690b Second air inlet 691a First water passage 691b Second water passage 692a First water inlet 692b Second water inlet 693a First water outlet 693b Second water outlet 697 Bottom 697a First bottom 697b 2 bottom portion 697c 3rd bottom portion 697d 4th bottom portion 698 outer peripheral wall portion 702 tank joint 800 tank

Claims (8)

A first atmosphere inlet communicating with a first water passage connecting a first water inlet and a first water outlet, and a second atmosphere communicating with a second water passage connecting a second water inlet and a second water outlet. a main body having an inlet;
a valve element that opens and closes the first atmosphere introduction port and the second atmosphere introduction port;
with
The valve body
Closing the first atmosphere introduction port when the first water passage is in a water-conducting state, and opening the first atmosphere introduction port when the first water passage is in a non-water-conducting state;
closing the second atmosphere introduction port when the second water conduit is in a water-conducting state, and opening the second atmosphere introduction port when the second water conduit is in a non-water-conducting state;
The main body is
a water receiver for receiving wash water overflowing from the first atmosphere introduction port and the second atmosphere introduction port;
a discharge part for discharging the wash water overflowing the water receiving part;
A vacuum breaker, comprising: a guide section that guides wash water overflowing from the first atmosphere introduction port to the second atmosphere introduction port. The valve body
a first valve body that opens and closes the first atmosphere introduction port;
2. The vacuum breaker according to claim 1, further comprising a second valve body that opens and closes said second atmosphere introduction port. The guide portion is a wall portion protruding from the bottom surface of the water receiving portion,
3. The vacuum breaker according to claim 1, wherein said wall portion is provided so as to surround said first atmosphere introduction port and has an opening formed on said second atmosphere introduction port side. 4. The vacuum breaker according to claim 3, wherein the height of the wall portion is lower than the height of the outer peripheral wall portion of the water receiving portion. 5. The height of the bottom surface of the main body where the second air introduction port is formed is lower than the height of the bottom surface of the main body where the first air introduction port is formed. vacuum breaker as described in The vacuum breaker according to any one of claims 1 to 5, wherein the discharge section discharges the wash water overflowing the water receiving section to the flow path on the first water outlet side. The vacuum breaker according to any one of claims 1 to 6, wherein said discharge section discharges wash water overflowing said water receiving section to a tank for storing wash water flowing out from said first water outlet. The vacuum breaker according to any one of claims 1 to 7, wherein said second water passage is connected to a rim-side water supply passage.

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