JP2016141965A - Vacuum breaker, and sewage flowing unit provided with the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vacuum breaker that enhances degree of freedom of installation.SOLUTION: A vacuum breaker includes: a body part 41 having a first flow channel R1 extending in a vertical direction, a second flow channel R2 extending in a direction intersecting with the first flow channel R1, and an opening 432 formed above the first flow channel R1; a flow channel switching member 44 movable between a first position and a second position, the first position connecting the first flow channel R1 with the second flow channel R2 and closing the opening 432, and the second position opening the first flow channel R1 to the atmosphere through the opening 432; a holding member 45 holding the flow channel switching member 44 movably between the first position and the second position; a lead-out port 466 leading overflowing water outside through a gap between the flow channel switching member 44 and the opening 432; and an overflowing water lead-out member 46 fitted on the body part 41 or the holding member 45, to be rotatable around the body part 41.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a vacuum breaker and a filth distribution unit comprising the same.

  People who have a functional disorder in their organs due to rectal cancer, bladder cancer, or an accident, and who have artificially constructed a stoma for excretion in the abdomen (excretion port built in the abdomen) are generally ostomate be called. For ostomate, there are various difficulties in daily excretion. In recent years, waste logistics units that allow ostomates to smoothly drain feces and other waste collected in pouches (bags that receive stool and urine from the stoma) and wash the stoma are installed in multipurpose rooms in public facilities. It has been installed.

  The above-mentioned dirty logistics unit or the like generally includes a water discharge pipe with a hose and a wash bowl portion that receives water discharged from the water discharge pipe, and the water discharge pipe with a hose is configured to be drawable. The

  By the way, when piping work is performed in the upstream flow path of the water supply, the upstream flow path of the water supply may become negative pressure. In this case, if the water discharge pipe with hose is submerged in the water accumulated in the wash bowl, the water accumulated in the wash bowl may flow back to the upstream flow path of the water supply through the water discharge port and hose of the water discharge pipe. was there. Therefore, in order to prevent the water accumulated in the wash bowl portion from flowing back into the upstream flow path of the water supply through the water outlet and hose of the water discharge pipe when the upstream flow path of the water supply becomes negative pressure, A technique of providing a vacuum breaker in the flow path is known (for example, see Patent Document 1).

  A conventional vacuum breaker supplies water to the water outlet side with water pressure when water is supplied, and opens the upstream flow channel to the atmosphere in order to eliminate the negative pressure when the upstream flow channel becomes negative pressure. It is configured. Further, in the vacuum breaker used in the sink unit described in Patent Document 1, when the operation handle is opened halfway, water overflows and overflows on the air intake side for opening the upstream channel to the atmosphere. It becomes water. Therefore, the vacuum breaker described in Patent Document 1 is configured to lead the overflow water to the outside through the outlet.

JP 2009-52337 A

  Here, in the filth distribution unit provided with the vacuum breaker, the arrangement of the components constituting the filth distribution unit may differ depending on the product specifications and the like. In this case, the space for arranging the vacuum breaker is limited, and it is necessary to change the arrangement of the vacuum breaker according to the specifications of the product.

  In the vacuum breaker described in Patent Document 1 in which overflow water is led to the outside through the outlet, the direction of the outlet from which the overflow water is led is fixed. For this reason, when installing a vacuum breaker in the sink, the space for placing the vacuum breaker is limited, and it becomes necessary to bypass the discharge flow path connected to the outlet, and the position for placing the vacuum breaker is restricted. There is a possibility that. Therefore, in the vacuum breaker having the outlet for leading the overflow water to the outside, the degree of freedom of arrangement of the vacuum breaker may be limited.

  An object of this invention is to provide the vacuum breaker which can improve the freedom degree of arrangement | positioning in the vacuum breaker which has a derivation | leading-out port which derives | emits overflowing water outside.

  The present invention is formed above the first flow path, the first flow path extending in the vertical direction, the second flow path extending in the direction intersecting the first flow path above the first flow path, and the first flow path. A main body having an opening, a first position that is disposed in the opening of the main body, communicates the first flow path and the second flow path, and closes the opening; and A flow path switching member movable between a second position at which one flow path is opened to the atmosphere via the opening, and the flow path switching member between the first position and the second position. A movably holding member, and a lead-out port through which overflowing water overflows through the gap between the flow path switching member and the opening, and is rotatable relative to the main body. The present invention relates to a vacuum breaker provided with an overflow water outlet member attached to the holding member.

  The apparatus further includes a seal member disposed between the holding member and the overflow water deriving member, and the overflow water deriving member is attached to the main body in a state of being kept in a sealed state with the holding member by the seal member. It is preferable that it is connected to the holding member so as to be rotatable.

  The present invention also includes a bowl portion, a water discharge port from which water is discharged toward the bowl portion, a water discharge channel connected to the water discharge port and through which water flows toward the water discharge port, and the water discharge flow The present invention relates to a filth distribution unit comprising an opening / closing mechanism capable of opening and closing a path, and the vacuum breaker disposed between the opening / closing mechanism and the water outlet in the water discharge passage.

  In addition, it is preferable to include a tank having a receiving port for receiving water, and a tubular first overflow water outlet channel that is connected to the outlet and extends toward the inlet.

  In addition, an electric water heater, an expansion water discharge passage for discharging the expansion water of the electric water heater, a second overflow water outlet passage through which overflow water derived from the outlet port circulates, and the expansion water discharge flow A confluence discharge flow path in which the expanded water flowing through the passage and the overflow water flowing through the second overflow water outlet flow path join together and a drain trap connected to the downstream side of the confluence discharge flow path; It is preferable to provide.

  ADVANTAGE OF THE INVENTION According to this invention, the vacuum breaker which can improve the freedom degree of arrangement | positioning can be provided in the vacuum breaker which has the outlet which derives | emits overflowing water outside.

1 is a perspective view showing a filth logistics unit 1 according to a first embodiment of the present invention. It is a perspective view which shows the vacuum breaker 40 of 1st Embodiment of this invention. It is a disassembled perspective view which shows the vacuum breaker 40 of 1st Embodiment of this invention. It is sectional drawing which shows the vacuum breaker 40 of 1st Embodiment of this invention, Comprising: It is a figure which shows the case where the flow-path switching member 44 is located in a 2nd position. It is sectional drawing which shows the vacuum breaker 40 of 1st Embodiment of this invention, Comprising: It is a figure which shows the case where the flow-path switching member 44 is located in a 1st position. FIG. 3 is a side view showing a case where a vacuum breaker 40 is disposed on the right side of a washing water tank 30 in the filth distribution unit 1 of the first embodiment of the present invention. FIG. 2 is a plan view showing a case where a vacuum breaker 40 is disposed on the right side of a washing water tank 30 in the filth distribution unit 1 of the first embodiment of the present invention. FIG. 5 is a side view showing a modification of the first embodiment of the present invention, in which a vacuum breaker 40 is disposed on the left side of a washing water tank 30. FIG. 6 is a plan view showing a modification of the first embodiment of the present invention, in which a vacuum breaker 40 is disposed on the left side of a washing water tank 30. It is a figure explaining the piping structure of the filth distribution unit 1A which concerns on 2nd Embodiment of this invention. It is a figure explaining the piping structure of the filth distribution unit 1B which concerns on 3rd Embodiment of this invention.

  Hereinafter, preferred embodiments of the filth logistics unit 1 of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing a dirty logistics unit 1 according to the first embodiment of the present invention. In the following description, the left-right direction is the left-right direction in the horizontal direction when facing the front surface 10a of the lining 10, and the up-down direction is the up-down direction along the vertical direction.

As shown in FIG. 1, the waste logistics unit 1 of the present embodiment includes a box-shaped lining 10, a bowl portion 20, a washing water tank 30, a vacuum breaker 40, an electric water heater 50, and a water discharge pipe 60. And an operation handle 65.
The lining 10 is disposed behind the bowl portion 20. The lining 10 is configured in a box shape having at least a front surface 10a, a side surface 10b, and an upper surface 10c.

The lining 10 includes a frame portion (not shown) constituting the skeleton, a plurality of plate-like members 11 attached to the frame portion, and a baseboard 12.
The plurality of plate-like members 11 includes a front plate 101 that forms the front surface 10 a of the lining 10, a side plate 102 that forms the side surface 10 b of the lining 10, and a deck 103 that forms the upper surface 10 c of the lining 10.
The skirting board 12 is comprised with a strip | belt-shaped board member, and is attached to the lower part of a flame | frame part so that a floor surface may be met.

  The bowl portion 20 is disposed on the front side and below the front plate 101 of the lining 10. The bowl portion 20 has an upper opening 201 that opens upward. The bowl part 20 receives the water discharged from the water outlet 611 of the water discharge pipe 60 mentioned later.

As shown in FIG. 1, the washing water tank 30 is disposed inside the lining 10 and behind the front plate 101 and above the bowl portion 20.
The cleaning water tank 30 includes a tank main body 31 and a lid portion 32.
The tank body 31 is formed in a box shape with an upper surface opened, and stores cleaning water for cleaning the bowl portion 20.
The lid portion 32 is disposed on the upper surface of the tank body 31 and covers the upper surface of the tank body 31. The lid portion 32 has a drainage introduction opening 301 (see FIGS. 6A, 6B, 7A, and 7B) as a receiving opening that opens upward. The drainage introduction opening 301 is an opening that receives water into the cleaning water tank 30.

  The electric water heater 50 is arranged on the right side inside the lining 10 and behind and below the front plate 101. The electric water heater 50 heats the water supplied to the unit 1 through filthy logistics. In the present embodiment, the water heated by the electric water heater 50 may be referred to as hot water in the description of the electric water heater 50, and in the description of the operation handle 65, the vacuum breaker 40, and the water discharge pipe 60. Sometimes called water.

  The electric water heater 50 includes a casing 51, a water supply inlet 52, a hot water outlet 53, a water outlet 54, an expansion water outlet 55, and a hot water storage (not shown). Inside the casing 51, a hot water storage section (not shown) for heating the supplied water and storing it as hot water is disposed.

The water supply inlet 52 introduces water into the electric water heater 50. A water supply introduction hose 521 connected to a water pipe is connected to the water supply introduction port 52 via a water stop cock (not shown).
The hot water supply outlet 53 leads out hot water stored by being heated by the electric water heater 50. A hot water supply hose 531 connected to an opening / closing mechanism 651 of an operation handle 65 (described later) is connected to the hot water supply outlet 53.

The water supply outlet 54 derives water introduced from the water supply inlet 52 as it is without being heated. A water outlet hose 541 connected to an opening / closing mechanism 651 of an operation handle 65 (described later) is connected to the water supply outlet 54.
The expansion water discharge port 55 discharges expansion water generated during heating to the washing water tank 30 via the expansion water discharge hose 551. An expansion water discharge hose 551 connected to the cleaning water tank 30 is connected to the expansion water discharge port 55. The expanded water discharged to the washing water tank 30 is introduced into the washing water tank 30 through the drainage introduction part of the lid part 32 and stored.

  The water discharge pipe 60 is attached to the front plate 101 of the lining 10 above the bowl portion 20 via a water discharge pipe fixing hole (not shown). The water discharge pipe 60 has a water discharge pipe main body 61 disposed on the front side on the front side of the front plate 101 of the lining 10 and a guide tube 62 disposed on the rear side and connected to the front plate 101 of the lining 10.

The water discharge pipe main body 61 is a part from which water is discharged toward the bowl part 20, and is removable from the guide pipe 62.
A water discharge port 611 that opens downward is formed at the tip of the water discharge pipe body 61. The water discharge port 611 discharges water toward the bowl portion 20.
The water discharge pipe main body 61 is connected to a water discharge hose 63 that can be pulled out from the inside of the lining 10 on the rear end side. The guide tube 62 guides the water discharge hose 63 drawn from the inside of the lining 10.

  An opening / closing mechanism 651 of an operation handle 65 described later is connected to the end of the water discharge hose 63 opposite to the water discharge pipe main body 61 inside the lining 10. A vacuum breaker 40 described later is provided between the water discharge pipe 60 in the water discharge hose 63 and the opening / closing mechanism 651 of the operation handle 65.

  Inside the water discharge hose 63, when the operation handle 65 is operated from the closed state to the open state, hot water or water led out from the electric water heater 50 is directed from the opening / closing mechanism 651 of the operation handle 65 toward the water discharge port 611. Circulate. The water discharge hose 63 constitutes a water discharge flow path. The water discharge hose 63 is, for example, a flexible metal hose.

  The operation handle 65 is attached to the front plate 101 of the lining 10 above the bowl portion 20 through an operation handle fixing hole (not shown). The opening / closing mechanism 651 of the operation handle 65 is disposed on the back side of the front plate 101 of the lining 10 and is operated by the operation handle 65.

The opening / closing mechanism 651 of the operation handle 65 opens and closes the water discharge flow path constituted by the water discharge hose 63. That is, by operating the operation handle 65, the opening / closing mechanism 651 can be opened and closed, and the discharge channel can be switched between the open state and the discharge channel is closed. In addition, when the opening / closing mechanism 651 of the operation handle 65 is opened / closed, the state where the discharge flow path is opened includes a completely opened state and a partially opened state.
When the water discharge channel is opened by the opening / closing mechanism 651 of the operation handle 65 or when it is opened halfway, the amount of water is adjusted from the water outlet 611 of the water discharge pipe 60 according to the degree of the open state of the opening / closing mechanism 651. Water is discharged. When the water discharge channel is closed by the opening / closing mechanism 651, water is not discharged from the water discharge port 611 of the water discharge pipe 60.

  The vacuum breaker 40 is disposed inside the lining 10 and on the right side of the washing water tank 30. The vacuum breaker 40 is disposed between the opening / closing mechanism 651 of the operation handle 65 and the water discharge port 611 in the water discharge flow path constituted by the water discharge hose 63. The vacuum breaker 40 is configured to supply water to the water discharge port 611 with water pressure at the time of water supply, and to open to the atmosphere in order to eliminate the negative pressure when the upstream flow path of the water supply becomes negative pressure. .

  Next, details of the vacuum breaker 40 will be described with reference to the drawings. FIG. 2 is a perspective view showing the vacuum breaker 40 according to the first embodiment of the present invention. FIG. 3 is an exploded perspective view showing the vacuum breaker 40 according to the first embodiment of the present invention. FIG. 4 is a cross-sectional view showing the vacuum breaker 40 according to the first embodiment of the present invention, and shows a case where the flow path switching member 44 is located at the second position. FIG. 5 is a cross-sectional view showing the vacuum breaker 40 according to the first embodiment of the present invention, and shows a case where the flow path switching member 44 is located at the first position. FIG. 6A is a side view showing a case where a vacuum breaker 40 is arranged on the right side of the washing water tank 30 in the filth distribution unit 1 of the first embodiment of the present invention. FIG. 6B is a plan view showing a case where the vacuum breaker 40 is disposed on the right side of the washing water tank 30 in the filth distribution unit 1 according to the first embodiment of the present invention.

As shown in FIGS. 2 to 5, the vacuum breaker 40 includes a main body 41, a flow path switching member 44, an overflow water storage member 45 as a holding member, an overflow water outlet member 46, and a lid body 47. Prepare.
The main body 41 includes an introduction pipe 42 and a branch member 43.

  The introduction pipe 42 is disposed at the lower part of the vacuum breaker 40. The introduction pipe 42 is formed so as to extend in the vertical direction and penetrates in the vertical direction. The introduction pipe 42 has an introduction port 421 and an outlet port 422.

  As shown in FIGS. 3 and 4, the introduction port 421 is a portion surrounded by the inner surface of the lower end portion of the introduction pipe 42 and opens downward. Water from the electric water heater 50 is introduced into the introduction port 421 by operating the operation handle 65 (see FIG. 1) so that the opening / closing mechanism 651 (see FIG. 1) is opened. The outlet port 422 is a portion surrounded by the inner surface of the upper end portion of the introduction tube 42 and opens upward. From the outlet 422, water flowing through the inside of the introduction pipe 42 is led out.

  The internal space that penetrates the introduction pipe 42 and extends in the vertical direction constitutes the first flow path R1 as shown in FIG. The first flow path R1 extends in the vertical direction. In the first flow path R1, water flows from the lower side to the upper side of the introduction pipe. That is, the water introduced from the inlet 421 flows toward the outlet 422 in the first flow path R1.

  As shown in FIGS. 3 and 4, a notch 423 is formed in the upper end surface 42 a of the introduction pipe 42. The notch 423 is formed in a concave shape that is partially recessed from the upper end surface 42 a of the introduction tube 42.

  As shown in FIGS. 3 and 4, an introduction pipe flange 424 and an introduction pipe groove 425 are formed on the outer surface of the introduction pipe 42. The introduction pipe flange portion 424 is formed in a substantially disc shape that protrudes in the radial direction from the outer surface of the introduction pipe 42 at a substantially center in the vertical direction of the introduction pipe 42. The introduction pipe groove 425 is formed in a groove shape over the entire area in the circumferential direction on the outer surface of the introduction pipe 42 above the introduction pipe flange 424. A first O-ring 71 is attached to the introduction pipe groove 425.

  As shown in FIGS. 3 and 4, the branch member 43 is formed to extend in the vertical direction, is formed in a cylindrical shape penetrating in the vertical direction, and opens to the left side. The branch member 43 is extrapolated to the introduction pipe 42 above the introduction pipe 42 so as to cover the upper side of the introduction pipe 42 from the outside. The branch member 43 is in a state in which the first O-ring 71 is disposed between the branch member 43 and the introduction pipe 42, and the lower end portion of the branch member 43 is in contact with the upper surface of the introduction pipe flange portion 424 of the introduction pipe 42. In the state, it is connected to the introduction pipe 42. The branch member 43 is connected to the introduction pipe 42 without rotating with respect to the introduction pipe 42.

  As shown in FIG. 4, the branch member 43 is formed such that its upper end surface 43 a is positioned above the position of the upper end surface 42 a of the introduction pipe 42. Thus, a branch member upper opening (opening) 432 described later is formed at the upper end of the branch member 43 between the upper end surface 42 a of the introduction pipe 42 and the upper end surface 43 a of the branch member 43.

  As shown in FIGS. 3 and 4, the branch member 43 includes a branch member lower opening 431, a branch member upper opening 432, and a branch member side opening 433.

  The branch member lower opening 431 is a portion surrounded by the inner surface of the lower end portion of the branch member 43 and opens downward. The upper side of the introduction pipe 42 is inserted into the branch member lower opening 431.

  The branch member upper opening 432 is formed above the first flow path R1. As described above, the branch member upper opening 432 is a portion surrounded by the inner surface of the upper end portion of the branch member 43 between the upper end surface 42a of the introduction pipe 42 and the upper end surface 43a of the branch member 43, and opens upward. To do. The branch member upper opening 432 is formed in a step shape. That is, the branch member upper opening 432 includes a large-diameter opening 432a formed at the upper end and a small-diameter opening having a smaller diameter than the large-diameter opening 432a continuously formed below the large-diameter opening 432a. 432b. At the boundary between the large-diameter opening 432a and the small-diameter opening 432b, a step surface 435 that is annularly formed in the horizontal direction is formed at the outer edge of the large-diameter opening 432a. The flow path switching member 44 and the lower part of the overflow water accommodation member 45 described later are disposed in the branch member upper opening 432.

The branching member side opening 433 communicates with the branching member lower opening 431 and the branching member upper opening 432 at the approximate center in the vertical direction of the branching member 43 and opens to the left side.
In a state where the branch member 43 is attached to the introduction pipe 42, a communication space 434 is formed between the outer surface of the upper part of the introduction pipe 42 and the branch member 43 and the introduction pipe 42. The branch member upper opening 432, the communication space 434, and the branch member side opening 433 communicate with each other.

  The branch member side opening 433 constitutes the second flow path R2. The second flow path R2 extends to the left in the substantially horizontal direction intersecting the first flow path R1 above the first flow path R1. In the second flow path R2, the water led through the first flow path R1 and led out from the outlet port 422 of the introduction pipe 42 flows through the communication space 434.

  As shown in FIGS. 3 and 4, the flow path switching member 44 is disposed in the branch member upper opening 432 of the branch member 43. The flow path switching member 44 is disposed above the upper end surface 43 a of the introduction pipe 42. The flow path switching member 44 includes a disk-shaped disk-shaped bottom part 441 and a cross-shaped rising cross-shaped part 442 that is raised upward from the disk-shaped bottom part 441 in a plan view. In the flow path switching member 44, a disk-shaped bottom portion 441 and a rising cross-shaped portion 442 are continuously formed in this order from the bottom to the top. The outer diameter of the disk-shaped bottom portion 441 is larger than the outer diameter of the upper end portion of the introduction pipe 42. The flow path switching member 44 is made of, for example, a resin material.

  The flow path switching member 44 overflows in a state where it is disposed in the branch member upper opening 432 of the branch member 43 so as to be movable between the first position (see FIG. 5) and the second position (see FIG. 4). It is held by a water storage member 45 (described later).

The first position of the flow path switching member 44 is a position where the flow path switching member 44 is disposed when the discharge flow path is completely opened by the opening / closing mechanism 651 of the operation handle 65.
As shown in FIG. 5, the first position of the flow path switching member 44 is a disk-like shape of the flow path switching member 44 when the flow path switching member 44 is pressed by the water pressure of the water flowing through the first flow path R1. The outer edge portion of the upper surface of the bottom portion 441 is a position that abuts against the peripheral edge portion of the overflow water introduction opening 453 (described later) of the overflow water storage member 45 (described later). The first position in the flow path switching member 44 connects the first flow path R1 and the second flow path R2 and closes the branch member upper opening 432. At the first position in the flow path switching member 44, the first flow path R1 and the second flow path R2 communicate with each other and the branch member upper opening 432 is closed, so that the second flow path R1 and the second flow path R2 are closed. Water flows through the flow path R2.

The second position of the flow path switching member 44 is a position where the flow path switching member 44 is disposed when the discharge flow path is closed by the opening / closing mechanism 651 of the operation handle 65.
As shown in FIG. 4, the second position of the flow path switching member 44 is a position below the first position of the flow path switching member 44. The second position of the flow path switching member 44 is such that the outer edge of the upper surface of the disk-shaped bottom 441 of the flow path switching member 44 is the peripheral edge of the overflow water introduction opening 453 (described later) of the overflow water storage member 45 (described later). And the lower end portion of the flow path switching member 44 is in contact with the upper end surface 42 a of the introduction pipe 42. At the second position of the flow path switching member 44, the flow of water between the first flow path R 1 and the second flow path R 2 is blocked, and the first flow path R 1 is the branch member upper opening 432 of the branch member 43. And it is opened to the atmosphere through the notch 423. Thereby, even if the first flow path R1 has a negative pressure, air is introduced into the first flow path R1 from the outside, and the negative pressure in the first flow path R1 is eliminated.
The details of the configuration in which the first flow path R1 is opened to the atmosphere when the flow path switching member 44 is located at the second position will be described later.

The position between the first position and the second position in the flow path switching member 44 is a position where the flow path switching member 44 is disposed when the discharge flow path is opened halfway by the opening / closing mechanism 651 of the operation handle 65. It is.
When the flow path switching member 44 is located at a position between the first position (see FIG. 5) and the second position (see FIG. 4), the flow path switching member 44 includes the introduction pipe 42 and the overflow water accommodating member. 45 (described later) and spaced from the upper end surface 42a of the introduction pipe 42 and the lower end portion of the overflow water accommodating member 45 (described later). In this case, the first flow path R1, the second flow path R2, and the overflow water introduction opening 453 (described later) communicate with each other. Therefore, when the flow path switching member 44 is located at a position between the first position and the second position, out of the water circulated from the first flow path R1 toward the second flow path R2, the flow path The overflow water overflowing through the gap between the switching member 44 and the overflow water introduction opening 453 of the overflow water storage member 45 is circulated toward the overflow water storage space 451 (described later).

  As shown in FIGS. 3 and 4, the overflow water storage member 45 is formed in a cylindrical shape penetrating in the vertical direction. The lower part of the overflow water accommodation member 45 can move the flow path switching member 44 between the first position and the second position in a state where the flow path switching member 44 is disposed in the branch member upper opening 432 of the branch member 43. It is inserted into the branch member upper opening 432 of the branch member 43 so as to hold it in a stable state.

  The overflow water storage member 45 is in a state in which a second O-ring 72 (described later) is disposed between the overflow water storage member 45 and the branch member 43, and in the storage member flange portion 454 (described later) of the overflow water storage member 45. The lower end surface is connected to the branch member 43 in a state where the lower end surface is in contact with the step surface 435 of the branch member 43. The overflow water accommodation member 45 is connected to the branch member 43 in a state where it does not rotate with respect to the branch member 43.

  The overflow water accommodation member 45 holds the flow path switching member 44 so that the flow path switching member 44 can be moved between the first position and the second position. An overflow water introduction opening 453 communicating with the overflow water storage space 451 is formed above the first flow path R1 at the lower portion of the overflow water storage member 45.

  The overflow water introduction opening 453 is formed in the lower part of the overflow water storage member 45 and opens downward. The lower part of the overflow water accommodation member 45 is disposed in the branch member upper opening 432 of the branch member 43. In the overflow water introduction opening 453, the flow path switching member 44 is disposed in a state in which it can move in the vertical direction between the first position and the second position.

  The overflow water introduction opening 453 is formed on the upper side and has a cylindrical upper cylindrical opening 453a having a diameter smaller than the diameter of the overflow water storage space 451, and a conical cone whose diameter increases toward the bottom. An opening 453b and a cylindrical lower cylindrical opening 453c formed on the lower side and having a diameter larger than the diameter of the upper cylindrical opening 453a are continuous in this order from the upper side to the lower side. Formed. The diameter of the upper cylindrical opening 453a of the overflow water introduction opening 453 is such that the flow switching member 44 can be moved in the vertical direction outside the rising cross-shaped portion 442 of the flow switching member 44. It is equal to the diameter or slightly larger than the outer diameter of the rising cross-shaped portion 442.

  An overflow water storage space 451 is formed above the overflow water storage member 45. The overflow water storage space 451 communicates with the overflow water introduction opening 453. The overflow water storage space 451 is a portion surrounded by the inner surface of the upper end portion of the overflow water storage member 45 and is a cylindrical space opened upward. The overflow water storage space 451 is a part of the water flowing from the first flow path R1 to the second flow path R2, and overflows the overflow water through the gap between the flow path switching member 44 and the overflow water introduction opening 453. Can be accommodated.

  The overflow water storage member 45 is formed with a pair of overflow water communication holes 452 that face each other and penetrate in a substantially horizontal direction at a predetermined height. The pair of overflow water communication holes 452 allows the overflow water storage space 451 to communicate with the inside of the overflow water outlet member 46 (described later). The pair of overflow water communication holes 452 overflows the overflow water stored in the overflow water storage space 451 when the overflow water stored in the overflow water storage space 451 rises to the height of the pair of overflow water communication holes 452. It passes through the water outlet member 46 (described later).

On the outer surface of the overflow water storage member 45, a storage member flange portion 454, a first storage member groove portion 455, and a second storage member groove portion 456 are formed.
The housing member flange portion 454 is formed in a substantially disc shape that protrudes in the radial direction from the outer surface of the overflow water storage member 45 below the overflow water storage member 45.
The first housing member groove portion 455 is formed in a groove shape over the entire region in the circumferential direction on the outer surface of the overflow water housing member 45 below the housing member flange portion 454. A second O-ring 72 is attached to the first housing member groove 455.

  The second housing member groove portion 456 is formed in a groove shape over the entire area in the circumferential direction on the outer surface of the overflow water housing member 45 above the housing member flange portion 454. The second housing member groove 456 is formed in a groove shape that is wider than the first housing member groove 455 and has a deep recess. A third O-ring 73 (seal member) that is thicker than the second O-ring 72 is attached to the second housing member groove 456.

  A lid 47 described later is attached to the upper end portion of the overflow water accommodation member 45. A housing member screw portion 457 is formed on the inner peripheral surface of the upper end portion of the overflow water housing member 45. The housing member screw portion 457 of the overflow water housing member 45 is screwed into a lid body screw portion 473 formed on the outer peripheral surface of the lower end portion of the lid body 47 described later. As a result, the lid 47 described later is connected to the upper end portion of the overflow water storage member 45 in a state where the overflow water outlet member 46 described later is attached to the overflow water storage member 45.

  As shown in FIGS. 3 and 4, the overflow water outlet member 46 is formed to extend in the vertical direction, is formed in a cylindrical shape penetrating in the vertical direction, and opens to the left side. The overflow water outlet member 46 is inserted into the overflow water accommodation member 45 at the upper part of the overflow water accommodation member 45 so as to cover the upper part of the overflow water accommodation member 45 from the outside. The overflow water deriving member 46 is in a state where the third O-ring 73 (seal member) is disposed between the overflow water deriving member 46 and the overflow water accommodating member 45, and the lower end portion of the overflow water deriving member 46 overflows and accommodates water. In a state of abutting against the housing member flange portion 454 of the member 45, the overflow water is connected to the overflow water housing member 45 in a rotatable manner.

  Specifically, the overflow water outlet member 46 is rotatable with respect to the main body 41 (the introduction pipe 42 and the branch member 43) in a state in which the overflow water holding member 45 is kept sealed by the third O-ring 73. Connected to (attached to) the overflow water containing member 45.

  Specifically, the third O-ring 73 is formed with a thickness that allows the overflow water outlet member 46 to rotate with respect to the overflow water storage member 45 and has a thickness that maintains a sealed state with the overflow water storage member 45. In this state, the second storage member groove 456 is disposed between the overflow water outlet member 46 and the overflow water storage member 45. Thus, the overflow water outlet member 46 is rotatably attached to the overflow water storage member 45 via the third O-ring 73. Here, the overflow water accommodation member 45 does not rotate with respect to the main body 41 (the introduction pipe 42 and the branch member 43). Therefore, the overflow water outlet member 46 can rotate with respect to the main body 41 (the introduction pipe 42 and the branch member 43) via the third O-ring 73.

  As shown in FIGS. 3 and 4, the overflow water deriving member 46 includes a deriving upper cylindrical portion 461, a deriving intermediate cylindrical portion 462, and a deriving lower cylindrical portion 463. The lead-out upper cylindrical portion 461, the lead-out intermediate cylindrical portion 462, and the lead-out lower cylindrical portion 463 are successively formed in this order from the top to the bottom.

The outlet upper cylindrical portion 461 is disposed at the upper end portion of the overflow water outlet member 46 and is formed in a cylindrical shape.
The lead-out intermediate tubular portion 462 is formed continuously from the lower end portion of the lead-out upper tubular portion 461, and a shape obtained by cutting the right portion straight from a cylindrical shape having a diameter larger than the diameter of the lead-out upper tubular portion 461. Formed.
The outlet lower cylindrical portion 463 is formed continuously with the lower end portion of the outlet intermediate cylindrical portion 462 and is disposed at the lower end portion of the overflow water outlet member 46. The lead-out lower tubular portion 463 is formed in a cylindrical shape having the same diameter as that of the lead-out upper tubular portion 461.

  As shown in FIG. 4, the overflow water outlet member 46 has an upper end surface 46 a of the overflow water outlet member 46 in a state where the overflow water outlet member 46 is attached to the overflow water storage member 45. It is formed so as to be located above the position of 45a. Further, in the state where the overflow water outlet member 46 is attached to the overflow water storage member 45, the upper end portion of the overflow water storage member 45 is between the outer surface of the overflow water storage member 45 and the inner surface of the overflow water outlet member 46. A gap is formed.

  The overflow water lead-out member 46 has a lead-out member upper opening 464, a lead-out member lower opening 465, and a lead-out opening 466 as a lead-out port. The lead member upper opening 464, the lead member lower opening 465, and the lead opening 466 communicate with each other.

The lead-out member upper opening 464 is a portion surrounded by the inner surface of the lead-out upper cylindrical portion 461 and opens upward. The lid 47 is inserted into the lead-out member upper opening 464.
The lead-out member lower opening 465 is a portion surrounded by the inner surface of the lead-out lower cylindrical portion 463 and opens downward. The overflow water accommodation member 45 is inserted into the outlet member lower opening 465.

  The lead-out opening 466 is formed on the side of the lead-out intermediate cylindrical part 462 and opens to the left side. In the state where the overflow water outlet member 46 is attached to the overflow water storage member 45, the outlet opening 466 accommodates the overflow water of the overflow water storage member 45 through the pair of overflow water communication holes 452 of the overflow water storage member 45. The overflow water stored in the overflow water storage space 451 is led out to the outside in communication with the space 451.

  The lid body 47 includes a substantially disc-shaped top plate 471 that is wider in the horizontal direction than the outer diameter of the upper end portion of the overflow water outlet member 46, and a cylindrical member 472 that extends downward from the top plate 471. A lid screw portion 473 is formed on the outer peripheral surface of the lower end portion of the cylindrical member 472.

  The lid 47 is attached to the overflow water storage member 45 in a state where the overflow water outlet member 46 is rotatably attached to the overflow water storage member 45. The lid body 47 is attached to the overflow water accommodation member 45 by screwing the lid body screw portion 473 of the lid body 47 with the accommodation member screw portion 457 formed on the inner peripheral surface of the upper end portion of the overflow water accommodation member 45. It is done.

  In a state where the lid 47 is attached to the overflow water storage member 45, overflow water is led out between the outer edge portion of the top plate 471 of the lid 47 and the storage member flange portion 454 of the overflow water storage member 45 in the vertical direction. The member 46 is rotatably arranged. Here, since the top plate 471 is formed in a substantially disk shape that is wider in the horizontal direction than the outer diameter of the upper end portion of the overflow water outlet member 46, the outer edge portion of the top plate 471 of the lid body 47 is the overflow water outlet member. The upward movement of 46 is restricted. Therefore, by attaching the lid 47 to the overflow water storage member 45, the overflow water outlet member 46 is prevented from being detached from the overflow water storage member 45.

  In addition, when the cover 47 is attached to the overflow water storage member 45, a gap is formed between the inner surface of the upper end portion of the overflow water outlet member 46 and the outer surface of the cylindrical member 472 of the cover 47. Yes. Further, a gap communicating with the outside is formed between the upper end surface 46 a of the overflow water outlet member 46 and the lower surface of the top plate 471 of the lid body 47. For this reason, the clearance gap between the overflow water derivation | leading-out member 46 and the cover body 47 is connected with the exterior.

In the vacuum breaker 40 configured as described above, details of a configuration in which the first flow path R1 is opened to the atmosphere when the flow path switching member 44 is located at the second position will be described.
As shown in FIG. 4, the second position of the flow path switching member 44 is such that the outer edge of the upper surface of the disk-shaped bottom portion 441 of the flow path switching member 44 is the periphery of the overflow water introduction opening 453 of the overflow water storage member 45. The lower end of the flow path switching member 44 is in contact with the upper end of the introduction pipe 42.

  In this case, as shown in FIG. 4, a gap communicating with the outside is formed between the overflow water outlet member 46 and the lid body 47. The gap between the overflow water outlet member 46 and the lid 47 communicates with the gap between the overflow water storage member 45 and the overflow water outlet member 46. A gap between the overflow water storage member 45 and the overflow water outlet member 46 communicates with the pair of overflow water communication holes 452. The pair of overflow water communication holes 452 communicate with the overflow water storage space 451 of the overflow water storage member 45. The overflow water storage space 451 of the overflow water storage member 45 communicates with a gap between the flow path switching member 44 and the overflow water introduction opening 453 of the overflow water storage member 45. A gap between the flow path switching member 44 and the overflow water introduction opening 453 of the overflow water storage member 45 communicates with a notch 423 formed in the upper end surface 42a of the introduction pipe 42 to the first flow path R1. Communicate.

  Therefore, when the flow path switching member 44 is located at the second position, air from the outside flows into the first flow path R1 between the overflow water outlet member 46 and the lid 47, and the overflow water storage member 45. And the overflow water outlet member 46, a pair of overflow water communication holes 452 of the overflow water storage member 45, the overflow water storage space 451 of the overflow water storage member 45, the flow path switching member 44 and the overflow water storage member 45. Suction is possible through the gap between the overflow water introduction opening 453 and the notch 423. Thereby, when the flow path switching member 44 is located at the second position, the first flow path R1 is opened to the atmosphere.

  In the vacuum breaker 40 of the first embodiment configured as described above, the outlet opening 466 for leading the overflow water to the outside has an overflow water outlet channel as an overflow water outlet channel as shown in FIG. A tube 80 is connected. The overflow water outlet channel pipe 80 includes a connecting pipe 81 and an outlet channel body 82. The overflow water outlet channel pipe 80 is formed in a tubular shape extending in a straight line. A fourth O-ring 74 is disposed between the outlet opening 466 and the overflow water outlet passage pipe 80.

The vacuum breaker 40 of 1st Embodiment is arrange | positioned at the right side of the washing water tank 30, as shown to FIG. 6A and 6B. The overflow water outlet passage pipe 80 connected to the outlet opening 466 extends linearly toward the drainage inlet opening 301 of the cleaning water tank 30.
Here, since the overflow water deriving member 46 is configured to be rotatable, by rotating the overflow water deriving member 46 of the vacuum breaker 40, the direction of the outlet opening 466 for deriving the overflow water to the outside is changed to the washing water tank 30. It can be arranged to face. Therefore, the freedom degree of arrangement | positioning of the vacuum breaker 40 can be improved.

  The overflow water discharge channel pipe 80 has a linear shape so that the overflow water discharge opening 801 is located above the washing water tank 30 and is inclined downward from the discharge opening 466 toward the overflow water discharge opening 801. It extends to. Therefore, the overflow water discharged from the outlet opening 466 can be reliably discharged to the cleaning water tank 30.

  As shown in FIGS. 7A and 7B, the vacuum breaker 40 may be disposed on the left side of the cleaning water tank 30 depending on the product specifications of the filthy distribution unit 1 or the like. FIG. 7A is a side view showing a modification of the first embodiment of the present invention, in which a vacuum breaker 40 is arranged on the left side of the washing water tank 30. FIG. 7B is a plan view showing a modification of the first embodiment of the present invention, in which a vacuum breaker 40 is arranged on the left side of the washing water tank 30.

  As shown in FIGS. 7A and 7B, when the vacuum breaker 40 is disposed on the left side of the cleaning water tank 30, the overflow water outlet member 46 is configured to be rotatable. Therefore, by rotating the overflow water deriving member 46, the direction of the outlet opening 466 for deriving the overflow water to the outside can be arranged so as to face the cleaning water tank 30. Therefore, the freedom degree of arrangement | positioning of the vacuum breaker 40 can be improved.

Next, the operation of the vacuum breaker 40 configured as described above will be described.
When the opening / closing mechanism 651 of the operation handle 65 is closed, the flow path switching member 44 is located at the second position. As shown in FIG. 4, the second position of the flow path switching member 44 is such that the outer edge of the upper surface of the disk-shaped bottom portion 441 of the flow path switching member 44 is the periphery of the overflow water introduction opening 453 of the overflow water storage member 45. It is a position where the lower end portion of the flow path switching member 44 is in contact with the upper end surface 42 a of the introduction pipe 42. In this state, the first flow path R <b> 1 is opened to the atmosphere via the branch member upper opening 432 and the notch 423 of the branch member 43.

  Specifically, when the flow path switching member 44 is located at the second position, the first flow path R1 includes the notch 423, the flow path switching member 44, and the overflow water introduction opening 453 of the overflow water storage member 45. A gap between the overflow water storage member 45, a pair of overflow water communication holes 452 of the overflow water storage member 45, a gap between the overflow water storage member 45 and the overflow water outlet member 46, and It is released to the atmosphere through a gap between the overflow water outlet member 46 and the lid body 47.

  When the opening / closing mechanism 651 of the operation handle 65 is fully opened, the flow path switching member 44 is located at the first position. As shown in FIG. 5, the first position of the flow path switching member 44 is such that the flow path switching member 44 is pressed by the water pressure of the water flowing through the first flow path R <b> 1, so The outer edge portion of the upper surface of the bottom portion 441 is a position that abuts on the peripheral edge portion of the overflow water introduction opening 453 of the overflow water storage member 45. In this state, the first flow path R1 and the second flow path R2 communicate with each other and the branch member upper opening 432 is closed, so that water introduced into the introduction pipe 42 flows from the first flow path R1. It flows to the second flow path R2 through the communication space 434.

  Further, when the opening / closing mechanism 651 of the operation handle 65 is opened halfway, the flow path switching member 44 is located at a position between the first position and the second position. The position between the first position and the second position in the flow path switching member 44 is such that the flow path switching member 44 is positioned between the introduction pipe 42 and the overflow water accommodating member 45, and the upper end portion of the introduction pipe 42 and overflow. This is the position where the flow path switching member 44 is separated from the lower end of the water containing member 45.

  When the flow path switching member 44 is located at a position between the first position and the second position, the first flow path R1, the second flow path R2, and the overflow water introduction opening 453 communicate with each other. Therefore, when the flow path switching member 44 is located between the first position and the second position, the flow path switching member out of the water flowing from the first flow path R1 toward the second flow path R2. The overflow water that overflows through the gap between the overflow water inlet opening 453 of the overflow water storage member 45 is distributed toward the overflow water storage space 451 and is stored in the overflow water storage space 451.

The overflow water stored in the overflow water storage space 451 passes through the pair of overflow water communication holes 452, passes through the space between the overflow water storage member 45 and the overflow water outlet member 46, and is discharged from the outlet opening 466. Is done.
The overflow water discharged from the outlet opening 466 is discharged to the washing water tank 30 through the overflow water outlet passage pipe 80 as shown in FIGS. 6A and 6B.

  Here, it is assumed that the piping work is performed upstream of the first flow path R1 in a state where the water discharge port 611 is submerged in the water of the bowl portion 20 and the opening / closing mechanism 651 of the operation handle 65 is opened. When piping work is performed upstream of the first flow path R1, the first flow path R1 may become negative pressure. In such a case, if the opening / closing mechanism 651 of the operation handle 65 is opened halfway, if the vacuum breaker is not provided as in the prior art, the water stored in the bowl portion 20 is transferred to the first flow path. There was a case where the negative pressure of R1 was sucked (backflowed) from the water outlet 611 into the first flow path R1.

  However, in the present invention including the vacuum breaker 40, the first flow path R1 is in a state where the water discharge port 611 is submerged in the water of the bowl portion 20 and the opening / closing mechanism 651 of the operation handle 65 is opened halfway. When the pressure becomes negative, the flow path switching member 44 moves from the position between the first position and the second position to the second position due to the negative pressure of the first flow path R1.

  Here, when the flow path switching member 44 is located at the second position (see FIG. 4), the first flow path R1 is opened to the atmosphere. Specifically, the first flow path R1 includes a notch 423, a gap between the flow path switching member 44 and the overflow water introduction opening 453 of the overflow water storage member 45, and an overflow water storage space of the overflow water storage member 45. 451, a pair of overflow water communication holes 452 of the overflow water storage member 45, a gap between the overflow water storage member 45 and the overflow water outlet member 46, and a clearance between the overflow water outlet member 46 and the lid body 47. , Open to the atmosphere.

  Therefore, when the first flow path R1 becomes negative pressure, the first flow path R1 sucks outside air, and the negative pressure of the first flow path R1 is eliminated. As a result, the water stored in the bowl portion 20 is not sucked into the first flow path R1 from the water outlet 611 (does not flow backward).

According to the vacuum breaker 40 and the dirty logistics unit 1 of the first embodiment described above, the following effects are obtained.
The vacuum breaker 40 of the present embodiment includes a first flow path R1 extending in the vertical direction, a second flow path R2 extending in a direction intersecting the first flow path R1, and a branch formed above the first flow path R1. A main body 41 having a member upper opening 432, a first position that communicates the first flow path R1 and the second flow path R2 and closes the branch member upper opening 432, and the first flow path R1 branches. The flow path switching member 44 that can move between the second position opened to the atmosphere via the member upper opening 432, and the flow path switching member 44 can move between the first position and the second position. And a discharge opening 466 for leading the overflow water overflowing through the gap between the flow path switching member 44 and the branch member upper opening 432, and rotating with respect to the main body 41. Overflow water outlet member attached to overflow water storage member 45 as possible It includes a 6, a.

  Therefore, the direction of the outlet opening 466 can be changed by rotating the overflow water outlet member 46. Therefore, the freedom degree of arrangement | positioning of the vacuum breaker 40 can be improved. In addition, it is possible to easily avoid the overflow of the overflow water outlet channel 80 due to maintenance or the like.

  Further, in the present embodiment, a third O-ring 73 is further provided between the overflow water storage member 45 and the overflow water outlet member 46, and the overflow water outlet member 46 is overflowed by the third O ring 73. In a state where the airtight state with respect to 45 is maintained, it overflows and is connected to the water storage member 45 so as to be rotatable with respect to the main body 41. As a result, it is possible to arrange the overflow water outlet member 46 without using a mechanism such as a screw member only by arranging the third O-ring 73 between the overflow water storage member 45 and the overflow water outlet member 46. The 3O ring 73 can be easily attached and detached so as to be rotatable with respect to the main body 41 while maintaining a sealed state with the overflow water containing member 45. Therefore, since the overflow water derivation member 46 can be easily attached and detached, the maintainability of the vacuum breaker 40 can be improved.

  Further, the filth distribution unit 1 of the present embodiment includes a vacuum breaker 40 disposed between the opening / closing mechanism 651 of the operation handle 65 and the water discharge port 611 in the water discharge flow path constituted by the water discharge hose 63. Therefore, the back flow of water from the water outlet 611 can be suppressed.

  In the present embodiment, the flush water tank 30 having the drain introduction opening 301 for receiving water and the tubular overflow water outlet passage pipe 80 connected to the outlet opening 466 and extending toward the drain introduction opening 301 are provided. And comprising. Therefore, the overflow water discharged from the outlet opening 466 is reliably supplied to the washing water tank 30 by connecting the tubular overflow water outlet channel pipe 80 extending toward the drain introduction opening 301 to the outlet opening 466. Can be discharged.

Next, the dirty logistics unit 1A according to the second embodiment will be described. FIG. 8 is a diagram for explaining the piping configuration of the dirty logistics unit 1A according to the second embodiment of the present invention.
The filth distribution unit 1A according to the second embodiment is different from the filth distribution unit 1 according to the first embodiment mainly in discharging the overflow water derived from the vacuum breaker 40A. In the description of the second embodiment, the same components as those of the first embodiment are denoted by the same reference numerals, and the description thereof is omitted or simplified.

As shown in FIG. 8, the dirty logistics unit 1A of the second embodiment mainly includes a vacuum breaker 40A, an electric water heater 50A, and a drain trap 90.
The outlet opening 466 of the vacuum breaker 40A is connected to the first connection port 911 of the three-way joint 91 via a first rubber hose 901 serving as a second overflow water outlet channel. The first rubber hose 901 connects the outlet opening 466 and the first connection port 911 of the three-way joint 91. Overflow water led out from the lead-out opening 466 flows through the first rubber hose 901.

  The expansion water discharge port 55 of the electric water heater 50A is connected to the second connection port 912 of the three-way joint 91 via a second rubber hose 902 as an expansion water discharge channel. The second rubber hose 902 connects the expansion water discharge port 55 and the second connection port 912 of the three-way joint 91. The expanded water discharged from the electric water heater 50A flows through the second rubber hose 902.

The third connection port 913 of the three-way joint 91 is connected to the drain trap 90 via a third rubber hose 903 serving as a confluence discharge channel. The third rubber hose 903 connects the third connection port 913 of the three-way joint 91 and the drain trap 90. Through the three-way joint 91, the expanded water flowing through the second rubber hose 902 and the overflow water flowing through the first rubber hose 901 are joined to and flow through the third rubber hose 903.
The inlet of the drain trap 90 is connected to the downstream end of the third rubber hose 903. The outlet of the drain trap 90 is connected to a sewer pipe 93.

  In the waste logistics unit 1A of the second embodiment configured as described above, the overflow water led out from the lead-out opening 466 of the vacuum breaker 40A and the expanded water discharged from the electric water heater 50A are connected to the three-way joint 91. Are joined together. The overflow water and the expanded water merged at the three-way joint 91 are discharged toward the drain trap 90, pass through the drain trap 90, and are discharged to the sewer pipe 93. In the drain trap 90, the odor inside the sewage pipe 93 connected to the downstream side of the drain trap 90 is prevented from entering the room due to the sealed water stored in the seal portion of the drain trap 90.

  In the dirty logistics unit 1A of the second embodiment, the same effect as that of the first embodiment can be obtained. That is, even in a configuration in which the overflow water of the vacuum breaker 40A and the expanded water of the electric water heater 50A are merged and discharged, the degree of freedom of arrangement of the vacuum breaker 40A can be improved.

Next, the dirty logistics unit 1B according to the third embodiment will be described. FIG. 9 is a view for explaining the piping configuration of the filth distribution unit 1B according to the third embodiment of the present invention.
The filth distribution unit 1B of the third embodiment is different from the filth distribution unit 1 and 1A according to the first embodiment and the second embodiment mainly in discharging the overflow water derived from the vacuum breaker 40B. . In the description of the third embodiment, the same components as those of the first embodiment are denoted by the same reference numerals, and the description thereof is omitted or simplified.

As shown in FIG. 9, the dirty logistics unit 1B of the third embodiment mainly includes a vacuum breaker 40B and an overflow water discharge fitting 94.
The overflow water outlet opening 466 of the vacuum breaker 40 </ b> B is connected to the overflow water discharge fitting 94 via a fourth rubber hose 904. The fourth rubber hose 904 connects the outlet opening 466 and the overflow water discharge fitting 94.
The overflow water discharge fitting 94 is, for example, the lining 10 as shown in FIG. 9 above the bowl portion 20 via the overflow water discharge fitting fixing hole (not shown) in the dirty logistics unit 1 in FIG. The front plate 101 is attached.
In the waste logistics unit 1B of the third embodiment configured as described above, the overflow water led out from the lead-out opening 466 of the vacuum breaker 40 can be discharged to the bowl part 20.

  In the dirty logistics unit 1B of the third embodiment, the same effect as that of the first embodiment can be obtained. That is, even in the configuration in which the overflow water of the vacuum breaker 40B is discharged to the bowl portion 20, the degree of freedom of arrangement of the vacuum breaker 40B can be improved.

As mentioned above, although preferable embodiment of the vacuum breaker of this invention was described, this invention is not restrict | limited to embodiment mentioned above, It can change suitably.
For example, in the above-described embodiment, the vacuum breaker is applied to the unit by filthy distribution, but the present invention is not limited to this, and the vacuum breaker may be applied to the sewage unit of a different type from the unit by performing filth distribution.

  Further, in the first embodiment, the overflow water of the vacuum breaker is configured to be discharged to the washing water tank 30, but the present invention is not limited to this, and the overflow water of the vacuum breaker is discharged to another tank other than the washing water tank. You may comprise.

  Moreover, in the said embodiment, although the vacuum breaker 40 was arrange | positioned at the right side or the left side of the washing water tank 30, it is not restricted to this, You may arrange | position at the front side or the back side of the washing water tank 30.

  Moreover, in the said embodiment, although the overflow water derivation | leading-out member 46 was attached to the overflow water accommodating member 45, it is not restricted to this, You may attach to the main body 41 (introduction pipe 42, branch member 43).

1 Dirty logistics unit 20 Bowl part 30 Washing water tank (tank)
40 Vacuum breaker 41 Main body 44 Flow path switching member 45 Overflow water accommodation member (holding member)
46 Overflowing water outlet member 50 Electric water heater 73 Third O-ring (seal member)
80 Overflow water outlet channel (first overflow water outlet channel)
90 Drain trap 301 Drain introduction opening (reception port)
432 Branch member upper opening (opening)
451 overflow water storage space 466 outlet opening (outlet)
611 Discharge port 651 Opening / closing mechanism 901 First rubber hose (second overflow water outlet flow path)
902 Second rubber hose (expansion water discharge flow path)
903 3rd rubber hose (confluence discharge flow path)
R1 first flow path R2 second flow path

Claims (5)

A first flow path extending in the up-down direction, a second flow path extending in a direction intersecting the first flow path above the first flow path, and an opening formed above the first flow path, A body having
A first position that is disposed in the opening of the main body, communicates the first flow path and the second flow path and closes the opening; and the first flow path passes through the opening. A flow path switching member movable between a second position opened to the atmosphere and
A holding member that holds the flow path switching member movably between the first position and the second position;
An overflow water deriving member that has an outlet for deriving overflow water that flows through the gap between the flow path switching member and the opening to the outside and is attached to the main body or the holding member so as to be rotatable with respect to the main body And a vacuum breaker. A seal member disposed between the holding member and the overflow water outlet member;
2. The vacuum breaker according to claim 1, wherein the overflow water lead-out member is connected to the holding member so as to be rotatable with respect to the main body in a state where the sealing member holds a sealed state with the holding member. A bowl part, and a water outlet from which water is discharged toward the bowl part,
A water discharge passage connected to the water discharge port, through which water flows toward the water discharge port;
An opening and closing mechanism capable of opening and closing the water discharge channel;
A dirt distribution unit comprising: the vacuum breaker according to claim 1 or 2, wherein the vacuum breaker is disposed between the opening / closing mechanism and the water outlet in the water discharge channel. A tank having an inlet for receiving water;
The filth distribution unit according to claim 3, further comprising: a tubular first overflow water outlet channel that is connected to the outlet and extends toward the inlet. An electric water heater,
An expansion water discharge passage for discharging the expansion water of the electric water heater;
A second overflow water outlet channel through which overflow water led out from the outlet port circulates;
A merged discharge flow path in which the expanded water flowing through the expanded water discharge flow path and the overflow water flowing through the second overflow water outlet flow path merge and flow;
The waste logistics unit according to claim 3 provided with the drain trap connected to the lower stream side of said confluence discharge channel.

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