JP2008307251A - Cold water exhausting device in water discharge facility - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cold water exhausting device which can discharge the remaining water in a cold water status with cold water within piping in a short time even if the remaining water is abundant, has a simple mechanism, and requires a low cost. <P>SOLUTION: A switching valve 72, which changes watering to an overhead shower water emitting section 22 or the first bifurcation passage 68, is formed in the bifurcation section of the first bifurcation passage 68 by branching the first bifurcation passage 68 from a shower water passage 54 of watering to the overhead shower water emitting section 22 and branching the second bifurcation passage 70 from the downstream part rather than the first bifurcation passage 68 and the first bifurcation passage 68 and the second bifurcation passage 70 are connected to a cold water discharge valve 82. The cold water discharge valve 82 has the first valve body which opens the first discharge passage 74 which discharges watering to the first bifurcation passage 68, the second valve body which opens the second discharge passage 76 which discharges water remaining on the side of the overhead shower water emitting section 22, which is guided through the second bifurcation passage 70, and a connection means which performs the open operation of these valve bodies with interlocking. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a cold water discharge apparatus in a water discharge facility, and more particularly to a cold water discharge apparatus that can prevent cold water from being discharged at the initial stage of water discharge from a water discharge section such as a shower water discharge section.

  There is a water discharge facility that mixes water (cold water) and hot water (hot water) in the hot water mixing section, and discharges hot water from the water discharge section, especially a long shower water passage (main water supply passage) from the hot water mixing section. In the shower water discharge facility that extends and showers water from the shower water discharge unit connected to the tip of the shower water, cold water is discharged at the initial stage when the temperature-controlled hot water is discharged from the shower water discharge unit. There's a problem.

This initial cold water discharge is performed after the cold water (cold water in the pipe) staying in the pipe upstream of the mixing section (hot water supply pipe) is discharged in the initial stage and after the use of the water discharge equipment is finished. This is a phenomenon that occurs when hot water remaining in the water passage, the shower water discharge portion, etc. stays as cold water (residual water) and is discharged in the initial stage.
If a user accidentally bathes such cold water, he will feel uncomfortable.
For example, Patent Document 1 and Patent Document 2 listed below are intended to solve this problem.
FIG. 8 specifically shows what is disclosed in Patent Document 1.

In FIG. 8, 200 is a hot and cold water mixing faucet, 202 is a faucet body incorporating a hot and cold water mixing valve (mixing part), 204 is a water discharge pipe (caran), 206 is a shower hose, and a shower whose illustration is omitted at the tip thereof. A head (shower water discharger) is connected.
210 is a switching handle for switching between water discharged from the water discharge pipe 204 and water discharged from the shower head, and 212 is a switching valve.
Reference numeral 214 denotes a cold water discharge device provided between the shower hose 206 and the faucet body 202, and includes a casing 216 and a suction pipe 218.

The casing 216 is provided with a discharge port 220. Inside the casing 216 is a valve body 222 formed of a spool valve body that opens and closes the discharge port 220, and expands and contracts in the axial direction in response to the temperature of the water supply. A temperature sensing body 223 for driving 222 is provided.
The temperature sensing element 223 is a thermo wax type that expands and contracts in the axial direction by utilizing expansion and contraction of wax.
In the figure, reference numeral 224 denotes a shower water passage (main passage) formed inside the shower hose 206 and the casing 216.

In the cold water discharger 214 shown in FIG. 8, when the temperature of the water supply flowing through the shower water passage 224 is low when shower water is discharged from the shower head, the temperature sensing body 223 is in a contracted state, and FIG. As shown, the valve body 222 is in a state in which the discharge hole 220 is opened by the upward urging force of the spring 208, so that the water supplied from the faucet body 202 into the shower water passage 224 is discharged from the discharge port 220 of the casing 216. It is discharged outside and not supplied to the shower head.
That is, the cold water staying in the pipe on the upstream side of the faucet body 202 is discharged from the discharge port 220 in the upstream portion without being discharged from the shower head.

  At this time, due to the negative pressure acting on the suction pipe 218, the remaining water in the cold water state remaining in the shower hose 206 and the shower head is sucked to the shower water passage 224 side through the suction pipe 218 and is discharged from the discharge port 220 of the casing 216. It is discharged outside.

  Then, when the temperature of the water supply in the shower water passage 224 becomes hot water, the temperature sensing body 223 expands and the valve body 222 closes the discharge port 220 as shown in FIG. The hot water that has come is supplied to the shower head through the shower hose 206, and shower water is discharged from there.

FIG. 9 shows what is disclosed in Patent Document 2. In the figure, 226 is a hot and cold water mixing faucet, 228 is a faucet body, a shower hose 206 extends from the faucet body 228, and a shower is provided at the tip of the faucet. A head 230 is connected.
Also in this example, a cold water discharge device 232 is provided on the shower water passage in the same manner as that shown in FIG.

FIG. 10 shows the internal structure of the cold water discharge device 232.
As shown in the figure, the cold water discharge device 232 includes a casing 234, a valve body 236 provided therein, and a temperature sensitive spring made of a shape memory alloy that urges the valve body 236 in the right direction in the figure. 238, a bias spring 240 that urges the valve body 236 to the left in the opposite direction, a shower opening / closing valve 242 that opens and closes the shower water passage 224, and a ball valve 244 (see FIG. 10 (A)).

In the cold water discharge device 232 shown in FIG. 9 and FIG. 10, when the water supplied to the shower head 230 side through the shower water passage (main passage) 224 is cold water, the valve body 236 is contracted by the temperature-sensitive spring 238. Becomes a valve open state, and cold water (cold water in the pipe) is discharged from the discharge port 220.
At this time, the shower opening / closing valve 242 is in a closed state, and the ball valve 244 is in a closed state by the supply water pressure, and the shower water passage is closed halfway. Therefore, at this time, cold water is supplied to the shower head. Not.

  When the temperature of the water supply rises to a desired level of hot water, the temperature sensing spring 238 increases the urging force to close the valve body 236 (the shower opening / closing valve 242 is opened), and water supply from the discharge port 220 is performed. Stop discharging. Therefore, at this time, hot water having a target temperature is supplied to the shower head, and shower water is discharged from the shower head 230 (FIG. 10B).

  Thereafter, the shower water discharge from the shower head 230 is stopped, and when the remaining water remaining in the shower hose 206 and the shower head 230 becomes cold water, the valve body 236 is opened again, and the remaining water pushes the ball valve 244 open. Then, it is discharged from the discharge port 220 (FIG. 10C).

  However, the one disclosed in Patent Document 1 is designed to discharge the initial cold water in the pipe, the shower head, and the remaining water on the shower hose side at the same time using a single discharge passage and a single valve body. In addition, since the residual water on the shower head side is sucked and discharged through the suction pipe 218 of the thin tube by the action of negative pressure, it is long especially in the case of water discharge equipment with a large amount of residual water for discharging cold water. It takes time.

Further, in the one disclosed in Patent Document 1, the valve body is opened and closed based on the temperature sensing of the water supply by the temperature sensing element. The mechanism becomes complicated and the required cost increases.
Further, by incorporating a valve mechanism having a complicated structure on the shower water passage (main passage) 224, the resistance of the flow in the shower water passage 224 increases, which may lead to a decrease in the water discharge pressure from the shower head. is there.

  This point is basically the same as that disclosed in Patent Document 2 in which the discharge of the cold water and the stop of the discharge are performed on the shower water passage which is the main passage based on the temperature sensing of the water supply, as in Patent Document 1. The same.

  Although the problem at the time of shower water discharge from the shower water discharge part was described above, such a problem is a problem that can occur in common when discharging water from a water discharge part other than the shower water discharge part.

Japanese Patent Laid-Open No. 3-18332 JP 2004-283455 A

  The present invention is based on the circumstances as described above, and even if there is a large amount of residual water, the residual water in the cold water state can be discharged together with the cold water in the pipe in a short time, and a valve for discharging the cold water on the main passage is provided. The object of the present invention is to provide a cold water discharge device having a simple structure and low cost, which does not cause flow resistance by the mechanism.

  Thus, according to the first aspect, the first branch passage is branched from the main passage of the water supply to the water discharge section, and the second branch passage is branched from the downstream portion of the first branch passage, so that the first A switching valve for switching the water supply to the water discharge portion or the first branch passage is provided at a branch portion of the branch passage, the first branch passage and the second branch passage are connected to a cold water discharge valve, and the cold water discharge valve The first valve body that opens the first discharge passage for discharging the water supply to the first branch passage by receiving the water supply pressure of the first branch passage, and the water discharge section side guided through the second branch passage. A second valve body for opening the second discharge passage for discharging the remaining residual water, and a connecting means for opening the first valve body and the second valve body in conjunction with each other are provided.

  According to a second aspect of the present invention, in the first aspect, the cold water discharge valve is provided with a biasing means for biasing the second valve body together with the first valve body in a valve closing direction.

  According to a third aspect of the present invention, in any one of the first and second aspects, the first valve body is a diaphragm valve body.

  According to a fourth aspect of the present invention, in any one of the first to third aspects, the first discharge passage and the second discharge passage are joined in the middle to reach a discharge port. A mechanism for preventing the backflow of discharged water to the second discharge passage is provided.

  According to a fifth aspect of the present invention, in the fourth aspect, the backflow prevention mechanism generates a negative pressure at the junction of the second discharge passage with the first discharge passage due to the flow of discharged water of the first discharge passage. Thus, the discharge water of the second discharge passage is sucked by the action of the negative pressure and merged with the discharge water of the first discharge passage.

Effects and effects of the invention

  As described above, according to the first aspect of the present invention, the first branch passage is branched from the main water supply passage and the second branch passage is branched from the downstream portion thereof, and water is supplied to the branch portion of the first branch passage. A first discharge passage for providing a switching valve for switching to one branch passage, connecting the first branch passage and the second branch passage to a cold water discharge valve, and discharging the cold water discharge valve to supply water to the first branch passage A first valve body that is opened by receiving the supply water pressure of the first branch passage, a second valve body that is guided through the second branch passage and that opens the discharge passage of the remaining water remaining on the water discharger side, And a connecting means for opening operation.

According to the cold water discharge device of this first aspect, the cold water in the pipe staying in the pipe on the upstream side and the remaining water in the cold water state remaining on the water discharge section side are divided into the first branch passage and the first discharge passage. And in the water discharge equipment which can be discharged simultaneously through the second branch passage and the second discharge passage, and a large amount of residual water remains, cold water can be discharged quickly in a short time.
That is, the desired temperature-controlled hot water can be discharged from the water discharger in a short time, and the waiting time of the user can be shortened.

According to the first aspect of the present invention, the chilled water discharge valve is not provided on the main passage, but the first branch passage and the second branch passage are branched from the main passage, and the chilled water discharge valve is provided on the connection side of the branch portions. Since the cold water discharge is performed by the switching operation by the switching valve on the main passage, the structure of the cold water discharge device is not required without the need for a complicated switching mechanism using a temperature sensing element as in the prior art. It can be simplified and the required cost can be reduced.
Further, in this first aspect, since the chilled water discharge valve is not provided on the main passage, a flow resistance is generated by the chilled water discharge valve provided on the main passage, which reduces the discharge pressure from the discharge portion. It is possible to avoid problems that are connected.

  According to the first aspect of the present invention, by switching the switching valve to the water discharger side, the water pressure of the water supplied to the water discharger side can be applied as a force in the valve closing direction of the second valve body.

In this case, the cold water discharge valve may be provided with a biasing means for biasing the second valve body together with the first valve body in the valve closing direction (Claim 2).
If it does in this way, when water supply is switched to the water discharging part side, a 2nd valve body can be closed with stronger force.
Here, a metal spring, particularly a coil spring can be suitably used as the biasing means.

In the present invention, the first valve body can be a diaphragm valve body (Claim 3).
If it does in this way, the pressure of the feed water led to the 1st branch passage will be received in the 1st valve body effectively, and the pressure of the feed water will act as the force of the valve opening direction of the 1st valve body and the 2nd valve body Can be made.

Next, according to a fourth aspect of the present invention, the first discharge passage and the second discharge passage are joined in the middle to reach the discharge port, and the backflow of discharged water from the first discharge passage to the second discharge passage. A prevention mechanism is provided.
This backflow prevention mechanism has the following meaning.
That is, a large amount of discharged water circulates in the first discharge passage vigorously due to the supply water pressure. For this reason, there is a risk that the discharged water on the first discharge passage side will flow back to the second discharge passage side at the junction of the first discharge passage and the second discharge passage.
However, such inconvenience can be avoided by providing a backflow prevention mechanism according to the fourth aspect.

In this case, the backflow prevention mechanism can be constituted by a check valve. However, according to claim 5, the backflow prevention mechanism is connected to the junction of the second discharge passage by the flow of discharged water from the first discharge passage. It is possible to generate a negative pressure, suck the discharged water from the second discharge passage by the action of the negative pressure, and merge it with the discharged water from the first discharge passage (Claim 5).
In this way, it is possible to effectively prevent backflow from the first discharge passage to the second discharge passage without using a valve body to prevent backflow.
In addition, the backflow prevention mechanism can be configured with a simple structure at low cost.

Next, embodiments of the present invention will be described in detail with reference to the drawings.
In FIG. 1, 10 is the water discharge equipment of this embodiment, 12 is a shower tower which is vertically long and tall, and here the shower tower 12 has a height of about 1950 mm from the floor surface.
On the lower surface of the shower tower 12, a water discharge pipe (curan) 16 having a water discharge port 14 at its tip is rotatably provided.
Reference numeral 18 denotes a front plate in the shower tower 12, and an overhead shower water discharge portion 22 having a shower port 20 having a large diameter is provided at the upper end portion thereof.

Further, a body shower water discharger 24 is provided between the overhead shower water discharger 22 and the water discharge pipe 16 at the lower end.
The body shower water discharger 24 has shower ports 26-1a, 26-1b, 26-1c, 26-1d, 26-1e, 26-1f, and 26-2a, which are arranged in two rows on the front plate 18. A total of 12 shower openings 26-2b, 26-2c, 26-2d, 26-2e, and 26-2f are provided.

Moreover, the hand shower water discharging part 30 which has the shower port 28 is provided in the side.
A shower hose 32 is connected to the hand shower water discharger 30, and a shower hook 34 is provided on the shower tower 12, and the hand shower water discharger 30 is hooked there.
The hand shower water discharger 30 can be used after being removed from the state hooked on the shower hook 34.

On the front plate 18 in the shower tower 12, handles 36, 38, 40, 42 and 44 are arranged in a vertical line at a position between the shower ports 26-1 and 26-2 in the body shower water discharger 24. Yes.
Each of the handles 36, 38, 40, 42, 44 is a rotary handle.

Here, the uppermost handle 36 is for turning on / off the shower water discharged from the overhead shower water discharging unit 22, and the handle 38 below the handle 38 is a shower water discharged from the body shower water discharging unit 24, specifically a shower port. 26-1a to 26-2f is for turning on / off the shower water discharge, and the lower handle 40 is for turning on / off the shower water discharge from the hand shower water discharge unit 30.
Each shower port 20, 26-1a to 26-2f, 28 is composed of a large number of water spray holes.

On the other hand, the lower handle 42 is a handle for temperature adjustment (for temperature adjustment) that adjusts the temperature of the discharged water by changing the mixing ratio of water and hot water, and the lowermost handle 44 is connected to the discharge pipe 16. It is a handle for turning on and off water discharge.
The uppermost handle 36 also serves as a handle for switching a switching valve for discharging cold water described later.

In FIG. 2, 46 is a water supply passage for supplying cold water, and 48 is a hot water supply passage for supplying hot water from a water heater. A stop cock 50 is provided on each passage.
The water supply passage 46 and the hot water supply passage 48 are connected to the mixing valve 52, and water and hot water (hot water) sent through the water supply passage 46 and the hot water supply passage 48 are mixed by the mixing valve 52, and the mixing ratio thereof is It can be changed. That is, the temperature of the discharged water is adjusted in the mixing valve 52.

  54 is a shower water passage (main passage) that guides the water supply from the mixing section 52 to the overhead shower water discharge section 22. The second shower guides the water supply from the shower water passage 54 to the body shower water discharge section 24 and the hand shower water discharge section 30. A water passage 56 and a third shower water passage 58 are branched.

The second shower water passage 56 is connected to the above-described many shower openings 26-1 a to 26-2 a in the body shower water discharge unit 24, and the third shower water passage 58 is connected to the hand shower water discharge unit 30. Yes.
An open / close valve 60 for opening and closing the second shower water passage 56 is provided on the second shower water passage 56, and an open / close valve 62 for opening and closing the second shower water passage 58 is provided on the third shower water passage 58.
Here, the on / off valve 60 is opened / closed by operating the handle 38, and the on / off valve 62 is opened / closed by operating the handle 40.

The second shower water passage 56 is branched into branch shower water passages 56-1 and 56-2, and the shower ports 26 in which the branch shower water passages 56-1 are arranged in a vertical line on the right side in the drawing. -1a, 26-1b, 26-1c, 26-1d, 26-1e and 26-1f, and branch shower water passages 56-2 are arranged in a row on the left side in the figure. 26-2b, 26-2c, 26-2d, 26-2e and 26-2f.
Here, the branch shower water passages 56-1 and 56-2 are formed inside the straight tubular bodies arranged vertically, and both are linear in the vertical direction.

Reference numeral 64 denotes a water discharge pipe passage for guiding water supply to the water discharge pipe 16, and an open / close valve 66 for opening and closing the water discharge pipe passage 64 is also provided on the water discharge pipe passage 64.
The on-off valve 66 is opened and closed by operating the handle 44 at the lowest position of the shower tower 12.

  A first branch passage 68 is also branched from the shower water passage 54 for supplying the water supplied from the mixing valve 52 to the overhead shower water discharger 22 at a portion downstream of the second shower water passage 56. The second branch passage 70 is branched from the shower water passage 54 at the downstream portion. A switching valve 72 for switching the passage is provided at the branch portion of the first branch passage 68.

  Here, the switching valve 72 shuts off the shower water passage 54 and stops supplying water to the overhead shower water discharger 22 (the state shown in FIG. 2), and supplies water from the mixing valve 52 to the first branch passage 68. The state is switched between a state (state shown in FIG. 5) and a state where water supplied from the mixing valve 52 is further supplied to the overhead shower water discharger 22 (state shown in FIG. 6). It is operated by operating the uppermost handle 36 in FIG.

Here, the second branch passage 70 is a passage for discharging the residual water that has remained in the shower water passage 54 and the shower water passage 54 that is a main passage for supplying water to the overhead shower water discharge portion 22 and has become cold water.
Each of the first branch passage 68 and the second branch passage 70 is connected to the cold water discharge valve 82 at the tip side.

From the cold water discharge valve 82, a first discharge passage 74 that discharges water supplied to the first branch passage 68 and a second discharge passage 76 that discharges residual water introduced through the second branch passage 70 extend. Yes.
Here, the first discharge passage 74 is connected to the downstream common passage 77 together with the water discharge passage 64, and reaches the water discharge port (discharge port) 14 of the water discharge tube 16.
Here, the common passage 77 becomes a part of the first discharge passage 74 when discharging the water supply to the first branch passage 68, and becomes a part of the discharge pipe passage 64 when discharging water from the discharge pipe 16. It is.

A tip of a second discharge passage 76 extending from the cold water discharge valve 82 is connected to the common passage 77 and joined together.
In the figure, reference numeral 80 denotes a joining portion between the second discharge passage 76 and the common passage 77, that is, the first discharge passage 74, and 78 denotes a joining portion between the first discharge passage 74 and the discharge pipe passage 64 on the upstream side. Represents.

FIG. 3 specifically shows the internal structure of the cold water discharge valve 82 described above.
In the figure, reference numeral 84 denotes a casing of the cold water discharge valve 82, in which a first valve body 88 and a second valve body 86 are provided so as to be openable and closable.
Here, the second valve body 86 opens the second discharge passage 76 by separating upward from the valve seat 90 in the drawing, that is, by opening, and the remaining water from the second branch passage 70 is discharged to the second discharge passage. It is possible to discharge through 76.
Further, the seating on the valve seat 90, that is, the valve closing operation, closes the second discharge passage 76 and shuts off the flow.

On the other hand, the first valve body 88 can open the first discharge passage 74 and discharge the water supplied to the first branch passage 68 through the first discharge passage 74 by the upward separation in the figure from the valve seat 92, that is, the valve opening operation. To do.
The first discharge passage 74 is closed and the flow from the first branch passage 68 to the first discharge passage 74 is blocked by the seating or closing operation on the valve seat 92.

Here, the first valve body 88 is formed of a diaphragm valve body, and includes a diaphragm film 94 formed of an elastic material such as rubber that receives the supply water pressure of the first branch passage 68. In response to the water supply pressure in the branch passage 68, the valve opens upward in the figure.
The first valve body 88 and the second valve body 86 are connected to each other by a connecting shaft 96 serving as a connecting means, and are integrally moved vertically, that is, opened and closed.

  As shown in FIG. 2, the second branch passage 70 is always in communication with the shower water passage 54 at the downstream portion of the switching valve 72, so that the shower water passage is at the time of shower water discharge from the overhead shower water discharge portion 22. Since the feed water pressure of 54 acts on the second branch passage 70, the second valve body 86 needs to be in a water-sealed valve state in order to cut off the communication between the second discharge passage 76 and the second branch passage 70 in the valve-closed state. However, the first valve body 88 does not necessarily have to be in the water-sealed valve state in the closed state.

  In the cold water discharge valve 82 shown in FIG. 3, a coil spring 97 is provided on the upper side of the second valve body 86 to normally urge it in the valve closing direction. The biasing force also acts as a biasing force in the valve closing direction of the first valve body 88 via the connecting shaft 96.

In this embodiment, the discharge water flowing through the common passage 77, that is, the first discharge passage 74 flows back to the second discharge passage 76 side at the junction 80 of the second discharge passage 76 to the common passage 77 in FIG. 2. A backflow prevention mechanism 98 (refer to FIG. 4) is provided.
As shown in FIG. 4, the backflow prevention mechanism 98 includes an inner pipe 100 that allows water in the common passage 77 to flow downward in the figure, and an annular suction passage 104 that communicates with the junction 102 on the outer peripheral side thereof. ing.

  In this backflow prevention mechanism 98, negative pressure is generated in the annular suction passage 104 and the junction 102 around the inner pipe 100 by the flow of the discharged water of the common passage 77 that flows downward in the figure in the inner pipe 100. Under the action of the negative pressure, the discharged water in the second discharge passage 76 is sucked and merged with the discharged water on the common passage 77 side, sent to the water discharge pipe 16 and discharged from the water discharge port (discharge port) 14 to the outside. .

Next, the operation of this embodiment will be described below.
FIG. 2 shows a state where the switching valve 72 blocks the shower water passage 54 and stops water supply to the overhead shower water discharge unit 22, and the switching valve 72 is operated by operating the uppermost handle 36 shown in FIG. 1 from this state. 5 is switched to the state shown in FIG. 5, the water supply from the mixing valve 52 is guided to the first branch passage 68.
Then, as shown in FIG. 7, the first valve body 88 made of a diaphragm valve body of the cold water discharge valve 82 receives the water supply pressure of the first branch passage 68 and resists the urging force of the coil spring 97 and moves upward in the figure. The opening operation is performed, and the first discharge passage 74 is opened.
At this time, the second valve body 86 is also opened in conjunction with the second discharge passage 76 to be in an open state.

Accordingly, the cold water in the pipe upstream of the mixing valve 52, specifically, the cold water in the pipe between the mixing valve 52 and the hot water heater is supplied with water from the water supply passage 46 and through the first discharge passage 74 to the water outlet 14 of the water discharge pipe 16. Is discharged to the outside.
At the same time, the remaining water in the cold water state remaining in the shower water passage 54 and the overhead shower water discharge portion 22 is discharged from the water discharge port 14 to the outside through the second discharge passage 76.

  Here, with the switching valve 72 in the state shown in FIG. 5, the water supply from the mixing valve 52 is discharged through the first discharge passage 74 and the remaining water in the shower water passage 54 and the overhead shower water discharger 22 is discharged to the second discharge passage 76. When the water is discharged through, the supply water pressure is applied to the first discharge passage 74 side, more specifically, the common passage 77 side, and a large amount of water supply flows through the common passage 77 vigorously. However, in this embodiment, since the backflow prevention mechanism 98 is provided in the junction 80, such inconvenience occurs. There is nothing.

  When the cold water in the pipe remaining in the upstream pipe and the overhead shower water discharger 22 side, specifically, the remaining water remaining in the shower water passage 54 and the overhead shower water discharger 22 are discharged, the switching valve 72 is discharged. By switching the water supply to the state shown in FIG. 6, that is, the overhead shower water discharger 22 side, warm water having a desired temperature adjusted by the mixing valve 52 from the initial stage of water discharge can be discharged from the overhead shower water discharger 22. .

  In this example, the switching valve 72 is switched from the state shown in FIG. 2 to the state shown in FIG. 6 through the state shown in FIG. 5, that is, the switching valve 72 passes through the shower water passage 54. Since the switching valve 72 passes through the state in which the water supply from the shower water passage 54 is switched to the first branch passage 68 in the middle of the state where the shower water is discharged from the overhead shower water discharge portion 22 as a communication state, the overhead shower water discharge portion 22 is passed. It is possible to effectively prevent the cold water from being discharged from the shower.

  The above is the operation when the shower water is discharged from the overhead shower water discharge unit 22. However, when the switching valve 72 is in the state shown in FIG. Water is supplied from each shower port 26-1a to 26-2f of the body shower water discharger 24, and the user can take shower water discharged from the shower ports 26-1a to 26-2f.

Further, by opening the on-off valve 62 by operating the handle 40 with the on-off valve 60 closed, shower water can be discharged from the hand shower water discharging unit 30.
Further, by opening the on-off valve 66 by operating the handle 44, water can be discharged from the water outlet 14 of the water discharge pipe 16.

In this embodiment, there is no mechanism for discharging initial cold water when water is discharged from the body shower water discharge unit 24, the hand shower water discharge unit 30, and the water discharge pipe 16, but in the case of shower water discharge from the overhead shower water discharge unit 22. It is also possible to apply the same cold water discharge device to water discharge from the body shower water discharge unit 24, the hand shower water discharge unit 30, and the water discharge pipe 16.
However, when water is discharged from the hand shower water discharge unit 30 and the water discharge pipe 16 in the initial stage, the cold water is discharged for a short time, and the adverse effects thereof are not as great as the shower water discharged from the overhead shower water discharge unit 22. Even if you do not dare to prepare, there will be no particular problems.

  However, the water discharge from the body shower water discharger 24 may cause the same problem as in the case of the shower water discharge from the overhead shower water discharger 22, but in this example, the branch shower water passage 56 on the body shower water discharger 24 side. -1 and 56-2 are vertically linear, and the remaining water in the interior is automatically discharged from the lowermost shower openings 26-1f and 26-2f to the outside, so the body shower water discharger 24 side Then, there is no such a large amount of residual water in the cold water state that warm water can be discharged from the shower from a relatively early stage.

According to the present embodiment as described above, the cold water in the pipe staying in the pipe on the upstream side of the mixing valve 52 and the remaining cold water state remaining in the shower water passage 54 and in the overhead shower water discharger 22. Water can be discharged simultaneously through the first branch passage 68 and the first discharge passage 74 and the second branch passage 70 and the second discharge passage 76, and a large amount of residual water is generated particularly on the overhead shower water discharger 22 side. Even in the remaining water discharge facility of the present embodiment, cold water can be quickly discharged in a short time.
As a result, the desired temperature-controlled hot water can be discharged from the water discharger in a short time, and the waiting time of the user can be shortened.

Further, in the present embodiment, the cold water discharge valve is not provided on the shower water passage 54, but the first branch passage 68 and the second branch passage 70 are branched from the shower water passage 54, and the cold water is connected to the connection side of these branch portions. Since the discharge valve 82 is provided and the cold water is discharged by the switching operation by the switching valve 72 on the shower water passage 54, a complicated switching mechanism using a temperature sensing element as in the prior art is not required. In addition, the structure of the cold water discharge device can be simplified, and the required cost can be reduced.
Further, in the present embodiment, since the cold water discharge valve is not provided on the shower water passage 54, a flow resistance is generated by the cold water discharge valve provided there on the shower water passage 54, which leads to a decrease in the water discharge pressure. The problem can be avoided.

In the present embodiment, by switching the switching valve 72 to the overhead shower water discharger 22 side, the water pressure of the water supplied to the overhead shower water discharger 22 side is changed in the valve closing direction of the second valve body 86 of the cold water discharge valve 82. Can act as a force.
In addition, since the cold water discharge valve 82 is provided with a coil spring 97 that urges the second valve body 86 together with the first valve body 88 in the valve closing direction, when the water supply is switched to the overhead shower water discharge section 22 side, The two-valve body 86 can be closed with a stronger force.

  In the present embodiment, since the first valve body 88 is a diaphragm valve body, the pressure of the water supplied to the first branch passage 68 is effectively received by the first valve body 88, and the pressure of the water supplied is the first. The valve body 88 and the second valve body 86 can act as a force in the valve opening direction.

  Furthermore, in this embodiment, the backflow prevention mechanism 98 causes the discharged water on the first discharge passage 74 side to flow back to the second discharge passage 76 side at the junction of the first discharge passage 74 and the second discharge passage 76. This can be effectively prevented, and the backflow prevention mechanism 98 can be configured with a simple structure at low cost.

  Although the embodiment of the present invention has been described in detail above, this is merely an example. For example, in the present invention, the backflow prevention mechanism serves as a check valve, and this joins the first discharge passage and the second discharge passage. The present invention can be configured in various forms without departing from the gist of the present invention, such as being provided upstream of the merging portion of the second discharge passage 76 or the merging portion of the second discharge passage 76.

It is a front view which shows the water discharging equipment provided with the cold water discharging apparatus which is one Embodiment of this invention. It is the figure which showed typically the piping path | route in the same embodiment. It is sectional drawing of the cold water discharge valve in the embodiment. It is the figure which showed the backflow prevention mechanism in the same embodiment. It is operation | movement explanatory drawing of the embodiment. It is explanatory drawing of the action state different from FIG. It is action | operation explanatory drawing of the cold water discharge valve in the embodiment. It is the figure which showed an example of the conventionally well-known cold water discharging apparatus. It is the figure which showed the conventionally well-known cold water discharge | emission apparatus different from FIG. It is a figure showing the operation state of the cold water discharging apparatus of FIG.

Explanation of symbols

22 Overhead shower water discharge part 54 Shower water passage (main passage)
68 First branch passage 70 Second branch passage 72 Switching valve 74 First discharge passage 76 Second discharge passage 82 Chilled water discharge valve 86 Second valve body 88 First valve body 94 Diaphragm film 96 Connection shaft 97 Coil spring 98 Backflow prevention mechanism 102 junction

Claims (5)

The first branch passage is branched from the main passage of water supply to the water discharge section, and the second branch passage is branched from the downstream portion of the first branch passage, and water is supplied to the branch portion of the first branch passage. A switching valve for switching to the water discharge part or the first branch passage is provided, and the first branch passage and the second branch passage are connected to a cold water discharge valve,
The cold water discharge valve is guided through a first valve body that opens a first discharge passage for discharging water supplied to the first branch passage in response to a supply water pressure of the first branch passage, and the second branch passage, A second valve body that opens a second discharge passage for discharging residual water remaining on the water discharger side, and a coupling means that opens the first valve body and the second valve body in conjunction with each other. A cold water discharge device in a water discharge facility.   2. The chilled water discharge device according to claim 1, wherein the chilled water discharge valve is provided with urging means for urging the second valve body together with the first valve body in a valve closing direction.   The chilled water discharge device in a water discharge facility according to claim 1, wherein the first valve body is a diaphragm valve body.   The discharge from the first discharge passage to the second discharge passage according to any one of claims 1 to 3, wherein the first discharge passage and the second discharge passage are joined together to reach a discharge port. A cold water discharge device in a water discharge facility, wherein a water backflow prevention mechanism is provided.   5. The backflow prevention mechanism according to claim 4, wherein the backflow prevention mechanism generates a negative pressure at a junction of the second discharge passage with the first discharge passage by the flow of the discharge water of the first discharge passage. A cold water discharge device in a water discharge facility, wherein the discharge water of the second discharge passage is sucked by the action and merged with the discharge water of the first discharge passage.

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