JP4675460B2 - Water tap - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
Each of the present invention comprises an inflow path through which hot water or water is supplied from a faucet body, a plurality of outflow paths communicating with the inflow path via a valve port, and a valve body provided on the primary side of the valve port. The present invention relates to a water faucet provided with a water discharger having a switching valve device that opens and closes a valve port and switches communication with the inflow path to any of the outflow paths.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there is a faucet equipped with a water discharge tool such as a shower head that can switch the water discharge form to a bundle of concentrated water discharge or shower water discharge, for example. Here, the switching is performed by any one of an inflow path to which hot water or water is supplied from the faucet body and a plurality of outflow paths to a water outlet that performs bundled concentrated water discharge or a water outlet that performs shower water discharge. Usually, this is performed by a switching valve device for appropriately switching the communication. And each said outflow path is connected with the inflow path via the valve port, and as a switching valve apparatus, the spherical valve body which moves between each valve port, obstructs one valve port, and opens the other The thing provided with is generally employ | adopted. In such a switching valve device, generally, the valve body is disposed on the primary side of the valve port.
[0003]
[Problems to be solved by the invention]
The valve body is driven by operation of an operation unit such as a switching button provided on the water discharger. However, in the conventional water tap, the valve body of the switching valve device is disposed on the primary side of the valve port. Therefore, the valve element that closes the desired valve opening is subjected to stress in the seating direction due to the pressure of hot water or water supplied from the faucet body, that is, the water supply pressure, and the valve element is pressed against the valve opening. It becomes a state. And as the feed water pressure increases, the stress increases, so that the operation load of the operation unit becomes heavier. As described above, the conventional water tap has a problem that the operability of switching deteriorates when the water supply pressure increases. In particular, recently, many water faucets equipped with water faucets capable of switching various water discharge forms have been known, but such water faucets require a complicated mechanism for switching. Therefore, the operation load tends to be heavy, and the influence on the operability due to the water supply pressure becomes remarkable.
[0004]
Japanese Patent Application Laid-Open No. 2000-96643 describes a water faucet provided with a shower head having a switching valve device and a pressure reducing valve on the upstream side of the faucet body. In such a faucet, since the feed water pressure can be reduced on the upstream side of the faucet body, only the reduced feed water pressure is applied to the valve body of the switching valve device of the water discharger, and the switching operation load Can be prevented from becoming unnecessarily heavy. However, this faucet causes the following problems.
[0005]
The water faucet described in Japanese Patent Laid-Open No. 2000-96643 is a ceramic in order to prevent a high water supply pressure from being applied to a ceramic cartridge having a fixed plate and a movable plate in a state where water is stopped by a handle of a shower head. A pressure reducing valve is attached to the upstream side of the cartridge. For this reason, when it is intended to provide a pressure reducing valve on an existing water faucet, the pressure reducing valve must be incorporated into the pipe portion on the upstream side of the water faucet body that is normally concealed, and the work is large and complicated. Become. Therefore, it cannot be easily applied to an existing water faucet. In addition, large-scale and complicated work is required for repair and maintenance of the pressure reducing valve.
[0006]
In addition, as the pressure reducing valve, a valve that completely closes the flow path in a state where the feed water pressure is high must be employed. This is because if the flow path is not completely closed, a water supply pressure that is not reduced in pressure is applied to the ceramic cartridge in a state where water is stopped on the shower head side. Therefore, a pressure reducing valve having a complicated structure must be employed, and the entire water faucet is expensive.
[0007]
Each of the present invention solves the above-mentioned problems of the conventional water faucet, and can provide a water faucet that does not deteriorate the operability of switching even if the feed water pressure is high, with a simple structure. It aims at making it easy to apply also to the faucet.
[0008]
[Means for Solving the Problems]
  In order to solve the above problems, means taken by the present invention will be described below. The water faucet according to claim 1 of the present invention includes: “an inflow passage through which hot water or water is supplied from the faucet body; a plurality of outflow passages communicating with the inflow passage through the valve opening; And a switching valve device that opens and closes a valve port by a valve body provided on the primary side and switches the communication with the inflow path to any one of the outflow paths. And a pressure reducing device for reducing the pressure on the secondary side between the faucet body and the switching valve device.In the decompression device, the casing is formed in a substantially cylindrical shape, and a cylindrical portion is provided at a central portion of the casing. The cylindrical portion is supported by a plurality of beams, and a decompression flow path is provided between the adjacent beams. And a plurality of protrusions projecting in the direction of the cylindrical part on the inner peripheral surface of the casing, and an elastically deformable ring-shaped decompression body is attached to the outer periphery of the cylindrical partIt is a hydrant characterized by that.
[0009]
Here, the “switching valve device” refers to a device provided with a valve mechanism capable of switching the flow path by opening or closing the flow path with a valve body to perform water flow or water stoppage. Specifically, a spherical valve element that moves between a plurality of valve openings, a cylindrical valve element that is inserted into a cylindrical member that constitutes the valve opening, and that opens and closes the valve opening by sliding. Can be illustrated. In addition, the “pressure reduction device” is a device that reduces the flow rate by reducing the opening of the flow path, thereby reducing the pressure on the secondary side, or has a large resistance to hot water or water that circulates as the feed water pressure increases. An example is one in which the flow rate is reduced by a resistance member that gives the pressure, thereby lowering the pressure on the secondary side.
[0010]
In the present invention, the valve body provided on the primary side of the valve port employs a switching valve device that switches the outflow channel communicating with the inflow channel by selectively opening and closing the valve ports of the plurality of outflow channels. The switching valve device switches the water discharge form such as shower water spray and straight water discharge. In such a switching valve device, at the time of water discharge, water is supplied from the opened specific valve port, and accordingly, water supply pressure is applied to the valve body that closes any other valve port. The valve body is crimped to the valve opening. Therefore, by providing the pressure reducing device as described above, it is possible to prevent pressure above a certain level from being applied to the valve body.
[0011]
In the present invention, a “pressure reducing device” is provided between the faucet body and the switching valve device. Therefore, when incorporating the decompression device into the existing faucet, the work on the upstream side of the faucet body, which is likely to be complicated, is not necessary, and the decompression device can be incorporated by a simple work on the downstream side of the faucet body. . In addition, since the downstream side of the faucet body is an easy-to-work part, maintenance of the decompression device and the like can be easily performed. Furthermore, since the water supply pressure is applied to the valve body that closes the specific valve port in a state where hot water or water is flowing through the valve port, the pressure reducing device can be used in a state where hot water or water is flowing. What is necessary is just to reduce water supply pressure. Thus, not only a structure that completely closes the flow path and lowers the feed water pressure, but also a simple and inexpensive structure that does not completely close the flow path can be adopted as the decompression device.
[0012]
In addition, as “a mode including a pressure reducing device between the faucet body and the switching valve device”, a mode in which the pressure reducing device is incorporated in the water faucet itself, and when the water spouting device is connected to the water faucet body via a hose. Examples include a mode in which a pressure reducing device is incorporated in the hose itself, a mode in which a pressure reducing device is incorporated in a connecting portion between a faucet body and a hose, a mode in which a pressure reducing device is incorporated in a connecting portion between a hose and a water discharger, and the like. In addition, when applied to an existing water faucet, the water discharger itself or the hose itself in which the pressure reduction device is incorporated is replaced, or the pressure reduction device is installed between the water faucet body and the hose or between the water discharger and the hose. Add it.
[0013]
By the way, as in the invention described in claim 2, it is preferable to apply the invention described in claim 1 to a water faucet of “a structure in which a valve body has a spherical portion that fits into a valve port”.
[0014]
The valve body is moved between a plurality of valve openings to open desired valve openings and close other valve openings, while the valve openings are formed of an elastic material such as rubber or flexible resin. In addition, there is a switching valve device in which a spherical portion is provided in a part of a valve body seated on the valve port so that the valve port can be securely closed by fitting the valve body into the valve port. . In such a switching valve device, when the valve body is moved from one switching position to another switching position, it is necessary to move the valve body to the location of another valve opening. Here, when the valve body is moved, it is necessary to temporarily ride the valve body fitted in the valve opening in a direction away from the valve opening as described above, and a large force is required for the operation. Therefore, when the invention according to claim 1 is applied to the water tap using the switching valve device in which the valve body is fitted into the valve opening in this manner, it is preferable that deterioration in operability at a high water supply pressure can be avoided. The term “spherical surface portion” is intended to include those in which the entire valve body is spherical and also includes a part of the valve body having a spherical surface.
[0015]
The water tap according to claim 3 of the present invention is “the water tap according to claim 1 or 2, wherein the pressure reducing device is built in the water discharger”.
[0016]
If the pressure reducing device is built in the water discharger, only the water discharger needs to be removed and replaced when applied to an existing faucet. Also, the maintenance of the decompression device is sufficient if only the water discharger is removed. Therefore, it becomes easier to apply to the existing water faucet.
[0017]
  MaIn addition, the decompression device is provided with a decompression body that is elastically deformed by the supply water pressure and reduces the opening amount of the decompression flow path.It can also be.
[0018]
In a decompression device that operates by a mechanical mechanism such as a cylinder mechanism using a spring, the structure becomes complicated and the whole size increases. On the other hand, in this invention, a decompression device can be made into a simple mechanism by employ | adopting the decompression body which deform | transforms elastically. Therefore, for example, even if this decompression device is incorporated in the water discharger, it is possible to avoid an increase in the size of the water discharger itself, and the feeling of use of the water discharger is not impaired. As the decompression body, an O-ring or the like can be specifically exemplified. Such a decompression body is set to a size or elasticity that elastically deforms so as to block the decompression flow path when the feed water pressure increases, What is necessary is just to attach to the decompression flow path to open. In addition, a structure in which the decompression channel is not completely closed by the decompression body is preferable because a decompression device having a simpler structure can be obtained.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
  Next, from claim 1 to claimItem 3Embodiments of a water faucet to which the above inventions are applied will be described in detail with reference to FIGS. As shown in FIG. 1, the water discharger 1 is connected to a faucet body (not shown) of a water faucet through a hose 2. In this example, a handheld shower head is applied as the water discharger 1. ing. Moreover, the engaging part 4 which can be attached or detached to the support provided in the faucet body or the support provided separately from the faucet body is provided on the base end side of the main body 3 of the water discharger 1. The water discharger 1 is supported by the supporter so that it can be pulled out together with the hose 2. Further, the water discharger 1 has a pressure reducing device 60 built in the main body 3, and a switching valve device 31 described later is built in the downstream side of the pressure reducing device 60. And at the front-end | tip of the main-body part 3, the three operation buttons A, B, and C for driving the switching valve apparatus 31 and performing the switching operation of the water discharge form from the water discharging tool 1 are provided. A face 10 is attached to the lower surface of the main body 3. As described above, in the aspect in which the water discharger 1 is supported by the supporter so that it can be pulled out together with the hose 2, the connection part between the hose 2 and the faucet body, the connection part between the hose 2 and the water discharger 1, or the hose 2 itself. It is difficult to incorporate the decompression device 60 into Therefore, it is preferable to incorporate the decompression device 60 in the water discharger 1 itself.
[0020]
Referring to FIG. 1 and FIG. 5, a first flow path 11 b, a second flow path 11 c, and a third flow path 11 a that are partitioned in the face 10 are provided in order from the center to the outside. Each of these flow paths 11b, 11c, and 11a constitutes “a plurality of outflow paths” in each invention. The face 10 is provided with a concentrated water outlet 12 at the approximate center for discharging water that is rectified and concentrated in a bundle. A foam unit 54 is attached to the inside of the concentrated water outlet 12, and hot water and water flowing from the first flow passage 11 b provided at the back of the central water outlet 12 through the hose 2 from the water faucet are the foam unit 54. After passing through, it is discharged as concentrated water discharge mixed with air.
[0021]
On the surface of the face 10 around the central spout 12, a first sprinkler 14 arranged in a circumferential shape is provided. The first water sprinkling portion 14 has a large number of water sprinkling holes 16 communicating with the second flow path 11c. The water sprinkling holes 16 are formed in parallel with the axis of the face 10 in the water discharge direction, and straight water sprinkling can be performed from the many water sprinkling holes 16.
[0022]
Further, around the first water sprinkling portion 14, a second water sprinkling portion 18 that is similarly arranged circumferentially is provided. A large number of outward sprinkling holes 21 and sprinkling holes 22 communicating with the third flow path 11 a are formed in the second sprinkling portion 18. As shown in FIG. 1, the outward sprinkling holes 21 are formed in a circumferential shape near the outer periphery of the sprinkling portion 18, and the sprinkling holes 22 are formed in a circumferential shape near the inner periphery.
[0023]
Each outward sprinkling hole 21 is formed outward with respect to the axis of the face 10 in the direction of water discharge, and at an angle of about 10 to 30 degrees with respect to the axis of the face 10 in the direction of water discharge toward the outer periphery of the face 10. Hot water or water is discharged.
[0024]
The water spray holes 22 are formed of three types of water spray holes formed at different angles with respect to the axis of the face 10 in the water discharge direction. These water spray holes 22 discharge water at an angle of about 5 to 15 ° in the outer peripheral direction of the face 10, approximately parallel to the axis of the water discharge direction of the face 10, and at an angle of about 1 to 5 ° in the inner peripheral direction of the face 10. Configured to do.
[0025]
In the 2nd sprinkling part 18, from the outward sprinkling hole 21 provided near the outer periphery of the 2nd sprinkling part 18, watering is performed at a large outward angle from the axial center of the spouting direction of the water spouting tool 1, and the sprinkling hole From 22, water is sprayed at a small outward angle, parallel to the axial center, and inward with respect to the axial center. Accordingly, the sprinkling from the entire second water sprinkling portion 18 has a larger outer diameter and a smaller inner diameter at a position away from the water spouting device 1, and the sprinkling shape as a whole is also sprinkled between these water spouting. The area increases as the size increases. With the sprinkling from the second sprinkling unit 18 configured in this way, for example, even a large round dish can spread the sprinkling over the entire dish in a short amount of time and amount of hot and cold water. Pre-washing can be performed quickly.
[0026]
Moreover, since the most outward sprinkling holes 21 are provided on the outermost side of the face 10 (about one half of the total number of sprinkling holes provided in the first sprinkling part 18), water discharge from the second sprinkling part 18 is selected. When this occurs, the outermost water discharge becomes close to a film and the breakage is reduced. Therefore, when removing dirt on an object to be cleaned such as a dish, the dirt can be quickly washed away at a time, and the dirt can be made difficult to remain. Moreover, since not only the outward sprinkling hole 21 but also the sprinkling hole 22 that sprinkles inward, and also the sprinkling hole 22 that is spouted between the two, the sprinkling from the second sprinkling part 18 is more It is performed evenly and quick cleaning is possible. Furthermore, since the water sprinkling holes 22 for sprinkling slightly outside are also provided, water spraying from the second water sprinkling part 18 is performed more evenly and quick cleaning is possible.
[0027]
Next, a switching valve device for switching the water discharge form from the water discharger 1 will be described with reference to FIGS. 6 to 8. As shown in FIG. 8, in this water discharging tool 1, the concentrated water discharging from the concentrated water outlet 12 (refer FIG. 8 (a)), the straight watering (refer FIG. 8 (b)) from the 1st watering part 14, 2nd The diffused shower water spray (refer FIG.8 (c)) from the water spray part 18 can each be performed.
[0028]
As shown in FIG. 6, at the tip of the water discharger 1, three operation units A, B, and C for switching between the three types of water discharge modes described above are provided. The operation units A, B, and C are attached to the tip of the water discharger 1 so as to surround the tip of the water discharger 1 in a semicircular shape in order from the left side of the front view. By arranging the operation units A, B, and C in this way, when the water discharge tool 1 is held by hand, the operation units A, B, and C can be naturally operated with the fingers of the held hand. The operability of the operation units A, B, and C can be improved. The operation units A, B, and C are of a push type that is operated so as to be pushed inward of the water discharge tool 1. Water is discharged from the second water sprinkling unit 18 by pushing operation of these operation parts A, from the central water spout 12 by pushing operation of the operation part B, and from the first water sprinkling part 14 by pushing operation of the operation part C. It is comprised so that water discharge may be performed.
[0029]
The operation parts A and C are attached to the recesses 26 provided on both sides of the water discharger 1 so as to be slidable. When the operation parts A and C are pushed in, the operation parts A and C are placed inside the recesses 26. C is provided to be buried. Similarly, the operation part B is slidably attached to a recess 28 provided at the tip of the water discharger 1 so that when the operation part B is pushed in, the operation part B is buried inside the recess 28. Is provided. Thus, it is comprised so that it can be easily discriminate | determined from the state of each operation part A, B, and C which state of water discharge has been selected.
[0030]
A cylindrical insertion portion 30 is provided in the recess 26 on the back side of the operation portions A and C. The insertion portion 30 is inserted into the insertion hole 5 formed in the recess 26 so as to be slidable in a watertight state via the packing 6 attached to the outer peripheral surface thereof. And is attached so as to protrude into the inflow passage 24 communicating with the faucet body. And the front-end | tip of the insertion part 30 is axially attached via the pin 36 to the arm 34 of the valve apparatus 32 mentioned later.
[0031]
In the water discharger 1, a switching valve device 31 for switching between the three water discharge modes described above is provided. This switching valve device 31 passes through the third flow passage 11a to the second sprinkling section 18, the valve opening 7a to the first spout 11b to the central water discharge port 12, and the second flow passage 11c. A valve port 7 c that leads to the first water sprinkling unit 14 is provided. These valve ports 7 a, 7 b, 7 c are connected to the third flow path 11 a, the first flow path 11 b, the second flow path 11 c, and the inflow path 24. It is formed in the valve seat 33 arrange | positioned between. In addition, two valve devices 32 for opening and closing each valve port 7a, 7b, 7c are provided on the inflow path 24 side of each valve port 7a, 7b, 7c, that is, the primary side.
[0032]
The valve device 32 includes an arm 34 pivotably mounted in the inflow path 24 via a pin 38, and a steel ball provided at the tip of the arm 34 and biased in the direction of the valve seat 33 by a spring 41. And a valve case 42 that accommodates the valve body 40 (see FIG. 4). Here, the arm 34 is formed in a substantially square shape, and the tip side of the pin 38 is a support arm 44 and the other end side is an engagement arm 46. A protrusion 47 is provided upward at the tip of the engagement arm 46 on the operation portion A side, while a protrusion 48 is provided downward on the tip of the engagement arm 46 on the operation portion B side. It has been. The engaging arms 46 are each extended so as to overlap the upper side or the lower side of the operation part B, but also when the engaging arm 46 is swung in the front-rear direction when viewed from the distal end side of the water discharger 1. It is formed at a height that does not interfere with each other. With such a configuration, the support arm 44 is configured to swing inward of the water discharger 1 with the pin 38 as a fulcrum by the pushing operation of the operation portions A and C.
[0033]
On the other hand, an operation unit B provided between the operation units A and C is attached to the water discharger 1 so as to be freely movable. On the rear end side of the operation portion B, a protrusion 52 having a long hole 50 in which the protrusions 47 and 48 of the engagement arm 46 are slidably engaged is provided. The projecting portion 52 is slidably inserted in a watertight state through the packing 6 attached to the outer peripheral surface of the insertion hole 5 formed in the recess 28, and is attached so as to project into the inflow path 24. Yes. The engaging arm 46 is configured to swing in the direction of the valve seat 33 with the pin 38 as a fulcrum through the protrusions 47 and 48 by the pushing operation of the operation portion B.
[0034]
The operation of the switching valve device 31 configured as described above will be described. As shown in FIG. 6, when the operation portion B is pushed in, the engaging arm 46 is pressed against the inner wall surface on the proximal end side of the protruding portion 52 in the long hole 50 and swings, and accordingly, the pin 38 is used as a fulcrum. The valve device 32 is swung, the valve port 7a is closed by the valve device 32 on the operation unit A side, the valve port 7c is closed by the valve device 32 on the operation unit C side, and the valve port 7b is opened. Thereby, the operation parts A and C connected by the pin 36 move in the protruding direction.
[0035]
On the other hand, when the operation portion C is pushed in, as shown in FIG. 7, the valve device 32 on the operation portion C side attached to the insertion portion 30 is swung to open the valve port 7c and to open the valve port. 7b is closed. At this time, the protrusion 52 of the operation unit B is pushed by the engagement arm 46 of the valve device 32 on the operation unit C side, and the operation unit B moves in the distal direction of the water discharger 1. Although illustration is omitted, when the operation part A is pushed in from the state where the operation part C is pushed in, the valve device 32 on the operation part A side is swung through the insertion part 30 and the valve port 7a is opened. At the same time, the valve port 7b is closed. At this time, the valve case 42 of the valve device 32 on the operation unit C side is pushed by the valve case 42 of the valve device 32 on the operation unit A side, and the valve device 32 on the operation unit C side closes the valve port 7c. Rocks. Accordingly, the operation unit C moves in the protruding direction through the insertion unit 30.
[0036]
In this way, when the operating part A is pushed, the valve port 7a leading to the second watering part 18 is opened, and the shower watering diffused as shown in FIG. When it is pushed, the valve port 7b that leads to the central water spouting port 12 is opened, and central water jetting is performed as shown in FIG. 8A, and when the operation unit C is pushed, the valve port that leads to the first water sprinkling unit 14 7c is opened and straight watering is performed as shown in FIG. 8 (b).
[0037]
Next, the decompression device 60 built in the water discharger 1 will be described. As shown in FIG. 2, the decompression device 60 has a structure in which a ring-shaped decompression body 64 is mounted in a casing 62, and is incorporated in the inflow path 24 of the water discharger 1. In this embodiment, an O-ring is employed as the decompression body 64. The casing 62 is formed in a substantially cylindrical shape, and includes a columnar portion 72 at the center portion. The columnar portion 72 is supported by a plurality of beams 70. And the decompression flow path 74 is formed between the adjacent beams 70, respectively. A plurality of protrusions 76 project from the inner peripheral surface of the casing 62 toward the cylindrical portion 72. A decompression body 64 is attached to the outer periphery of the cylindrical portion 72.
[0038]
FIG. 2 shows a state where the feed water pressure is lower than a predetermined value. In this state, an appropriate space is provided between the valve body 64 and the inner wall surface of the casing 62, and the decompression flow path 74 is greatly opened. Therefore, in this state, hot water or water smoothly flows from the primary side 66 to the secondary side 68 of the decompression device 60, and the pressure on the secondary side 68 does not decrease so much. On the other hand, when the feed water pressure increases, the decompression body 64 is elastically deformed by the feed water pressure and expands outward as shown in FIG. As a result, the decompression flow path 74 is appropriately narrowed to reduce the flow rate of hot water or water, and the pressure is reduced on the secondary side 68 of the decompression device 60. Further, when the water supply pressure on the primary side 66 falls below a predetermined value, the decompression body 64 is restored by its own elasticity (see FIG. 3), and the decompression flow path 74 returns to the normal opening amount.
[0039]
Even when the feed water pressure becomes high, the protrusion 76 provided on the inner peripheral surface of the casing 62 restricts the expansion of the decompression body 64 beyond a certain level, and the minimum opening amount of the decompression flow path 74 is ensured. The This minimum opening amount can be adjusted by the protrusion amount of the protrusion 76 in the inward direction. Further, the minimum opening amount may be adjusted by restricting the amount of elastic deformation by using protrusions of other shapes or setting the elastic force of the decompression body 64 itself, without being limited to the protrusion 76. it can.
[0040]
With such a pressure reducing device 60, even when the feed water pressure is high, the feed water pressure is reduced on the secondary side of the pressure reducing device 60, and in the switching valve device 31 provided on the secondary side of the pressure reducing device 60, The water supply pressure in the direction of the valve port 7c applied to the valve body 40 decreases. Therefore, for example, as shown in FIG. 4, the force required when the valve body 40 moves from the valve port 7c to the valve port 7b can be reduced. Accordingly, as in the example shown in FIGS. 6 and 7, the operation load when the operation unit C is pushed from the state where the operation unit B is pushed in, that is, the operation load of the switching valve device 31 is unnecessary. The operability of the switching valve device 31 is improved without increasing the weight.
[0041]
In the present embodiment, since the pressure reducing device 60 having the extremely simple structure as described above is employed, the water discharge device 1 is not enlarged even if it is built in the water discharge device 1, and the manufacturing cost is low, which is preferable. .
[0042]
  FIG.Is shown inAnotherPressure reducing device 80. The decompression device 80 is provided with a flow path 84 in a built-in piston 82 and a closing portion 90 capable of closing the flow path 84 in the vicinity of the opening 88 of the flow path 84, while the flow path 84 is opened. A spring 86 for biasing the piston 82 is provided, and when the water supply pressure on the secondary side of the pressure reducing device 80 increases, the piston 82 moves against the biasing force of the spring 86 and the opening 88 of the flow path 84 is closed. 90, the water flow rate of the flow path 84 is decreased and the secondary side water supply pressure is lowered.
[0043]
A closing portion 90 is provided in the primary flow path 96 of the decompression device 80. The closing part 90 is supported by a substantially central portion of the decompression device 80 via a beam, and a communication channel 81 penetrating the closing part 90 is provided between the closing part 90 and the inner peripheral surface of the decompression device 80. It is provided as appropriate. A piston 82 is slidably attached to the downstream side of the closing portion 90. The piston 82 has a small-diameter portion 85 near the primary flow path 96 and a flange 83 near the secondary flow path 98, and a seal member 92 is provided between the flange 83 and the inner peripheral surface of the decompression device 80. Is attached. A projecting portion 94 slidably contacting the small diameter portion 85 of the piston 82 is provided on the inner peripheral surface of the decompression device 80, and a seal member 92 is attached between the projecting portion 94 and the small diameter portion 85. A spring 86 is attached between the flange 83 of the piston 82 and the protrusion 94 on the inner peripheral surface of the pressure reducing device 80. The wall surface of the decompression device 80 where the spring 86 is attached has a through hole 96 communicating with the outside, and the space between the piston 82 to which the spring 86 is attached and the inner wall surface of the decompression device 80 is opened to the atmosphere. ing.
[0044]
As described above, when the water supply pressure of the primary side flow path 96 increases and the flow rate of hot water or water to the secondary side flow path 98 through the communication flow path 81 and the flow path 84 increases, Water pressure increases. Then, due to the water pressure applied to the flange 83 of the piston 82, the piston 82 moves in the direction of the primary flow path 96 against the urging force of the spring 86. Thereby, the opening 88 of the flow path 84 of the piston 82 is close to the closing portion 90, and the amount of hot water or water flowing into the opening 88 is reduced. Moreover, depending on the case, the opening part 88 closely_contact | adheres to the closing part 90, and stops distribution | circulation of hot water or water. In this way, the flow rate of hot water or water to the secondary side flow path 98 is reduced, and the water pressure in the secondary side flow path 98 is reduced.
[0045]
Further, when the water pressure in the secondary side flow path 98 falls below a predetermined value, the biasing force of the spring 86 is won and the piston 82 moves in the direction of the secondary side flow path 98. Along with this, the interval between the opening 88 and the closing portion 90 increases, and the flow rate of hot water or water to the secondary side flow path 98 increases. When the water pressure in the secondary flow path 98 increases to a predetermined value or more, the piston 82 moves again in the direction of the primary flow path 96 to prevent the water pressure in the secondary flow path 98 from becoming unnecessarily high. . Actually, this operation is repeated in an extremely short time, and the flow rate is adjusted to an appropriate amount of hot water or water.
[0046]
Although the present embodiment is configured as described above, the present invention is not limited to this, and various modifications can be made within the scope of the gist of the present invention. For example, in the above embodiment, the water faucet that switches the water spraying mode of shower watering or straight water discharge is exemplified, but the present invention is not limited to this. For example, a switching valve device that switches between raw water as tap water and purified water subjected to water purification treatment For example, the present invention can be applied to a water faucet including a switching valve device that switches a flow path widely.
[0047]
  In addition, the position where the pressure reducing device is provided is not limited to the above-described water discharger 1 base end side. In the water faucet according to claim 3, as long as it is upstream of the switching valve device 31, good. Furthermore, claim 1,2The described faucet is not limited to the water discharge device 1 and may be provided in the hose 2 or between the hose 2 and the faucet body.
[0048]
  Also, DecreaseThe pressure body and the pressure reducing channel are not limited to those described above. For example, when the decompression body is provided in the central portion and the decompression body is incorporated so as to surround the decompression passage, and the water supply pressure exceeds a predetermined level, the decompression body is reduced in diameter and the opening amount of the decompression passage It is good also as adjusting.
[0049]
【The invention's effect】
  Since each invention of the present invention is configured as described above, a faucet that does not deteriorate the operability of switching even when the feed water pressure is high can be provided with a simple structure, and it can be easily applied to an existing faucet. Applicable to. In particular, the invention of claim 3 can be easily applied to an existing water faucet simply by removing or replacing the water discharger.wear.
[Brief description of the drawings]
FIG. 1 is a perspective view of a water discharge tool.
2A is a cross-sectional view of a main part of the decompression device, and FIG. 2B is a cross-sectional view taken along line XX of FIG.
3A is a cross-sectional view of the main part of the decompression device, and FIG. 3B is a cross-sectional view taken along line XX of FIG. 3A.
FIG. 4 is an enlarged vertical sectional view of a main part of the switching valve device.
FIG. 5 is a longitudinal sectional view of the face of the water discharger of FIG. 1;
FIG. 6 is a cross-sectional view of a water discharge tool showing a switching valve device.
FIG. 7 is a cross-sectional view of a water discharge tool showing a switching valve device.
FIGS. 8A, 8B, and 8C are side views of the water discharging device showing the state of switching the water discharging form by the switching valve device, respectively.
9A and 9B are longitudinal sectional views of another decompression device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1; Water discharging tool, 2; Hose, 3; Main part, 4; Engagement part, 5; Insertion hole, 6; Packing, 7a, 7b, 7c; 1st flow path, 11c; 2nd flow path, 12; Concentrated spout, 14; 1st sprinkling part, 16; Sprinkling hole, 18; 2nd sprinkling part, 21; Outward sprinkling hole, 22; Inlet channel, 26; recess, 28; recess, 30; insertion portion, 31; switching valve device, 32; valve device, 33; valve seat, 34; arm, 36; pin, 38; Spring 42, valve case 44, support arm 46, engagement arm 47, projection 48, projection 50, slot 52, protrusion 54, foam unit 60, decompression device 62, casing 64; decompression body, 66; primary side, 68; secondary side, 70; beam, 72; cylindrical portion, 74; 76; Projection, 80; Pressure reducing device, 81; Communication channel, 82; Piston, 83; Flange, 84; Channel, 85; Small diameter portion, 86; Spring, 88; Opening, 90; Seal member, 94; protrusion, 96; primary side flow path, 98; secondary side flow path, 99;

Claims (3)

The valve port is opened and closed by an inflow passage through which hot water or water is supplied from the faucet body, a plurality of outflow passages communicating with the inflow passage through the valve port, and a valve body provided on the primary side of the valve port. And a switching valve device that switches the communication with the inflow path to any of the outflow paths, and a water faucet provided with a water discharger having an inside thereof,
Between the faucet body and the switching valve device, comprising a pressure reducing device that reduces the pressure on the secondary side ,
In the decompression device, a casing is formed in a substantially cylindrical shape, and a cylindrical portion is provided at a central portion of the casing. The cylindrical portion is supported by a plurality of beams, and a decompression flow path is formed between adjacent beams. A plurality of protrusions projecting from the inner peripheral surface of the casing toward the cylindrical portion, and an elastically deformable ring-shaped decompression body is attached to the outer periphery of the cylindrical portion. Hydrant to do.   The water tap according to claim 1, wherein the valve body has a spherical portion that fits into the valve port.   The faucet according to claim 1 or 2, wherein the decompression device is built in the water discharger.

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