Patent Grant
7740191
This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2006-056992, filed on Mar. 2, 2006; the entire contents of which are incorporated herein by reference.
1. Field of the Invention
This invention relates to a shower device for use in a bathroom or a shower booth, capable of automatic reciprocating action for repetitively changing the water sprinkle direction of the shower, and a shower booth.
2. Description of the Related Art
There are growing needs for shower devices intended for relaxation, beauty/health enhancement and the like. In an approach for this application, for example, swirling flow or the like is used to modulate water flow at a relatively fast rate of several tens of hertz or more for enhancing massage effect and the like. On the other hand, the water sprinkle position and water sprinkle direction of a shower nozzle or the like can be repetitively changed at a relatively slow rate of several hertz or less, for example, to uniformly spray water onto a prescribed area of a human body for enhancing relaxation effect and the like.
Electrically-operated means such as a motor or solenoid can also be used for reciprocating action. However, for installing such means into a system for discharging water in a bathroom or the like, it is necessary to ensure power supply and to take measures against electric shock and leakage and the like. There are also many problems to be solved with regard to cost and reliability.
In this respect, if reciprocating action can be achieved hydraulically, the need for electricity, lubricating oil and the like is eliminated, and improvement can be expected in many aspects such as initial cost, running cost, reliability, and maintainability.
A shower device capable of vertical reciprocating action is disclosed (Japanese Patent Application Publication No. HO 2-134119A), where a piston is combined with a four-way valve. In this shower device, a piston provided in a cylinder is moved vertically by hydraulic pressure, and a shower head is moved vertically through a wire. The vertical motion of the piston is switched by switching the water supply channel to the cylinder using the four-way valve.
It can be said that a driving device using water pressure from combination of a cylinder like this and a piston can attain directly driving force with a low speed and a high power as motion of the piston, compared with a driving device obtaining driving force by rotating a water mill with a high speed, and is suitable for use as the shower device which needs a stable motion as naked humans touches directly. That is, if considering about a usage pattern, as the device is set so as to be directly touchable for a user, rigidity is needed for the shower head itself not so as to break when the user collides with the shower head accidentally, and high driving force is needed for move the shower head. Furthermore, the low speed is preferred to get a comfortable feeling of use of the shower. The water pressure driving device from combination of the cylinder and the piston can transmit the high driving force to the shower head and can easily drive the shower head with the low speed, compared with the water pressure driving device using the water mill.
However, in the case of this shower device, as the shower head is moved vertically, a long distance for moving the shower head is necessary to discharge water in a broad area. As a result, an area being possible for the shower head to exist broadens and there is a problem of resulting in a design impairment when setting the shower device in the limited space such as a bathroom and a shower booth.
This invention has been made in consideration of these problems. An object of the invention is to provide a shower device and a shower booth having a compact and simple structure, a reduced area being possible for the shower head to exist in spite of keeping capability of discharging water in the broad area, and improved design.
According to an aspect of the invention, there is provided a shower device including: a driving unit including a housing and a core allowed to reciprocate by water which is introduced into the housing; a shower part allowed to swing; a water guide channel introducing water which is introduced into the housing to the shower part; and a power transmission part transmitting a motion of the core to the shower part, the shower part sprinkling water while swinging when water is introduced into the housing.
According to another aspect of the invention, there is provided a shower booth including: a wall; a ceiling; and the above-described shower device provided on at least one of the wall and the ceiling.
Embodiment of the invention will now be described with reference to the drawings.
Firstly, the structure and the mechanism of driving unit 100 provided in the shower device of the embodiment are described in detail.
More specifically, driving unit 100 has housing 102 and water discharge tubular body 180 protruding from housing 102. Inside water discharge tubular body 180 is provided water discharge channel 182. Housing 102 has two water inlet ports 112, 114. Water inlet ports 112, 114 are coupled in parallel. When water (including hot water and cold water) is supplied to water inlet ports 112, 114 at nearly the same pressure, water discharge tubular body 180 discharges water from water discharge channel 182 while reciprocating right and left as shown by arrow M.
Driving unit 100 has core 120 movably provided in housing 102. The interior of housing 102 is divided by core 120 into a first pressure chamber 116 and a second pressure chamber 118. Core 120 has a hollow structure. The hollow space constitutes core inner channel 124 communicating with water discharge channel 182 provided in water discharge tubular body 180. Core inner channel 124 communicates with pressure chambers 116, 118 via introducing ports (drain hole) 132, 134, respectively.
Core 120 is provided with valve bodies 142, 144 for changing the opening of introducing ports 132, 134. Core 120 is also provided with a control means for controlling valve bodies 142, 144. The control means can produce an opening difference between introducing ports 132 and 134, thereby causing a difference in channel resistance between the right and left channel extending from the water inlet port to core inner channel 124. The resulting pressure difference between right and left pressure chamber 116, 118 can be used to move core 120.
In the state shown in
On the other hand, as illustrated in
Note that the “opening” of the introducing port used herein refers to a parameter determining the channel resistance for fluid flowing between the introducing port and the valve body. For example, in the state shown in
Therefore, when the force applied to core 120 exceeds the sliding resistance, core 120 moves to the right side. On the other hand, valve body 142 is also movable relative to core 120. Thus, when the force applied to valve body 142 exceeds the sliding resistance of valve body 142, valve body 142 moves to the right side relative to core 120. If valve body 142 moves to the right side, the channel through introducing port 132 has an even higher channel resistance, which expands the pressure difference. That is, the forces applied to core 120 and valve 142 are increased, respectively, and the movement of core 120 and valve body 142 is promoted. Ultimately, as shown in
As described above, in driving unit 100 of the embodiment, core 120 can be moved simply by providing an opening difference between introducing ports 132, 134 to produce a pressure difference required for the movement. Then the pressure difference is maximized by causing one of the introducing ports to be in the open state and the other to be in the closed state. This achieves the most reliable and stable force for movement.
Returning again to
When core 120 continues to move to the left side and arrives at or near the left end of housing 102 as shown in
In the following, the structure of driving unit 100 of the embodiment will be described in more detail with reference to examples.
When water is introduced into water inlet ports 112, 114 provided in housing main body 103, water discharge tubular body 180 protruding on either side reciprocates linearly in the direction of arrow M.
The internal structure is described. As shown in
Next, the structure of the core 120 is described. Core inner channel 124 is formed by combining core lid 122 with core main body 121. Core inner channel 124 communicates with water discharge channel 182 provided in water discharge tubular body 180. Core main body 121 and core lid 122 have introducing ports 132, 134 allowing core inner channel 124 to communicate with pressure chambers 116, 118.
In the example, leaf spring 160 and slide bars 146, 148 are provided in core 120 as the control means. Slide bars 146, 148 are provided so as to traverse core inner channel 124 with main valves.
As illustrated in
The action of main valves 142, 144 to vary the opening of introducing ports 132, 134 is determined by the coaxially provided slide bars 146, 148. More specifically, as shown in
In the following, the action of the driving unit of the example is described.
In this state, when water is supplied to water inlet ports 112, 114 at nearly the same pressure, the water introduced from water inlet port 114 into pressure chamber 118 as shown by arrow B flows from introducing port 134 into core inner channel 124 as shown by arrow C and flows out as shown by arrow D via water discharge channel 182. On the other hand, because introducing port 132 is closed, the water introduced from water inlet port 112 into pressure chamber 116 as shown by arrow A has no outflow path and the pressure in pressure chamber 116 becomes higher than the pressure in pressure chamber 118. That is, by providing an opening difference between introducing ports 132, 134, a difference in channel resistance occurs, which causes a pressure difference. As a result, core 120 is pushed and moved in the direction of arrow M.
When core 120 moves in the direction of arrow M, the volume of pressure chamber 116 increases, and the volume of pressure chamber 118 decreases by that amount. Therefore the water in pressure chamber 118 is pushed out by the amount of water flowing into pressure chamber 116 via the path of arrow A, and is included in the discharge amount of water flowing out of channel 182.
As core 120 continues to move in the direction of arrow M from the state shown in
As shown in
As described above, according to the example, because core 120 is provided with main valves 142, 144 as valve bodies and with a control means composed of slide bars 146, 148 and leaf spring 160, the size relation of the opening difference between introducing ports 132 and 134 can be appropriately inverted depending on the movement of core 120. Thus core 120 is able to reciprocate. The stroke of reciprocation of core 120 of the example can be configured appropriately on the basis of the length of the interior space of housing 102 and the thickness (width) of core 120.
Next, the function of the control means in the example is described in more detail.
Subsequently, core 120 moves further, and thereby slide bar 148 is further pushed against core 120. Then, as shown in
Then, as shown in
As described above, in the example, the bend direction of compressed leaf spring 160 is appropriately reversed by slide bars 146, 148, and its biasing force is used to operate main valves 142, 144, thereby alternatively controlling introducing ports 132, 134 to be in one of the fully open state and the fully closed state. That is, the biasing force of leaf spring 160 is used to reliably produce the opening difference between both of introducing port 132, 134 for reversing core 120.
The mechanism of this example for controlling main valves 142, 144 via slide bars 146, 148 plays a very important role in the smooth action of the water discharger of this embodiment. More specifically, compressed leaf spring 160, which is stable in the state bent to the right side or the left side, may fall into a metastable state, neutral state about halfway between these stable states as shown in
In contrast, according to this example, slide bars 146, 148 are provided, and their stroke is appropriately adjusted. Thus, in the metastable neutral state as shown in
In other words, before the opening difference enough to move core 120 is lost, leaf spring 160 is reversed, and main valves 142, 144 are moved by the reversing force (biasing force) via slide bars 146, 148. Thus the opening difference between introducing ports 132, 134 can be inverted to the opening difference enough to move core 120 in the opposite direction.
This eliminates the problem that introducing ports 132, 134 may have nearly the same opening which results in stopping core 120 when leaf spring 160 is in the neutral state. Thus a smooth repetitive motion can be achieved.
Furthermore, in this configuration, even when shower water sprinkle is started from the state where core 120 is stopped about halfway through its moving stroke, main valves 142, 144 can be controlled by leaf spring 160 at the beginning of shower water sprinkle to be in the state where one of introducing ports 132, 134 is alternatively opened. Thus a pressure difference is produced between both sides of core 120, and a stable initial action can be started. That is, the state where the opening of introducing port 134 is larger than the opening of introducing port 132, or the state where the opening of introducing port 132 is larger than the opening of introducing port 134, can be retained alternatively.
As described above, in the example, the moving direction of core 120, the movable direction of main valves 142, 144, the movable direction of slide bars 146, 148, and the biasing direction of leaf spring 160 can be made generally the same to avoid waste in the action of force and to effectively use the moving force of the core having a large pressure-receiving area. Thus a smooth and stable action is achieved. That is, the moving action and the opening control action of core 120 are interlocked, and thereby the control action to invert the size relation of the opening of introducing ports 132, 134 for the reversal of core 120 is made reliable and easy. Thus the valve bodies and the control means are made simple and compact.
In the example shown in
Furthermore, the thrust obtained in the reciprocating linear action of driving unit 100 of this embodiment is determined by the product of the pressure of water loaded on core 120 and the pressure-receiving area of the core. Therefore, as the pressure-receiving area of core 120 is increased, a correspondingly larger thrust can be obtained.
While
The outer peripheral shape of water discharge tubular body 180 does not need to be circular, but may be in a polygonal or flattened shape. Furthermore, water discharge tubular body 180 does not need to be placed at the center of core 120, but may be decentered from the center of core 120. This facilitates downsizing core 120, and driving unit 100 can be downsized.
When the interior space of housing 102 is configured as a cylinder and water discharge tubular body 180 is placed at the center of cylindrical core 120 as in this example, water discharge tubular body 180 can be rotated. Thus, the reciprocating linear motion of core 120 allows the shower water sprinkle direction to change as well.
As described above, core 120 can be moved simply by providing an opening difference between the introducing port 132 and 134 to produce a pressure difference required for the movement. Likewise, the moving direction of core 120 can be reversed simply by inverting the size relation of the opening of introducing ports 132, 134 using the control means. For example, the ratio of opening between introducing ports 132, 134 can be changed from 70:30 to 30:70 by the control means to achieve the reversal action. Furthermore, when the opening is changed from 100:0 to 0:100 by the control means, the most reliable and stable reversal action is achieved.
According to driving unit 100 of the embodiment, the core contained in housing 102 is provided with valve bodies 142, 144 and the control means. Core 120 can be reciprocated by supplying water into the pressure chambers on both sides thereof. Here, the moving direction of core 120 is made generally the same as the movable direction of valve bodies 142, 144 to interlock the moving action and the opening control action of core 120. Thus the reversal action of the valve bodies to invert the size relation of the opening of introducing ports 132, 134 for the reversal of core 120 is made reliable and easy, and the valve bodies and the control means are made simple and compact.
As described later in detail, water discharge channel 182 inside water discharge tubular body 180 of the embodiment plays a role as a water guide channel introducing water flowed in from core 120 into the shower part. Moreover, for example, as described later with respect to
Driving unit 100a is provided with water discharge tubular body 180 on both sides of core 120. That is, water discharge tubular body 180 protrudes from both sides of housing 102 and is particularly useful when sprinkling water from both sides is desired. In such a case, water discharge channel 182 inside water discharge tubular body 180 of the embodiment plays a role as a water guide channel introducing water flowed in from core 120 into the shower part. Furthermore, as described later with respect to
In the first embodiment of the driving unit described above, the unit in which the core reciprocates linearly was described. Next, a second embodiment of the driving unit in which the core oscillates will be described.
Driving unit 200 of this embodiment has water discharge tubular body 280 that illustratively protrudes on one side from housing 202 formed from housing main body 203 and housing lids 204, 205. Water discharge tubular body 280 has a hollow structure having water discharge channel 282 inside and opened at the tip. When water is introduced into water inlet ports 212, 214 provided in housing 202, water discharge tubular body 280 oscillates in the direction of arrow R.
The internal structure is described. As shown in
Next, the structure of core 220 is described. In this embodiment again, core 220 has a valve body and a control means similar to driving unit 100 described above. Core inner channel 224 is formed in core 220. Core inner channel 224 communicates with water discharge channel 282 provided in water discharge tubular body 280. Core 220 has introducing ports (drain hole) 232, 234 allowing core inner channel 224 to communicate with pressure chambers 216, 218. Main valves 242, 244, slide bars 246, 248 are provided so as to traverse core inner channel 224. The shape of the main valve and the slide bar is as described above with reference to
That is, leaf spring 260 is supported at both ends by core 220. Slide bars 246, 248 move relatively to core 220 via leaf spring 260. The action of main valves 242, 244 to vary the opening of introducing ports 232, 234 is determined by the coaxially provided slide bars 246, 248. Slide bar 246, 248 are subjected to a biasing force depending on the bend direction of leaf spring 260. As a result, main valves 242, 244 are subjected to the biasing force from slide bars 246, 248 to place introducing ports 232, 234 in one of the state of the fully open state and the fully closed state alternatively.
In the following, the action of driving unit 200 is described.
First,
In this state, when water is supplied to water inlet ports 212, 214 at nearly the same pressure, the water introduced from water inlet port 214 into pressure chamber 218 as shown by arrow A flows from introducing port 234 into core inner channel 224 as shown by arrow C and flows out as shown by arrow D via water discharge channel 282. On the other hand, because introducing port 232 is closed, the water introduced from water inlet port 212 into pressure chamber 216 as shown by arrow B has no outflow path and the pressure in pressure chamber 216 becomes higher than the pressure in pressure chamber 218. That is, by providing an opening difference between introducing ports 232, 234, a difference in channel resistance occurs, which causes a pressure difference. As a result, core 220 is pushed and oscillates in the direction of arrow R.
When core 220 oscillates in the direction of arrow R, the volume of pressure chamber 216 increases, and the volume of pressure chamber 218 decreases by that amount. Therefore the water in pressure chamber 218 is pushed out by the amount of water flowing into pressure chamber 216 via the path of arrow B, and is included in the discharge amount of water flowing out of channel 282.
Core 220 further continues to oscillate and slide bar 248 abuts against the inner wall of housing 202 and is pushed against core 220. Then the bend direction of leaf spring 260 is reversed, and slide bars 246, 248 are biased toward the opposite side as shown in
As shown in
As described above, in driving unit 200 again, core 220 is provided with the valve bodies composed of main valves 242, 244, and the control means composed of leaf spring 260 and slide bars 246, 248. Thus the size relation of the opening between the introducing ports can be appropriately inverted depending on the movement of core 220 to move core 220 right and left repetitively. In addition, in driving unit 200 again, as described above with reference to
In other words, before the opening difference enough to move core 220 is lost, leaf spring 260 is reversed, and main valves 242, 244 are moved by the reversing force (biasing force) via slide bars 246, 248. Thus the opening difference between introducing ports 232, 234 can be reversed to the opening difference enough to move core 220 in the opposite direction.
In driving unit 200 again, the oscillating direction of core 220, the movable direction of main valves 242, 244, the movable direction of slide bars 246, 248, and the biasing direction of leaf spring 260 can be made generally the same to avoid waste in the action of force and to effectively use the moving force of the core having a large pressure-receiving area. Thus a smooth and stable action is achieved. That is, when core 220 approaches the inner wall of housing 202, the moving direction of core 220 is made generally the same as the movable direction of main valves 242, 244, the biasing direction of leaf spring 260, and the movable direction of slide bars 246, 248. Thus the oscillating action and the opening control action of core 220 are interlocked, and the action of inverting the size relation of the opening of introducing ports 232, 234 for the reversal of core 220 is made reliable and easy. Thus the valve bodies and the control means are made simple and compact.
Furthermore, in this configuration, even when shower water sprinkle is started from the state where core 220 is stopped about halfway through its oscillating stroke, main valves 242, 244 can be controlled by leaf spring 260 at the beginning of shower water sprinkle to be in the state where one of introducing ports 232, 234 is opened alternatively. Thus a pressure difference is produced between both sides of core 220, and a stable initial action can be started. That is, the state where the opening of introducing port 234 is larger than the opening of introducing port 232, or the state where the opening of introducing port 232 is larger than the opening of introducing port 234, can be retained alternatively.
The stroke (oscillating angle) of the oscillating motion of core 220 in driving unit 200 can be appropriately configured by the opening angle of the fan-shaped space of housing 202.
Furthermore, in this embodiment again, the thrust obtained by the oscillating action is determined by the product of the pressure of water applied to core 220 and the pressure-receiving area of the core. Therefore, as the pressure-receiving area of core 220 is increased, a correspondingly larger thrust can be obtained.
In this embodiment again, water discharge channel 282 inside water discharge tubular body 280 plays a role as a water guide channel introducing water flowed in from core 120 into the shower part. Furthermore, as described later with respect to
Application of driving unit 100 and driving unit 200 described above allows the shower device of this invention to be capable of smooth reciprocating linear motion and oscillating motion of the core only by the supplied pressure of water without the necessity of electrical or mechanical motive energy. Furthermore, the shower device without waste water is realized by sprinkle the water in swinging state of the shower part.
Furthermore, in the shower device of the invention, the valve bodies and the control means allowing a reciprocating motion accompany the core. Therefore the need for an external four-way valve, for example is eliminated, and a smooth reciprocating motion can be achieved by a simple configuration. This facilitates downsizing of a whole device, and the beauty and the layout of bathroom space are advantageous.
It is configured that the shower part is coupled to water discharge tubular body reciprocating and water is discharged from the interior of the water discharge tubular body. Therefore, advantageously, the flow channel is simplified, the pressure loss can be reduced, and a sufficient amount and pressure of water discharge can be ensured.
Furthermore, because of the structure of incorporating the valve bodies and the control means in housing, smooth action resistant to external disturbances can be achieved while an assembly process can be simplified. As a result, highly reliable and stable operation of shower water sprinkle can be achieved.
Moreover, water supply to the driving unit can be implemented simply by coupling the lines branched from a common water tubular channel to two water inlet ports, achieving good workability. In addition, with respect to water inlet ports, water inlet ports corresponding to left and right pressure chambers may be simply formed, respectively. For example, divided channels are formed in the housing, coupled to each water inlet port, and water inlet coupling port to the housing is unified to be one, thereby, piping can be also further simplified.
Next, a method to stop the swinging motion of the shower part for improving convenience during taking a shower is described.
In the case of this example, bypass channel 340 is provided communicating pressure chamber 216, 218 formed from side to side of core 220. Moreover, switching valve 342 is provided in the bypass channel 340. Operation of switching valve 342 makes it possible to stop core 220 and control the speed.
That is, when right and left pressure chambers 216, 218 are communicated to bypass channel 340 by opening switching valve 342, water is bypassed from the pressure chamber of which the volume should have increased to the pressure chamber of which the volume should have decreased. For example, as shown by arrow R in
On the other hand, when the opening of switching valve 342 is adjusted, the oscillating speed of core 220 can be adjusted. That is, when the amount of bypass water flow via bypass channel 340 is smaller, the speed of core 220 becomes higher, and when the amount of bypass water flow via bypass channel 340 is larger, the speed of core 220 becomes lower. Therefore, adjusting the opening of switching valve 342 makes it possible to adjust the speed of core 220.
In the case of this example, one switching valve 342 can stop core 220 or control the speed independently of the oscillating direction of core 220. The channel resistance of the right and left water channel extending to water inlet ports 212, 214 does not change, therefore, the pressure loss in a water inlet pass does not change and the total amount of water discharge can be kept substantially constant during normal operation, during stopping, and during decreasing speed also.
In addition, bypass channel 340 is preferred to communicate with pressure chamber 216, 218 at both ends of the inside space of housing 202. That is, the opening port of bypass channel 340 is preferred to be formed close to the end of housing 202 as much as possible so that bypass channel 340 is not obstructed even if core 220 is located at the end of right and left stroke.
The method of stopping of the example described above is applicable similarly to driving unit 100 described previously with reference to
As described above, the oscillating speed (including stop) can be controlled, thereby a user is allowed to stop swinging motion of the shower part at desired angle while maintaining water sprinkle during taking a shower by sprinkle water from the shower part, therefore gets ease of use.
Up to this point, driving unit 100 and driving unit 200 were described.
Next, a first embodiment of the shower device with driving unit 100 described above (embodiment of the core reciprocating linear motion) is described in detail.
The water discharge tubular bodies of driving unit 100a are provided with a water discharge channel, water supplied into driving unit 100a is introduced into shower part 71a, 71b through the water discharge channel, and water is sprinkled from shower sprinkle port provided at shower part 71a, 71b. Reciprocating linear motion of the core makes the shower part swing via converting mechanism (not shown). In this way, the so-called swinging motion can be possible, which makes it possible to change periodically the direction of sprinkle while sprinkling water from shower part 71a, 71b by swinging shower part 71a, 71b in the direction of arrow M2 via operation of driving unit 100.
In addition, the water discharge channel inside the water discharge tubular body plays a role as a water guide channel introducing water flowed in from the core into the shower part. And the power transmission part in this embodiment is comprised of the water discharge tubular body coupled to the core and the converting mechanism.
Such sprinkled water is poured onto the shoulders or the like of a user. Then, because the water discharge position is varied periodically, the massage effect of the so-called “Utaseyu” (water falling down on a user's body like a waterfall) can act more extensively and effectively. Furthermore, because the user does not need to move his/her body for varying the site of action, the usability is improved. Moreover, the discharged water can also be sprayed onto the body extensively to achieve a relaxation effect, and the usability is improved.
Here, ‘swinging motion’ in this embodiment means by action of the shower part described above. That is, the shower part having the sprinkle port has a swinging axis, and the shower part swings about the axis. At this time, the opening direction of the sprinkle port of the shower part is substantially perpendicular to the swinging axis. In this way, the region allowing the shower part to exist can be reduced and maintained to be substantially constant while discharging water in a broad area by swinging action of the shower part, therefore, the shower device with improved design can be realized. Moreover, the swinging axis is preferred to be provided close to the sprinkle port of the shower part. Furthermore, in the state of the shower device installed, the sprinkle port is preferred to be provided more forward than the swinging axis. In addition, because the shower part is that swings vertically, the swinging axis in this embodiment is provided substantially parallel to a floor surface.
Next, a second embodiment of the shower device with driving unit 200 described above (embodiment of the core oscillating) is described in detail.
The water discharge tubular body of driving unit 200 is provided with a water discharge channel, water supplied into driving unit 200 is introduced into shower part 81 through the water discharge channel, and water is sprinkled from shower sprinkle port provided at shower part 81. Here, the water discharge tubular body oscillates as shown by arrow R by operation of driving unit 200, as a result oscillating motion, that is, swinging motion can be possible while shower part 81 also sprinkling water. That is, the direction of shower sprinkle can be changed periodically.
Shower device 3 of this embodiment can sprinkle shower water to a wide area in a compact shape by swinging motion of shower part 81 as shown by arrow R and rinse user's body in a wide area, furthermore the user can take a shower effectively with free hands. Moreover, massage effect and relaxation effect by stimulation of shower changing repetitively can be expected. Furthermore, change of the shower sprinkle direction by swinging motion like this makes the region allowing shower part 81 to exist during swinging suppress, thereby, achieving good design such as the beauty of the whole of a bathroom or the layout.
In this embodiment, oscillating motion of the core can be transmitted directly to swinging motion of the shower part, therefore a more compact shower device can be achieved. And so-called swinging motion capable of changing periodically can be achieved.
In addition, the water discharge channel inside the water discharge tubular body plays a role as a water guide channel introducing water flowed in from the core to the shower part. Moreover, the power transmission part in this embodiment corresponds to the water discharge tubular body coupled to the core.
Here, ‘swinging motion’ in this embodiment means by action of the shower part described above. That is, the shower part having the sprinkle port has a swinging axis, and the shower part swings about the axis. At this time, the water sprinkle plane of the shower part is substantially parallel (the opening direction of the sprinkle port of the shower part is substantially perpendicular) to the swinging axis. In this way, the region allowing the shower part to exist can be reduced and maintained to be substantially constant while discharging water in a broad area by swinging action of the shower part, therefore, the shower device with improved design can be realized. Moreover, the swinging axis is preferred to be provided close to the sprinkle port of the shower part. Furthermore, in the state of the shower device installed, the sprinkle port is preferred to be provided more forward than the swinging axis. In addition, because the shower part is that swings vertically, the swinging axis in this embodiment is provided substantially parallel to a floor surface.
Next, a third embodiment of the shower device with driving unit 200 described above (embodiment of the core oscillating) is described in detail.
Moreover,
Shower device 4 of this embodiment includes flame 400, and shower part 410 and switch 420 supported by this flame. Flame 400 is allowed to be embedded in a wall of shower booth 950 and a bathroom or the like.
Shower part 410 swings up and down in the direction of arrow R.
Furthermore, according to this embodiment, shower device 4 can be embedded in the wall of the shower booth and the bathroom. This not only allows a simple and good appearance but also can prevent giving an oppressive feeling to a user and colliding with the body in a tight shower booth and a bathroom or the like.
In the following, the structure of shower device 4 of this embodiment will be described.
Moreover,
Additionally
In addition, shower device 4 shown in
Shower part 410 is provided with plural shower sprinkle ports 412 in two dimensions with dual orientation, is allowed to sprinkle water in a broad area. Supporting flame 408 is provided in the interior protected by casing 401 on the back side of flame 400, and driving unit 200 is fixed described previously with reference to
Moreover, all of
One end of shower part 410 is axially supported by axial supporting part 440 and the other end is axially supported by axial supporting part 448.
Water supplied from a water supply source not shown in the figures is introduced to water supplier 404. As described previously with reference to
One end 228 of core 220 in driving unit 200 penetrates housing lid 205 and protrudes, where is fixed to gear 450 and transmits oscillating motion of core 220 to gear 450. Gear 450 transmits oscillating motion to gear 452 which is fixed to shower part 410 (power transmission part). As a result, shower part 410 swings.
According to this embodiment, by choosing a size of driving unit 200 and a gear ratio of gear 450 and 452, period of swinging motion of shower part 410 can be a few hertz. When sprinkling water in a broad region of the body of a user, the period of swinging motion of shower part 410 is not proper neither for too fast nor for too slow in order to give comfortable feeling of massage. Because the user can not feel change of a body part receiving shower.
The frequency of swinging motion of shower part 410 is preferred to be 0.1 hertz or more and 5 hertz or less to give a comfortable feeling of massage and effect of working out of stiffness. Moreover, it is more effective when the frequency is 0.2 hertz or more and 3 hertz or less. Furthermore, when the frequency is 0.3 hertz or more and 1 hertz or less, a user can receive still more comfortable feeling. According to this embodiment, swinging motion of shower part 410 can be achieved at the period like this.
Moreover, in this embodiment, the oscillating axis of oscillating motion of core 220 is different from the swinging axis of swinging motion of shower part 410. That is, the oscillating axis of oscillating motion of core 220 is provided on the back side apart from flame 400, on the other hand, the swinging axis of swinging motion of shower part 410 is provided near to flame 400. In this way, shower part 400 can be provided in front of shower flame 400 while accommodating driving unit 200 on the rear side. That is, the shower device can be provided, which has no protruding portion around shower part 400 and is easy to use with clear appearance.
On the other hand, in the shower device of this embodiment, swinging motion of shower part 410 can be stopped by operation of switch 420.
That is, bypass channel 340 and switching valve 342 are provided in driving unit 200 and bypass channel 340 is allowed to be switched by switch 420.
Valve inner channel 344 existing on a way to bypass channel 340 is provided in the interior of switching valve 342. And screening body 424 is supported so as to be capable of switching valve inner channel 344.
On the other hand, as shown in
In addition, switch 420 is allowed to hold the state shown in
That is,
Moreover,
Also in this variation, switching valve 342 is provided on a way to bypass channel 340. Valve inner channel 344 is provided in the interior of switching valve 342 and is allowed to be switched by rotating screening body 426. Screening body 426 is driven by gear 428. Wire 472 slidably kept in guide 470 is coupled to switch 420. The tip of wire 472 is coupled to rack 474. When switch 420 is pushed, wire 472 slides and rack 474 rotates gear 428. Rotation of gear 428 is transmitted to screening body 426 and valve inner channel 344 is switched.
As shown in
On the other hand, as shown in
Also in this variation, the state shown in
Moreover, a clearance between the shower part having the shower sprinkle port and flame 400 is formed to have dimension so that hands are not caught even if shower part 410 swings. It is more preferred that an opening side plane for providing shower part 410 of the flame is formed in a shape along swinging track of the end of shower part 410 so that the clearance is substantially constant even if shower part 410 swings.
Furthermore, casing 401 is preferred to be formed in a shape of a box having an opening on the side of shower part 410 of shower device 4. In this way, even if water flows into the clearance between shower part 410 and flame 400, water does not leak to the back side of the wall by casing 401 formed in a shape of a box. It is more preferred that the bottom surface of casing 401 has a downward slope on the side of shower part 410, water flowed into casing 401 can be drained off to a bath room or shower booth.
In this embodiment, oscillating motion of the core can be transmitted to swinging motion of shower part 410 via gear 450, 452, therefore, the shower device can be more compact. And the so-called swinging motion capable of changing periodically can be achieved.
In addition, the water discharge channel in the interior of the water discharge tubular body plays a role as the water guide channel introducing water flowed in from the core to the shower part.
Here, ‘swinging motion’ in this embodiment means by action of the shower part described above. That is, the shower part having the sprinkle port has a swinging axis, and the shower part swings about the axis. At this time, the water sprinkle plane of the shower part is substantially parallel (the opening direction of the sprinkle port of the shower part is substantially perpendicular) to the swinging axis. In this way, the region allowing the shower part to exist can be reduced and maintained to be substantially constant while discharging water in a broad area by swinging action of the shower part, therefore, the shower device with improved design can be realized. Moreover, the swinging axis is preferred to be provided close to the sprinkle port of the shower part. Furthermore, in the state of the shower device installed, the sprinkle port is preferred to be provided more forward than the swinging axis. In addition, because the shower part is that swings vertically, the swinging axis in this embodiment is provided substantially parallel to a floor surface.
Next, a fourth embodiment of the shower device with driving unit 100 described above (embodiment of the core reciprocating linear motion) is described in detail.
Shower device 5 of this embodiment is also provided with shower part 410 supported by the flame not shown in a figure as well as shower device 4 of the third embodiment and is allowed to be embedded in a wall of shower booth 950 and a bathroom or the like. Shower part 410 is axially supported by axial support portion 454 and is allowed to swing up and down, as shown in
Also in this embodiment, by selecting properly a size or the like of driving unit 100 and link mechanism 458, periodicity of swinging motion of shower part 410 can be about a few hertz. As a result, comfortable feeling of massage and effect of working out of stiffness can be given to users.
Also in this embodiment, by providing switch 420, bypass channel 340 and switching valve 342 described previously with reference to
‘Swinging motion’ in this embodiment means by action of the shower part described above. That is, the shower part having the sprinkle port has a swinging axis, and the shower part swings about the axis. At this time, the water sprinkle plane of the shower part is substantially parallel (the opening direction of the sprinkle port of the shower part is substantially perpendicular) to the swinging axis. In this way, the region allowing the shower part to exist can be reduced and maintained to be substantially constant while discharging water in a broad area by swinging action of the shower part, therefore, the shower device with improved design can be realized. Moreover, the swinging axis is preferred to be provided close to the sprinkle port of the shower part. Furthermore, in the state of the shower device installed, the sprinkle port is preferred to be provided more forward than the swinging axis. In addition, because the shower part is that swings vertically, the swinging axis in this embodiment is provided substantially parallel to a floor surface.
Next, a fifth embodiment of the shower device with driving unit 100 described above (embodiment of the core reciprocating linear motion) or driving unit 200 (embodiment of the core oscillating) is described in detail.
Shower device 6 of this embodiment can be used as a body shower, for example, by installing on wall 900 in a shower booth and a bathroom or the like. Moreover, the shower device 6 of this embodiment can be also used as an overhead shower by installing on a ceiling of a shower booth and a bathroom or the like.
In the interior of body 500, driving unit 100 described previously with reference to
Furthermore, body 500 is allowed to be adjustable of the direction up and down or right and left with respect to supporting portion 510. That is, water sprinkle direction can be adjusted depending on the installation location of shower device 5 and user's preference or the like. Furthermore, body 500 may be also rotatable manually about an axis C as shown by arrow F with respect to supporting portion 510. In this way, swinging direction of shower part 410 can be freely adjusted to the right and left direction shown by arrow A (state of swinging axis substantially parallel to floor surface), to the up and down direction shown by arrow B (state of swinging axis substantially perpendicular to floor surface) and to the intermediate slanted direction between those (state of swinging axis neither parallel nor perpendicular to floor surface), too.
Furthermore, also in this embodiment, by providing switch 420, bypass channel 340 and switching valve 342 described previously with reference to
Shower device 6 of this embodiment can be easily installed using shower coupling port already existing, because of no necessity to embed in wall 900 in a shower booth and a bathroom. As a result, comfortable feeling of massage and effect of working out of stiffness caused by automatic swinging motion of shower part 410 can be easily achieved.
‘Swinging motion’ in this embodiment means by action of the shower part described above. That is, the shower part having the sprinkle port has a swinging axis, and the shower part swings about the axis. At this time, the water sprinkle plane of the shower part is substantially parallel (the opening direction of the sprinkle port of the shower part is substantially perpendicular) to the swinging axis. In this way, the region allowing the shower part to exist can be reduced and maintained to be substantially constant while discharging water in a broad area by swinging action of the shower part, therefore, the shower device with improved design can be realized.
Up to this point the embodiment of the invention has been described. However, the invention is not limited to these examples.
That is, any ones to which a person skilled in the art added design modification with respect to any element comprising the shower device of the invention are also encompassed with the scope of the invention as long as they include the features of the invention. For example, any ones to which a person skilled in the art added modification properly with respect to outer shape of the driving unit of the shower device and the shower part, shape or location of components, and stroke and angle of swing or the like are also encompassed with the scope of the invention as long as they include the features of the invention.
Moreover, in each embodiment described above, a speed adjusting means may be provided, which adjusts the speed of swinging motion or the speed of reciprocating linear motion of the shower part driven by the driving unit. The speed adjusting means like this can be realized, for example, by providing a sliding member producing a variable sliding resistance to the water discharge tubular body, and by providing the bypass channel between two pressure chambers and the switching valve controlling the amount of flow in the bypass channel. Providing the speed adjusting means like this allows the speed of swinging motion of the shower part to change and further the speed of swinging motion of the shower part to stop while sprinkling shower water from the shower part coupled to the driving unit. That is, it becomes to be possible for users to take shower sprinkle water stopping the shower part in a preferred sprinkle direction. For example, behaviors comes to be possible, which users get massage effect by operating shower intensively to a body part and wash their head by receiving shower water intensively to the head, then the user-friendly shower device can be provided.
Moreover, in each embodiment describe above, a stroke adjusting means may be provided, which adjusts the angle range of swinging motion or the stroke of reciprocating linear motion of the shower part driven by the driving unit. The stroke adjusting means like this can be realized, for example, by providing a variable end protruding into the pressure chamber in the housing of the driving unit and by ensuring that the end touches the slide bar of the core. By providing the stroke adjusting means, the swinging range and moving range of the shower part coupled to the driving unit can be adjusted and the change range of the direction of the shower sprinkle can be adjusted. That is, users can adjust the operation range of shower sprinkle depending on their preference. Moreover, the user-friendly and effective shower device can be provided, which does not sprinkle water in the useless area by adjusting the change range in agreement with the individual body type.
The invention can provide a shower device and a shower booth having a compact and simple structure and capable of automatic reciprocating action changing repetitively a direction of shower water sprinkle using water power.
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| 2006-056992 | Mar 2006 | JP | national |
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