CN219850197U - Shower head and shower device - Google Patents

Abstract

The utility model provides a shower head and a shower device, wherein the shower head comprises a shell component, a first valve, a second valve, a control board, a battery and a first wireless charging coil, when the first valve is opened, water can flow out from a first water outlet of the shell component, when the second valve is opened, water can flow out from a second water outlet of the shell component, the control board is used for switching the states of the first valve and the second valve, the battery supplies power for the control board, and the first wireless charging coil is used for charging the battery; the shower device comprises the shower head and at least one of a wireless charger and a remote controller, wherein the remote controller is used for sending signals to the control panel, and the wireless charger can be used for wirelessly charging the remote controller and the shower head. The shower head provided by the utility model has various water outlet functions and wireless charging functions, and is high in functional diversity and use convenience.

Description

Shower head and shower device

Technical Field

The utility model relates to the technical field of bathroom equipment, in particular to a shower head and a shower device.

Background

In order to improve the shower experience of users, some showers on the market have various water outlet effects. For example, the water outlet area of the shower head can be adjusted, and when the user switches the shower head to a certain state, water is sprayed out from the central area of the water outlet surface of the shower head; when the user switches the shower head to another state, water is sprayed out from the edge area of the water outlet surface. For another example, the water outlet flow pattern of the shower head can be adjusted, and when the user switches the shower head to a certain state, the water flow is direct continuous water flow; when the user switches the shower head to another state, the water flow is pulse water flow or galloping water flow.

For some showers, when the water outlet effect is switched, a user needs to manually push or pull a certain adjusting part of the shower, so that the position of a water distribution disc or a valve core in the shower is changed, and then the water flow path in the shower is changed. The adjustment process of such a shower head is relatively laborious. In order to save the strength of the user when adjusting the shower, other shower heads are switched through the built-in electromagnetic valve, and the state of the electromagnetic valve can be changed by pressing the corresponding key by the user, so that the water flow path inside the shower head is changed through the electromagnetic valve.

However, since the solenoid valve requires power consumption, a battery for supplying power to the solenoid valve needs to be installed inside the shower head. When the electric quantity of the battery is insufficient, a user needs to detach the shower head and replace the battery, so that the use convenience of the shower head can be affected. In order to reduce the number of times of replacing the battery, the shower head and the socket can be connected through the plug, so that the battery is charged. However, in a wet bathroom environment, both the plug disposed on the shower and the socket disposed within the bathroom are prone to short-circuiting with water, which can result in a significant safety hazard for use of the shower.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the shower head provided by the utility model has high use convenience and use safety.

The utility model also provides a shower device comprising the shower head.

According to an embodiment of the first aspect of the present utility model, a shower head includes: a housing assembly having a water inlet, a first water outlet, and a second water outlet; the first valve is arranged in the shell assembly, and when the first valve is opened, the water inlet is communicated with the first water outlet; the second valve is arranged in the shell assembly, and when the second valve is opened, the water inlet is communicated with the second water outlet; the control board is arranged in the shell assembly, the first valve and the second valve are electrically connected with the control board, and the control board is used for switching the states of the first valve and the second valve; the battery is arranged in the shell assembly, is electrically connected with the control panel and supplies power for the control panel; the first wireless charging coil is installed in the shell assembly, the first wireless charging coil is electrically connected with the control panel, and the first wireless charging coil is used for generating electricity and charging the battery.

The shower head according to the embodiment of the first aspect of the utility model has at least the following beneficial effects: the shower head switches the flow path of water through the first valve and the second valve, and has various water outlet functions. Wherein, first valve and second valve are controlled through the control panel, and the battery supplies power to the control panel. Since the shower head provided by the utility model is provided with the first wireless charging coil for charging the battery, when the electric quantity of the battery is insufficient, a user can charge the battery of the shower head in a wireless charging mode. This means that, in the use of the shower, the number of times that the user needs to detach the shower and replace the battery is small, and the convenience of using the shower is high. In addition, as the shower head is charged in a wireless charging mode, the shower head does not need to be provided with an exposed plug, the plug does not need to be inserted into a socket in the use process of the shower head, the socket for supplying power to the shower head does not need to be arranged in a bathroom, and the safety of a user when the shower head is used in the bathroom is high.

According to some embodiments of the utility model, the water sprayer further comprises a hydroelectric generator mounted inside the housing assembly, the hydroelectric generator being electrically connected to the control board, the hydroelectric generator generating electricity and charging the battery when water flows through the hydroelectric generator; wherein the hydroelectric generator is located between the water inlet and the first water outlet, and/or the hydroelectric generator is located between the water inlet and the second water outlet.

According to some embodiments of the utility model, the hydro-generator has a generator water inlet and a generator water outlet in communication with each other, the generator water inlet being in communication with the water inlet, the housing assembly further having a water passing chamber, a first water passing port and a second water passing port, the generator water outlet, the first water passing port and the second water passing port each being in communication with the water passing chamber; when the first valve is opened, the first water passing port is communicated with the first water outlet; when the second valve is opened, the second water passing port is communicated with the second water outlet.

According to some embodiments of the utility model, the housing assembly further has a water diversion chamber, a diversion inlet, a first diversion outlet, a second diversion outlet, the diversion inlet, the first diversion outlet, and the second diversion outlet all in communication with the water diversion chamber, the diversion inlet also in communication with the water inlet when the second valve is opened; the shower head further comprises an impeller and a water diversion disc, wherein the impeller is rotationally connected with the shell assembly and is arranged in the water diversion cavity, the central axis of the water diversion inlet is arranged along the tangential direction of the impeller, so that water entering the water diversion cavity from the water diversion inlet can push the impeller to rotate, the water diversion disc is connected with the impeller and is arranged in the water diversion cavity, and when the impeller rotates, the water diversion disc periodically covers the first water diversion outlet and the second water diversion outlet; the shell assembly comprises a second water outlet nozzle, wherein the second water outlet nozzle is provided with a first swing inlet, a second swing inlet and a second water outlet, the first swing inlet and the second swing inlet are communicated with the second water outlet, and the orientation of the first swing inlet is different from the orientation of the second swing inlet; when the water distribution disc is uncovered on the first diversion outlet, the first diversion outlet is communicated with the first swing inlet; when the water distribution disc is uncovered on the second water distribution outlet, the second water distribution outlet is communicated with the second swing inlet.

According to some embodiments of the utility model, the housing assembly further has a water diversion chamber in communication with the diversion inlet, a diversion inlet in communication with the second water outlet, and a diversion outlet in communication with the water inlet when the second valve is opened; the shower head further includes: the impeller is rotationally connected with the shell component and is arranged in the water distribution cavity, and the central axis of the diversion inlet is arranged along the tangential direction of the impeller so that water entering the water distribution cavity from the diversion inlet can push the impeller to rotate; and the water distribution disc is connected with the impeller and arranged in the water distribution cavity, when the impeller rotates, the water distribution disc periodically covers the water distribution outlet, and when the water distribution disc releases the cover of the water distribution outlet, the water distribution outlet is communicated with the second water outlet.

According to some embodiments of the utility model, a wall surface of the water diversion cavity is provided with first speed reducing teeth, the first speed reducing teeth are distributed around a central axis of the impeller, the water diversion disk is eccentrically connected with the impeller, the periphery of the water diversion disk is provided with second speed reducing teeth, the second speed reducing teeth are meshed with the first speed reducing teeth, and the number of the second speed reducing teeth is smaller than that of the first speed reducing teeth.

According to a second aspect of the utility model, an embodiment of a shower apparatus comprises: the shower head according to the embodiment of the first aspect; the remote controller is connected with the shower head in a wireless communication mode, and can send signals to the control panel, so that the first valve is opened and closed, and the second valve is opened and closed.

The shower device of the embodiment has at least the following beneficial effects: the user can control the water outlet mode of the shower head through the remote controller, and the arrangement mode has the advantage that a cable for connecting the shower head with a control device for controlling the shower head is not needed. Therefore, a space for the cable to penetrate is not needed to be reserved in the shower, and the volume of the shower can be reduced; in addition, the shower device does not need to be provided with a cable which penetrates from the shower head and is exposed to the bathroom environment, so that the safety of the shower device is improved.

According to some embodiments of the utility model, the shower apparatus further comprises a wireless charger having a wireless charging transmitting coil, the remote control having a second wireless charging coil; when the wireless charger is placed on the shower or the shower is placed on the wireless charger, the wireless charging transmitting coil is magnetically coupled with the first wireless charging coil; when the wireless charger is placed on the remote controller or the remote controller is placed on the wireless charger, the wireless charging transmitting coil is magnetically coupled with the second wireless charging coil.

According to some embodiments of the utility model, a shower head as described in the embodiments of the first aspect; the wireless charger is provided with a wireless charging transmitting coil, and when the wireless charger is placed on the shower or the shower is placed on the wireless charger, the wireless charging transmitting coil is magnetically coupled with the first wireless charging coil.

According to some embodiments of the utility model, the shower device comprises a shower head according to an embodiment of the first aspect; the wireless charger is provided with a wireless charging transmitting coil, and when the wireless charger is placed on the shower or the shower is placed on the wireless charger, the wireless charging transmitting coil is magnetically coupled with the first wireless charging coil.

The shower device of the embodiment has the following beneficial effects: the wireless charger can carry out wireless charging for the gondola water faucet, and the user needs to tear open the gondola water faucet and change the number of times of the battery in the gondola water faucet and reduce, therefore, shower device's use convenience is higher.

According to some embodiments of the utility model, the housing assembly includes an upwardly disposed mounting surface, the mounting surface being a horizontal surface, and the wireless charging transmitting coil is magnetically coupled to the first wireless charging coil when the wireless charger is mounted on the mounting surface.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The utility model is further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a schematic view of a shower head in one embodiment of the utility model;

FIG. 2 is an exploded view of the sprinkler of FIG. 1;

FIG. 3 is an exploded view of the water outlet panel of FIG. 2;

FIG. 4 is an exploded view of the water outlet panel of FIG. 2 from another perspective;

FIG. 5 is a schematic view of the sprinkler of FIG. 1 with the first cover removed;

FIG. 6 is a cross-sectional view of the sprinkler of FIG. 1;

FIG. 7 is an enlarged schematic view of area A of FIG. 6;

FIG. 8 is a schematic diagram of the mating relationship of a impeller, a water distribution tray, and a water distribution chamber in accordance with one embodiment of the present utility model;

FIG. 9 is a schematic view of the mating relationship of the impeller, the water distribution tray and the water distribution chamber at another view angle (top view);

FIG. 10 is a schematic view of a flow path of water flowing to a second water outlet according to an embodiment of the present utility model;

FIG. 11 is an enlarged schematic view of area B of FIG. 3;

FIG. 12 is a schematic view showing the relative positions of a first swing inlet, a second swing inlet and a second water outlet according to an embodiment of the present utility model;

Fig. 13 is a schematic view of a shower device in one embodiment of the utility model.

Reference numerals:

100-of a shower head, 101-of a ball nut, 102-of a ball, 103-of a first cover body, 104-of a screw, 105-of a second cover body, 106-of an impeller, 107-of a water outlet panel, 108-of a battery, 109-of a hydroelectric generator, 110-of a control panel, 111-of a charging panel, 112-of a first valve, 113-of a second valve, 114-of a mounting seat, 115-of a shell assembly, 116-of a second water outlet, 117-of a first water outlet, 118-of a water inlet, 119-of a placing surface;

201-first shell member, 202-second shell member, 203-third shell member, 204-fourth shell member, 205-fifth shell member, 206-sixth shell member, 207-first through hole, 208-second through hole, 209-third through hole, 210-first swing inlet, 211-fourth through hole, 212-first escape hole, 213-second escape hole, 214-second swing inlet, 215-seventh through hole;

301-first surrounding rib, 302-second surrounding rib, 303-fifth through hole, 304-third surrounding rib, 305-sixth through hole, 306-second water outlet nozzle, 307-first water outlet nozzle;

401-first path, 402-second path, 403-third path, 404-first water flow, 405-second water flow;

501-a first water passing port, 502-a second water passing port, 503-a generator water inlet, 504-a generator water outlet, 505-a generator impeller, 506-a shell and 507-a water passing cavity;

601-a water distribution cavity, 602-a distribution inlet, 603-a first distribution outlet, 604-a water distribution disc, 605-a second distribution outlet, 606-a first speed reducing tooth and 607-a second speed reducing tooth;

701-shower device, 702-wireless charger, 703-remote control.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, the meaning of a number is one or more, the meaning of a number is two or more, and greater than, less than, exceeding, etc. are understood to exclude the present number, and the meaning of a number is understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

The shower head 100 of the present utility model may be used as a top shower head or as a hand shower head. That is, the shower head 100 of the present utility model may be fixedly installed in the bathroom above the top of the user's head, or may be installed in the bathroom in a non-fixed form (may be held by the user's hand and moved along with the user's hand). In the present utility model, the communication between two holes means that water can flow from one hole to the other hole when flowing in the shower 100, and the two holes are not necessarily directly connected, and water can flow from one hole to the other hole through some flow channels or passages in the shower 100.

Fig. 1 illustrates a shower head 100 in one embodiment of the present utility model, and fig. 2 illustrates an exploded view of the shower head 100 in fig. 1. Referring to fig. 1 and 2, the shower head 100 includes a housing assembly 115, a first valve 112, a second valve 113, a control board 110, a battery 108, and a charging board 111.

The charging pad 111 includes a housing and a first wireless charging coil located inside the housing, the housing being configured to protect the first wireless charging coil and reduce the risk of damage to the first wireless charging coil. The housing may be insulating, e.g. the housing is provided as a hard plastic shell; the case may also be provided as a flexible case, for example, a flexible insulating film, an insulating tape, or the like, which is wrapped around the outside of the first wireless charging coil.

Referring to fig. 2, the housing assembly 115 specifically includes a ball head 102, a first cover 103, a second cover 105, a mounting base 114, and a water outlet panel 107, wherein the water outlet panel 107 is formed by assembling a plurality of housing members to each other. As shown in fig. 3 and 4, the water outlet panel 107 includes a first case 201, a second case 202, a third case 203, a fourth case 204, a fifth case 205, and a sixth case 206 distributed from top to bottom. The six shells cooperate to define a flow path for water. As shown in fig. 5, the shower head further includes a ball nut 101, where the ball nut 101 is screwed with the top of the mounting base 114, and fixes the ball 102 on the top of the mounting base 114. The second cover 105 is fixed to the top of the first case 201 by the screw 104.

Referring to fig. 1 and 2, the housing assembly 115 has a water inlet 118, a first water outlet 117, and a second water outlet 116, and water may enter the showerhead 100 from the water inlet 118 and exit the showerhead 100 from either the first water outlet 117 or the second water outlet 116. As shown in fig. 2, a water inlet 118 may be provided at the top of the ball head 102. As shown in fig. 4, the fourth housing 204 has a plurality of first water nozzles 307, and a bottom end of each first water nozzle 307 has a first water outlet 117, and the first water nozzle 307 passes through the first avoiding hole 212 of the fifth housing 205 from top to bottom and protrudes downward with respect to the bottom surface of the fifth housing 205. As shown in fig. 4, the third housing member 203 has a plurality of second water nozzles 306, and each second water nozzle 306 has a second water outlet 116 at its bottom end, and the second water nozzles 306 pass through the second avoidance holes 213 of the sixth housing member 206 from top to bottom and protrude downward with respect to the bottom surface of the sixth housing member 206. Referring again to fig. 1, the second water outlet 116 is located at the periphery of the first water outlet 117.

The first valve 112, the second valve 113, the control board 110, the battery 108, and the charging board 111 are all mounted inside the housing assembly 115. More specifically, referring to fig. 5, fig. 5 shows the sprinkler 100 of fig. 1 after the first cover 103 is removed. The mounting base 114 is fixed to the top of the first housing 201 of the water outlet panel 107, the first valve 112 and the second valve 113 are both installed in the mounting base 114, and the control board 110, the battery 108 and the charging board 111 are directly connected to the top of the first housing 201. Referring to fig. 2 and 5, after the first cover 103 is connected to the water outlet panel 107, the first cover 103 is covered over the water outlet panel 107, and the first valve 112, the second valve 113, the control board 110, the battery 108 and the charging board 111 are all located in the space enclosed by the first cover 103 and the first housing 201. In this way, the first valve 112, the second valve 113, the control board 110, the battery 108, and the charging board 111 can be located inside the housing assembly 115.

The first valve 112 and the second valve 113 are electrically connected to the control board 110 (wires for making electrical connection are not shown), and the control board 110 is used to switch the states of the first valve 112 and the second valve 113. The first valve 112 and the second valve 113 may each be provided as a solenoid valve, and the control board 110 may be provided as a PCB (Printed Circuit Board ). When the first valve 112 is in an open state, the water inlet 118 is communicated with the first water outlet 117, and water flows out from the first water outlet 117 of the shower head 100; when the second valve 113 is in an open state, the water inlet 118 communicates with the second water outlet 116, and water flows out of the second water outlet 116 of the sprinkler 100. When the different valves are opened, the water outlet positions of the bottom of the shower head 100 are different, so that the shower head 100 having the first valve 112 and the second valve 113 means that the shower head 100 has various water outlet functions.

The battery 108 is electrically connected to the control board 110 (wires for making electrical connection are not shown), the battery 108 is used to power the control board 110, and the control board 110 powers the first valve 112 and the second valve 113, thereby operating the first valve 112 and the second valve 113. A first wireless charging coil inside the charging plate 111 is electrically connected to the control board 110 (a wire for making an electrical connection is not shown), and the first wireless charging coil is used to generate electricity and charge the battery 108. For example, after the shower head 100 is placed on a wireless charging stand, a transmitting coil in the wireless charging stand is magnetically coupled with a first wireless charging coil, and the transmitting coil generates an alternating magnetic field due to the alternating current, and the first wireless charging coil is in the alternating magnetic field and generates a current under the action of the alternating magnetic field, and the current flows through the control board 110 and the battery 108 in sequence, so that the battery 108 is charged.

The operation of the control panel 110, the first valve 112 and the second valve 113 requires power consumption, and after the shower head 100 is used for a long period of time, the electric quantity of the battery 108 may be insufficient. Since the shower head 100 of the present utility model has the first wireless charging coil for charging the battery 108, the user can charge the battery 108 of the shower head 100 by wireless charging when the electric quantity of the battery 108 is insufficient. This means that the number of times the user disassembles the showerhead 100 and replaces the battery 108 is reduced during the use of the showerhead 100, and the convenience of use of the showerhead 100 is high. In addition, since the shower head 100 is charged in a wireless charging manner, the shower head 100 does not need to be provided with an exposed plug, and the plug does not need to be inserted into a socket in the use process of the shower head 100, so that the safety of a user in using the shower head 100 in a bathroom is high.

The internal structure of the sprinkler 100 is further described below.

The shower head 100 of the present utility model is provided with a first valve 112 and a second valve 113 in order to provide various water outlet functions. The following is a brief description of which water outlet functions the sprinkler 100 may have. For convenience of description, the water outlet mode of the valve when only the first valve 112 is opened will be referred to as a first mode, the water outlet mode of the sprinkler 100 when only the second valve 113 is opened will be referred to as a second mode, and the water outlet mode of the sprinkler 100 when the first valve 112 and the second valve 113 are simultaneously opened will be referred to as a third mode.

Referring to fig. 1, in some embodiments, when the showerhead 100 is in the first mode, water flows out of the first water outlet 117 of the showerhead 100 and the water flow is a continuous direct water flow; when the sprinkler 100 is in the second mode, water flows out from the second water outlet 116 of the sprinkler 100, and the water flow is continuous direct water flow at the moment; when the sprinkler 100 is in the third mode, water flows out from the second water outlet 116 and the first water outlet 117 simultaneously, and the water flow is continuous direct water flow. In this arrangement, the user switches the water outlet mode of the shower head 100, mainly to the water outlet position of the shower head 100.

Alternatively, in other embodiments, when the showerhead 100 is in the first mode, water flows out of the first water outlet 117 of the showerhead 100 and the water flow is a continuous direct water flow; when the shower head 100 is in the second mode, water flows out from the second water outlet 116 of the shower head 100, and the water flow is a waving water flow at the moment; when the sprinkler 100 is in the third mode, water flows out from the second water outlet 116 and the first water outlet 117 simultaneously, and at this time, the water flow out from the first water outlet 117 is continuous direct water flow, and the water flow out from the second water outlet 116 is galloping water flow. The user can be brought better visual experience to the rivers of waving, and under this kind of setting up mode, the user switches the play water mode of gondola water faucet 100, can switch the state of the play water rivers of gondola water faucet 100.

Still or, in other embodiments, when the showerhead 100 is in the first mode, water flows out of the first water outlet 117 of the showerhead 100 and the water flow is a continuous direct water flow; when the sprinkler 100 is in the second mode, water intermittently flows out from the second water outlet 116 of the sprinkler 100; when the sprinkler 100 is in the third mode, water flows out from the second water outlet 116 and the first water outlet 117 simultaneously, at this time, the water flow out from the first water outlet 117 is continuous direct water flow, and water intermittently flows out from the second water outlet 116. The intermittent water flow from the second water outlet 116 can intermittently press the skin of the user, and has a good massage effect on the body of the user.

Referring to fig. 1 and 2, in one embodiment, the showerhead 100 further includes a hydro-generator 109, the hydro-generator 109 being mounted inside the housing assembly 115. Specifically, referring to fig. 2 and 5, the hydro-generator 109 is mounted on the mount 114, and the mount 114 is located in a space surrounded by the first cover 103 and the first case 201. The hydro-generator 109 is electrically connected to a control board 110 (wires for making electrical connection are not shown) and the hydro-generator 109 charges the battery 108 as water flows through the hydro-generator 109. The position of the hydro-generator 109, as seen along the flow path of the water in the showerhead 100, satisfies at least one of two conditions: (1) The hydro-generator 109 is located between the water inlet 118 and the first water outlet 117; (2) The hydro-generator 109 is positioned between the water inlet 118 and the second water outlet 116.

In this way, when the sprinkler 100 is in one or more water-out modes, the kinetic energy of the water inside the sprinkler 100 can be converted into electrical energy and charge the battery 108. Because hydroelectric generator 109 also can charge gondola water faucet 100, the time interval between the adjacent two wireless charging of gondola water faucet 100 can be prolonged, and the frequency that the user carries out wireless charging to gondola water faucet 100 can be reduced, is favorable to improving gondola water faucet 100's use convenience like this.

Referring to fig. 6, hydro-generator 109 includes a housing 506, a generator impeller 505, coil windings, and magnets (coil windings and magnets not shown). The housing 506 is fixedly connected with the mounting base 114, and the housing 506 is provided with a generator water inlet 503 and a generator water outlet 504 which are communicated with each other. The dashed arrow in fig. 7 shows the flow of water from the water inlet 118 to the generator water inlet, after the water enters the interior of the housing 506 through the generator water inlet 503, the water pushes the generator impeller 505 to rotate and then exits the hydro-generator 109 from the generator water inlet 503. One of the coil windings and the magnets is fixed relative to the generator wheel 505 and the other is fixed relative to the housing 506, and when the generator wheel 505 rotates, the coil windings rotate relative to the magnets, the hydro-generator 109 generates electricity and charges the battery 108.

In an embodiment, the hydro-generator 109 may satisfy both the condition (1) and the condition (2), so that the hydro-generator 109 may charge the battery 108 of the showerhead 100 no matter in which water outlet mode the showerhead 100 is operated, and the frequency of wirelessly charging the showerhead 100 may be further reduced (compared to only satisfying the condition (1) or only satisfying the condition (2)).

The manner in which the hydro-generator 109 can simultaneously satisfy the above-described condition (1) and condition (2) is as follows. Referring to fig. 7, the generator water inlet 503 communicates with the water inlet 118, and the housing assembly 115 further has a water passing cavity 507, a first water passing port 501 and a second water passing port 502, and the water passing cavity 507, the first water passing port 501 and the second water passing port 502 may be disposed on the mounting base 114. That is, the water passing chamber 507, the first water passing port 501 and the second water passing port 502 are all disposed inside the housing assembly 115. The dashed arrows in fig. 7 show the flow direction of the water. Wherein, the generator water outlet 504, the first water passing port 501 and the second water passing port 502 are all communicated with the water passing cavity 507, and water flows out from the generator water outlet 504, then enters the water passing cavity 507 and flows to the first water passing port 501 and the second water passing port 502. When the first valve 112 is opened, the first water passing port 501 is communicated with the first water outlet 117, and water finally flows out from the first water outlet 117 after passing through the first water passing port 501; when the first valve 112 is closed, the first water passing port 501 and the first water outlet 117 are separated by the first valve 112, and water cannot flow out from the first water outlet 117. When the second valve 113 is opened, the second water passing port 502 is communicated with the second water outlet 116, and water finally flows out from the second water outlet 116 after passing through the second water passing port 502; when the second valve 113 is closed, the second water passing port 502 is separated from the second water outlet 116 by the second valve 113, and water cannot flow out from the second water outlet 116. That is, after flowing through the hydro-generator 109, the water is further divided into the first valve 112 or the second valve 113, so that the hydro-generator 109 can charge the battery 108 of the sprinkler 100 no matter in which water outlet mode the sprinkler 100 is operated.

The first valve 112 and the second valve 113 may each be provided as a solenoid valve. The first valve 112 comprises an electromagnet and a valve core, when the first valve 112 is closed, the valve core covers and seals the first water passing port 501, so that the first water passing port 501 is separated from the first water outlet 117; when the first valve 112 is opened, the electromagnet is energized and attracts the valve spool, and the first water passing port 501 is uncovered by the valve spool, thereby communicating with the first water passing port 501. The principle of how the second valve 113 communicates or separates the first water passing port 501 and the first water outlet 117 may refer to the working principle of the first valve 112, and will not be repeated here.

The structure of the water outlet panel 107 will be described below, and a flow path of water after flowing through the first valve 112 or the second valve 113 will be described.

Referring to fig. 4, when the sprinkler 100 is in the first mode, a flow path of water in the water outlet panel 107 is shown as a first path 401. Referring to fig. 4, the first case 201 includes a first through hole 207, a second through hole 208, a first enclosing rib 301, and a second enclosing rib 302, the first enclosing rib 301 encloses the outside of the first through hole 207, and the second through hole 208 is located outside the first enclosing rib 301 and enclosed by the second enclosing rib 302. The second housing 202 includes a third through hole 209 and a third enclosing rib 304, and the third enclosing rib 304 encloses the outside of the third through hole 209. The third housing member 203 includes a fourth through hole 211. After the water outlet panel 107 is assembled, the bottom of the first enclosing rib 301 and the bottom of the second enclosing rib 302 are both abutted with the top surface of the second shell 202, the bottom of the third enclosing rib 304 is abutted with the top surface of the third shell 203, the third through hole 209 is enclosed by the first enclosing rib 301, and the fourth through hole 211 is enclosed by the third enclosing rib 304. As described above in connection with fig. 7, water flowing out of the first water passing port 501 enters the first through hole 207; referring to fig. 4, after passing through the first through hole, the water flows through the third through hole 209 and the fourth through hole 211 in sequence, and finally flows out of the first water outlet 117 of the first water outlet 307.

The water flow path when the sprinkler 100 is in the second mode will be described. Referring to fig. 4, the first case 201 further includes a fifth through hole 303, and the fifth through hole 303 is located outside the first enclosing rib 301 and enclosed by the second enclosing rib 302. As described above with reference to fig. 7, when the sprinkler 100 is in the second mode, water may pass through the second water passing port 502. Referring to fig. 4 and 7, after passing through the second water passing hole 502, water passes through the second through hole 208, and then flows in the space defined by the first enclosing rib 301, the second enclosing rib 302, and the top surface of the second casing 202, and flows into the fifth through hole 303; the general flow of water during this process may be referred to as the dashed path in fig. 5, wherein the second cover 105 would be located above the fifth through hole 303.

Referring to fig. 8, the first housing member 201 of the housing assembly 115 further has a water diversion chamber 601, and a diversion inlet 602, a first diversion outlet 603, and a second diversion outlet 605 in communication with the water diversion chamber 601. In fig. 8, the top of the water diversion cavity 601 is open, but referring to fig. 2, the second cover 105 is used to cover and close the top of the water diversion cavity 601, so as to prevent water from flowing out of the top of the water diversion cavity 601 and contacting with the charged components such as the control board 110.

Referring to fig. 9, after passing through the fifth through hole 303, water flows to the split inlet 602 and enters the water distribution chamber 601 from the split inlet 602. That is, as will be appreciated in conjunction with fig. 7 and 8, when the second valve 113 is open, the water inlet 118 and the shunt inlet 602 are in communication. The water entering the water diversion chamber 601 will flow to the second water outlet 116 through two different paths, and the water in the water diversion chamber 601 can flow out from the first diversion outlet 603 or the second diversion outlet 605.

The sprinkler 100 further comprises an impeller 106 and a water distribution plate 604, the impeller 106 and the water distribution plate 604, the impeller 106 being rotatably connected to the housing assembly 115 (the impeller 106 being in particular connected to the first housing member 201), the water distribution plate 604 being rotatable with the impeller 106. The water distribution tray 604 intermittently covers the first and second distribution outlets 603 and 605 as the water distribution tray 604 rotates. For example, in fig. 8, the water distribution tray 604 covers the first distribution outlet 603 and does not cover the second distribution outlet 605; if the water diversion plate 604 is rotated 180 ° around the central axis of the impeller 106 based on the state shown in fig. 8, the water diversion plate 604 will cover the second diversion outlet 605, and the first diversion outlet 603 is not covered by the water diversion plate 604; when the water distribution plate 604 rotates a plurality of times, the water distribution plate 604 intermittently (or periodically) covers the first and second distribution openings 603 and 605. As shown in fig. 9, the central axis of the split inlet 602 is arranged along the tangential direction of the impeller 106, and after water flows into the water dividing cavity 601 from the split inlet 602, the water flow can push the impeller 106 to rotate.

As shown in fig. 11, the third housing member 203 has a second water outlet nozzle 306, and the second water outlet nozzle 306 has a first swing inlet 210 and a second swing inlet 214. As shown in fig. 12, the second water outlet 116 is also disposed on the third housing 203. The first swing inlet 210 and the second swing inlet 214 are oriented differently, and in fig. 11, the first swing inlet 210 is located at the top of the second water outlet nozzle 306 and is disposed upward; the second swing inlet 214 is located at a side portion of the second water outlet nozzle 306, and the second swing inlet 214 is oriented the same as the circumferential direction of the third housing member 203.

When the first diverting outlet 603 is not covered by the water diversion tray 604, the first swing inlet 210 communicates with the first diverting outlet 603. Referring to fig. 10, the edge position of the second case 202 further has a seventh through hole 215. When the first diverting outlet 603 is uncovered by the water diversion disk 604 (the state of the water diversion disk in fig. 8 rotated 180 °), water flows along the top surface of the second casing 202 (as shown in fig. 10) after passing through the first diverting outlet 603, and flows to the seventh through hole 215 at the edge of the second casing 202, during which the water flows along the second path 402; next, as shown in fig. 12, the water sequentially flows through the first swing inlet 210 and the second water outlet 116 after passing through the seventh through hole 215. That is, when the first diverting outlet 603 is not covered by the diverter tray 604, the first diverting outlet 603 communicates with the second water outlet 116.

When the second outflow port 605 is not covered by the water separation disc 604, the second swing inlet 214 communicates with the second outflow port 605. Referring to fig. 8, the second housing member 202 further has a sixth through hole 305, the sixth through hole 305 being in communication with the second outflow port 605, and, as shown in fig. 3, the sixth through hole 305 being located outside the third enclosing rib 304. Referring to fig. 8, when the second outflow port 605 is not covered by the water diversion plate 604, water passes through the sixth through hole 305 after passing through the second outflow port 605; subsequently, as shown in fig. 10, water flows on the top surface of the third housing member 203 and flows to the second swing inlet 214 at the edge position of the third housing member 203, during which the water flows along the third path 403; the water flows into the second water outlet nozzle 306 after passing through the second swing inlet 214, and finally flows out of the second water outlet 116 of the second water outlet nozzle 306. That is, when the second tap 605 is not covered by the water diversion tray 604, the second tap 605 communicates with the second water outlet 116.

Fig. 12 is a schematic view of the relative positions of the first swing inlet 210, the second swing inlet 214, and the second water outlet 116. Referring to fig. 12, the water flow sequentially passing through the first swing inlet 210 and the second water outlet 116 is referred to as a first water flow 404, the water flow sequentially passing through the second swing inlet 214 and the second water outlet 116 is referred to as a second water flow 405, and the paths of the first water flow 404 and the second water flow 405 are different due to the different positions of the first swing inlet 210 and the second swing inlet 214, and the directions of the first water flow 404 and the second water flow 405 after flowing out from the second water outlet 116 are different. On this basis, the water diversion plate 604 intermittently covers the first diversion outlet 603 and the second diversion outlet 605, so that the water flowing out of the second water outlet 116 can be periodically switched between the first water flow 404 and the second water flow 405, and thus the water flowing out of the second water outlet 116 can be swung (or swung) to realize the water flowing out.

Referring to fig. 9, in an embodiment, a wall surface of the water distribution chamber 601 is provided with first deceleration teeth 606, the first deceleration teeth 606 are distributed around a central axis of the impeller 106 (i.e., a rotation axis of the impeller 106), the water distribution plate 604 is eccentrically connected with the impeller 106, the periphery of the water distribution plate 604 is provided with second deceleration teeth 607, the second deceleration teeth 607 are meshed with the first deceleration teeth 606, and the number of the second deceleration teeth 607 is less than that of the first deceleration teeth 606. The cooperation of the first decelerating tooth 606 and the second decelerating tooth 607 can decelerate the impeller 106 and the water diversion disk 604, so as to avoid the poor water flow waving effect caused by too fast water flow waving.

The above explanation of the flow path of water in the water outlet panel 107 assembly is based on the embodiment in which the water flow is dancing water when the sprinkler 100 is in the second mode. If the water flow is massage water (intermittent water outlet) when the sprinkler 100 is in the second mode, the sprinkler 100 may be provided with only one diverting outlet, for example, the second diverting outlet 605 and the second swing inlet 214 may be omitted, leaving the impeller 106, the diverting disc 604 and the first diverting outlet 603, based on the above-described embodiment. Thus, when the diverter tray 604 covers the diverter outlet (the first diverter outlet 603), the diverter tray 604 separates the diverter outlet from the second outlet 116, and the second outlet 116 does not discharge water. Accordingly, the water distribution tray 604 intermittently covers the distribution outlet to intermittently discharge the water from the second water outlet 116. Moreover, the slow down fit between the water distribution tray 604 and the walls of the water distribution chamber 601 can be maintained to prevent the massage water from becoming a continuous direct flow. If the water flow is a continuous direct water flow when the sprinkler 100 is in the second mode, the water distribution tray 604, the impeller 106, the second swing inlet 214, and the second outflow port 605 may not be provided with the sprinkler 100.

The utility model also provides a shower device 701, the shower device 701 comprising the shower head 100 according to any of the embodiments described above.

Referring to fig. 13, in one embodiment, a shower apparatus 701 includes a showerhead 100 and a remote control 703. The shower head 100 and the remote controller 703 are separately provided, and the remote controller 703 is connected to the shower head 100 by wireless communication. The remote control 703 can send a signal to the control board 110 to open and close the first valve 112 and the second valve 113. More specifically, the remote control 703 and the shower head 100 may be connected by a communication method such as 2.4G, bluetooth, wifi, etc. The remote controller 703 has physical keys or a touch screen, and a wireless signal transmitting module is arranged inside the remote controller 703; accordingly, the control board 110 of the sprinkler 100 is integrated with a wireless signal receiving module. When the user presses a key on the remote control 703 or a virtual key in the touch screen, the remote control 703 sends a signal to the control board 110, and the control board 110 switches the states of the first valve 112 and the second valve 113 according to the signal.

That is, the user can control the water outlet mode of the shower head 100 through the remote controller 703, which is advantageous in that it is not necessary to provide a cable for connecting the shower head 100 to a control device for controlling the shower head 100. In this way, a space for the cable to pass through is not required to be reserved in the shower head 100, and the volume of the shower head 100 can be reduced; in addition, the shower device 701 does not need to be provided with a cable which is penetrated out of the shower head 100 and exposed to the bathroom environment, which is advantageous in improving the safety of the shower device 701.

Referring to fig. 13, in one embodiment, a shower apparatus 701 includes a showerhead 100 and a wireless charger 702, the wireless charger 702 being capable of charging the showerhead 100. The wireless charger 702 has a wireless charging transmitting coil (not shown) inside, and the wireless charging coil is magnetically coupled with the first wireless charging coil when the wireless charger 702 is placed on the shower head 100 or the shower head 100 is placed on the wireless charger 702. The magnetic coupling between two coils means that the mutual influence between the two coils is linked by a magnetic field, and the current change of one coil can cause the adjacent coils to generate induced electromotive force. When the wireless charging coil is powered with ac, the wireless charging coil generates an alternating magnetic field, the first wireless charging coil inside the shower head 100 is in the alternating magnetic field and generates voltage and current under the action of the alternating magnetic field, and the current flows to the battery 108 through the control board 110, so as to charge the battery 108 of the shower head 100.

In the case where the shower 100 is set as a top spray, a user may place the wireless charger 702 on the shower 100, thereby causing the wireless charger 702 to charge the shower 100. For example, the outer surface of the housing assembly 115 includes an upwardly disposed placement surface 119, as shown in fig. 2, the placement surface 119 may be a portion of the upper surface of the first cover 103; the placement surface 119 is a horizontal surface, and when the wireless charger 702 is placed on the placement surface 119, a wireless charging transmitting coil in the wireless charger 702 is magnetically coupled with a first wireless charging coil of the shower head 100. Providing a horizontal placement surface 119 is advantageous for improving the stability of the wireless charger 702 when placed on the showerhead 100. Further, the wireless charger 702 may be further configured in a flat plate shape to improve stability of the wireless charger 702 when placed on the shower head 100.

The advantage of charging the shower head 100 by placing the wireless charger 702 on the shower head 100 is that the shower head 100 is high in operation convenience, and a user does not need to detach the shower head 100 or fix the wireless charger 702 at the bottom of the shower head 100 by using an adhesive tape, a rope or the like.

It should be noted that, the wireless charger 702 has an interface (for example, a USB interface, the interface is not shown) and a battery, the interface of the wireless charger 702 may be connected to an external power supply through a cable, and the external power supply charges the battery of the wireless charger 702; when the wireless charger 702 charges the showerhead 100, the battery of the wireless charger 702 may power the wireless charging coil. After the wireless charger 702 charges itself, the user can unplug the cable connected to the wireless charger 702 and then take the wireless charger 702 into the bathroom and place it on the placement surface 119 of the shower head 100, thereby charging the shower head 100.

In the case where the shower apparatus 701 includes the shower head 100 and the wireless charger 702, the shower apparatus 701 may further include a remote controller 703, and, as shown in fig. 13, the wireless charger 702 may charge either the shower head 100 or the remote controller 703. Specifically, the remote controller 703 has a second wireless charging coil, and the wireless charging transmitting coil is magnetically coupled with the second wireless charging coil when the remote controller 703 is placed on the wireless charger 702 or the wireless charger 702 is placed on the remote controller 703. The principle of charging the remote controller 703 by the wireless charger 702 is similar to that of charging the shower head 100 by the wireless charger 702, and a description thereof will not be repeated here. Because the wireless charger 702 can charge the shower head 100 and the remote controller 703, the replacement frequency of the battery 108 of the remote controller 703 is reduced, and the use convenience of the remote controller 703 is improved; furthermore, in the shower device 701, different remote controllers 703 are not required to be configured for the remote controller 703 and the shower head 100, and the shower head 100 and the remote controller 703 share one wireless charger 702, which is beneficial to reducing the overall cost of the shower device 701.

In some embodiments, after the user opens the shower head 100 through the remote control 703, the first valve 112 is opened for a first preset time, then the first valve 112 is closed, and then the second valve 113 is opened for a second preset time. The arrangement can discharge residual cold water in the shower head 100 when the shower head 100 is just started, so that the shower experience of a user is improved. In some specific embodiments, the first preset time may be 30 seconds and the second preset time may be 15 seconds.

In the description of the present utility model, the descriptions of the terms "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Claims (10)

1. Gondola water faucet, its characterized in that includes:

A housing assembly having a water inlet, a first water outlet, and a second water outlet;

the first valve is arranged in the shell assembly, and when the first valve is opened, the water inlet is communicated with the first water outlet;

the second valve is arranged in the shell assembly, and when the second valve is opened, the water inlet is communicated with the second water outlet;

the control board is arranged in the shell assembly, the first valve and the second valve are electrically connected with the control board, and the control board is used for switching the states of the first valve and the second valve;

the battery is arranged in the shell assembly, is electrically connected with the control panel and supplies power for the control panel;

the first wireless charging coil is installed in the shell assembly, the first wireless charging coil is electrically connected with the control panel, and the first wireless charging coil is used for generating electricity and charging the battery.

2. The showerhead of claim 1 further comprising a hydro-generator mounted within the housing assembly, the hydro-generator electrically connected to the control panel, the hydro-generator generating electricity and charging the battery as water flows through the hydro-generator;

Wherein the hydroelectric generator is located between the water inlet and the first water outlet, and/or the hydroelectric generator is located between the water inlet and the second water outlet.

3. The showerhead of claim 2 wherein the hydro-generator has a generator water inlet and a generator water outlet in communication with each other, the generator water inlet in communication with the water inlet, the housing assembly further having a water passing chamber, a first water passing port and a second water passing port, the generator water outlet, the first water passing port and the second water passing port each in communication with the water passing chamber;

when the first valve is opened, the first water passing port is communicated with the first water outlet; when the second valve is opened, the second water passing port is communicated with the second water outlet.

4. The showerhead of claim 1 wherein the housing assembly further has a water diversion chamber, a diversion inlet, a first diversion outlet, a second diversion outlet, the diversion inlet, the first diversion outlet and the second diversion outlet each communicating with the water diversion chamber, the diversion inlet also communicating with the water inlet when the second valve is open;

The shower head further comprises an impeller and a water diversion disc, wherein the impeller is rotationally connected with the shell assembly and is arranged in the water diversion cavity, the central axis of the water diversion inlet is arranged along the tangential direction of the impeller, so that water entering the water diversion cavity from the water diversion inlet can push the impeller to rotate, the water diversion disc is connected with the impeller and is arranged in the water diversion cavity, and when the impeller rotates, the water diversion disc periodically covers the first water diversion outlet and the second water diversion outlet;

the shell assembly comprises a second water outlet nozzle, wherein the second water outlet nozzle is provided with a first swing inlet, a second swing inlet and a second water outlet, the first swing inlet and the second swing inlet are communicated with the second water outlet, and the orientation of the first swing inlet is different from the orientation of the second swing inlet;

when the water distribution disc is uncovered on the first diversion outlet, the first diversion outlet is communicated with the first swing inlet; when the water distribution disc is uncovered on the second water distribution outlet, the second water distribution outlet is communicated with the second swing inlet.

5. The showerhead of claim 1 wherein the housing assembly further has a water diversion chamber in communication with the diversion inlet, a diversion inlet in communication with the second water outlet, and a diversion outlet in communication with the water inlet when the second valve is open;

The shower head further includes:

the impeller is rotationally connected with the shell component and is arranged in the water distribution cavity, and the central axis of the diversion inlet is arranged along the tangential direction of the impeller so that water entering the water distribution cavity from the diversion inlet can push the impeller to rotate;

and the water distribution disc is connected with the impeller and arranged in the water distribution cavity, when the impeller rotates, the water distribution disc periodically covers the water distribution outlet, and when the water distribution disc releases the cover of the water distribution outlet, the water distribution outlet is communicated with the second water outlet.

6. The shower head according to claim 4 or 5, wherein a wall surface of the water distribution cavity is provided with first deceleration teeth, the first deceleration teeth are distributed around a central axis of the impeller, the water distribution disc is eccentrically connected with the impeller, the periphery of the water distribution disc is provided with second deceleration teeth, the second deceleration teeth are meshed with the first deceleration teeth, and the number of the second deceleration teeth is smaller than that of the first deceleration teeth.

7. A shower apparatus, comprising:

the showerhead of any one of claims 1 to 6;

the remote controller is connected with the shower head in a wireless communication mode, and can send signals to the control panel, so that the first valve is opened and closed, and the second valve is opened and closed.

8. The shower device of claim 7, further comprising a wireless charger having a wireless charging transmit coil, the remote control having a second wireless charging coil;

when the wireless charger is placed on the shower or the shower is placed on the wireless charger, the wireless charging transmitting coil is magnetically coupled with the first wireless charging coil; when the wireless charger is placed on the remote controller or the remote controller is placed on the wireless charger, the wireless charging transmitting coil is magnetically coupled with the second wireless charging coil.

9. A shower apparatus, comprising:

the showerhead of any one of claims 1 to 6;

the wireless charger is provided with a wireless charging transmitting coil, and when the wireless charger is placed on the shower or the shower is placed on the wireless charger, the wireless charging transmitting coil is magnetically coupled with the first wireless charging coil.

10. The shower apparatus of claim 9, wherein the outer surface of the housing assembly includes an upwardly disposed mounting surface, the mounting surface being a horizontal surface, the wireless charging transmitter coil being magnetically coupled with the first wireless charging coil when the wireless charger is mounted on the mounting surface.