CN217214518U - Wireless controller, wireless control equipment and hot water system - Google Patents

Abstract

The utility model discloses a wireless controller, wireless control equipment and hot water system. Wherein, this wireless controller includes: the device comprises a shell, a communication module, a sealing part and at least one control part; the shell is provided with a control position; the communication module is arranged in the shell; the control part is matched with the control position and is suitable for being applied with a driving force to trigger the communication module to send out a control signal; the sealing part is coupled with the at least one control part, at least part of the sealing part is arranged in the shell, and a sealing cavity is formed by the sealing part and at least part of the shell; the communication module is arranged in the sealing cavity. The control part and the sealing part are coupled to form an integral structure, so that the waterproof effect is better, the sealing part cannot be abraded, and the problem that a waterproof layer in the existing waterproof switch is not durable is solved.

Description

Wireless controller, wireless control equipment and hot water system

Technical Field

The utility model relates to a wireless controller, wireless control equipment and hot-water heating system.

Background

Be equipped with waterproof construction among the present waterproof wireless controller, through with the circuit board, the subassembly or the device of communication module (including detection switch) etc. can not contact water sets up and realizes that equipment is waterproof in waterproof construction, waterproof construction of waterproof wireless controller includes waterproof body usually, set up one deck waterproof layer (waterproof membrane such as silica gel) usually in the waterproof body, and then form a sealed waterproof chamber between the casing of waterproof body and waterproof layer, then will be with the circuit board, the subassembly or the device of communication module etc. can not contact water sets up in waterproof chamber, waterproof wireless controller's button triggers the communication module through separating the waterproof layer.

SUMMERY OF THE UTILITY MODEL

In view of technical defect and the technical drawback that exist among the prior art, the embodiment of the utility model provides a wireless controller, wireless control equipment and hot-water heating system.

As an aspect of the embodiment of the present invention, a wireless controller is provided, which includes: the device comprises a shell, a communication module, a sealing part and at least one control part;

the shell is provided with a control position;

the communication module is arranged in the shell;

the control part is matched with the control position and is suitable for being applied with a driving force to trigger the communication assembly to send out a control signal;

the sealing part is coupled with the at least one control part, at least part of the sealing part is arranged in the shell, and a sealing cavity is formed by the sealing part and at least part of the shell;

the communication module is arranged in the sealing cavity.

As a second aspect of the embodiments of the present invention, there is provided a wireless control device, including an actuator and the wireless controller according to any one of the above embodiments; the wireless controller can transmit wireless control signals in the working state, and the actuator can receive the wireless control signals transmitted by the wireless controller in the working state.

As a third aspect of the embodiments of the present invention, a hot water system is related to, comprising the wireless controller according to any one of the above items and a water heater communicatively connected to the wireless controller; the wireless controller can emit wireless control signals under the working state, and the water heater can receive the wireless control signals emitted by the wireless controller.

As a fourth aspect of the embodiments of the present invention, a power generation device is related to, including: the self-generating motor and the driving reset unit;

the self-generating motor comprises a driving assembly;

the driving reset unit is arranged to be capable of being applied with a manipulated driving force to switch between a first position and a second position;

the drive reset unit comprises a drive part and a reset part;

the driving part comprises a first pressing part and a second pressing part, and the first pressing part and the second pressing part form a step structure; wherein:

when the driving part is at the first position: a preset gap is formed between the first pressing part and the driving assembly; the second pressing part is abutted with the reset part;

when the driving part is at the second position: the driving assembly stores mechanical energy under the driving force of the first pressing part and triggers the self-generating motor to output electric energy; the reset part stores mechanical energy under the driving force of the second pressing part so as to drive the driving part to rebound and reset to the first position after the driving force is released.

The embodiment of the utility model provides a following technological effect has been realized at least:

the embodiment of the utility model provides an above-mentioned wireless controller, because control portion and sealing coupling are for overall structure, make water-proof effects better, be different from the structural style that the button separates the waterproof layer and triggers detection switch among the prior art, through direct partly as waterproof seal structure with control portion, can directly trigger communication module and send and predetermine control signal under the drive power effect, can not cause wearing and tearing to the sealing, the problem of the waterproof layer intolerance among the current waterproof switch has been solved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and examples.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is an exploded view of a wireless controller in an embodiment of the invention;

FIG. 2 is a block diagram of a waterproof assembly in an embodiment of the present invention;

fig. 3 is a partial cross-sectional view of a wireless controller in an embodiment of the invention;

FIG. 4 is a view showing a structure of a waterproof part in an embodiment of the present invention;

FIG. 5 is a view showing a structure of a supporting portion of the lower case according to the embodiment of the present invention;

fig. 6 is a structural diagram of a self-generating motor in the embodiment of the present invention;

FIG. 7 is a structural view of a driving part in the embodiment of the present invention;

fig. 8 is a partially enlarged view of the driving portion in the embodiment of the present invention;

fig. 9 is a structural diagram of a self-generating motor in the embodiment of the present invention;

fig. 10 is an internal structure diagram of a wireless controller according to an embodiment of the present invention;

fig. 11 is a cross-sectional view of a wireless controller in an embodiment of the invention;

fig. 12 is an assembly relationship diagram of the reset portion, the connecting arm and the elastic spring in the embodiment of the present invention;

fig. 13 is a system block diagram of a water heater control system in an embodiment of the present invention;

fig. 14 is a circuit block diagram of the intelligent faucet according to the embodiment of the present invention;

fig. 15 is a flowchart of the processing procedure of the intelligent faucet according to the embodiment of the present invention;

FIG. 16 is a flow chart illustrating the control of a water heater according to an embodiment of the present invention;

fig. 17 is a schematic structural diagram of a control mechanism of a faucet valve body according to an embodiment of the present invention;

FIG. 18 is a cross-sectional schematic view of the control mechanism of the faucet valve body shown in FIG. 17;

FIGS. 19A and 19B are schematic views illustrating the construction of the middle cap of the control mechanism of the faucet valve body shown in FIG. 17;

FIG. 20 is a structural schematic view of the lower housing of the control mechanism of the faucet valve body illustrated in FIG. 17;

FIG. 21 is a schematic structural view of a base of the control mechanism of the faucet valve body shown in FIG. 17;

FIG. 22 is a schematic view of a communication assembly of the control mechanism of the faucet valve body shown in FIG. 17;

fig. 23 is a structural diagram of a self-generating motor of a control mechanism of a faucet valve body in an embodiment of the present invention;

fig. 24 is a schematic cross-sectional view of another faucet valve body control mechanism provided in an embodiment of the present invention;

FIG. 25 is a schematic view of the internal structure of the control mechanism of the faucet valve body shown in FIG. 24;

FIG. 26 is a schematic view of the construction of the paddle of the control mechanism of the faucet valve body shown in FIG. 24;

FIG. 27 is a schematic top view, partially in section, of the control mechanism of the faucet valve body illustrated in FIG. 24;

FIG. 28 is a schematic view of the assembly of the base and mixing valve of the control mechanism of the faucet valve body of FIG. 24;

fig. 29 is a schematic cross-sectional view of a control mechanism of a faucet valve body according to an embodiment of the present invention;

FIG. 30 is a schematic view of the internal structure of the control mechanism of the faucet valve body shown in FIG. 29;

FIG. 31 is a schematic top view, partially in section, of the control mechanism of the faucet valve body shown in FIG. 30;

fig. 32 is a schematic structural diagram of a control mechanism of a faucet valve body according to an embodiment of the present invention;

FIG. 33 is a cross-sectional schematic view of the control mechanism of the faucet valve body shown in FIG. 32;

FIG. 34 is a schematic view of the internal structure of the control mechanism of the faucet valve body shown in FIG. 32;

FIG. 35 is a schematic view of the drive support mechanism of the control mechanism of the faucet valve body shown in FIG. 32;

FIG. 36 is a schematic view of a communication assembly of the control mechanism of the faucet valve body shown in FIG. 32;

FIG. 37 is a schematic view of the self-generating unit of the control mechanism of the faucet valve body shown in FIG. 32;

fig. 38 is a schematic structural view of another control mechanism of a faucet valve body according to an embodiment of the present invention;

FIG. 39 is a cross-sectional schematic view of the control mechanism of the faucet valve body illustrated in FIG. 38;

FIG. 40 is a schematic view of the internal structure of the control mechanism of the faucet valve body shown in FIG. 38;

FIG. 41 is a schematic view of the drive support mechanism of the control mechanism of the faucet valve body shown in FIG. 38;

fig. 42 is a schematic structural diagram of a control mechanism of a faucet valve body according to another embodiment of the present invention;

FIG. 43 is a cross-sectional schematic view of the control mechanism of the faucet valve body shown in FIG. 42;

FIG. 44 is a schematic view of the internal structure of the control mechanism of the faucet valve body shown in FIG. 42;

FIG. 45 is a schematic view of the assembly of the drive support mechanism and mixing valve of the control mechanism of the faucet valve body shown in FIG. 42;

fig. 46 is a schematic structural diagram of a control mechanism of a faucet valve body according to another embodiment of the present invention;

FIG. 47 is a cross-sectional schematic view of the control mechanism of the faucet valve body shown in FIG. 46;

fig. 48 is a top view, partially in elevation, of the control mechanism of the faucet valve body of fig. 46.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The implementations described in the following exemplary embodiments do not represent all implementations consistent with the present invention. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the invention, as detailed in the appended claims.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The inventor of the utility model finds that, waterproof wireless controller among the prior art is owing to realize that waterproof layer generally is the flexible material preparation, is triggering the detection switch in-process through the button is repeated, and the waterproof layer is worn and torn very easily after being extrudeed many times between detection switch and button to lose water-proof effects. In order to at least partially solve the technical problem of the prior art that the waterproof layer is not durable, the inventor has made the present invention, and provides a new wireless controller through specific embodiments.

Referring to fig. 1, the present invention provides an embodiment of a wireless controller, including:

the device comprises a shell 1, wherein a control position 111 is arranged on the shell 1;

a communication module 3 disposed in the housing 1;

at least one control part 22, wherein the control part 22 is matched with the control position 111 and is configured to be applied with a driving force to trigger the communication module 3 to send out a control signal;

a sealing part 21, wherein the sealing part 21 is coupled with the at least one manipulation part 22, at least a part of the sealing part 21 is disposed in the housing 1, and forms a sealed cavity 4 with at least a partial region of the housing 1; the communication module 3 is arranged in the sealed cavity 4.

In the embodiment of the present invention, the housing 1 includes an upper shell 11 and a lower shell 12, the upper shell 11 and the lower shell 12 enclose a containing cavity. At least part of the sealing part 22 is arranged in the accommodating cavity and forms the sealing cavity 4 with at least part of the area of the lower shell 12. In the embodiment of the present invention, the upper shell 11 and the lower shell 12 of the housing 1 can be connected in a detachable manner, for example, assembled by means of a buckle, a screw, etc. Of course, the upper shell 11 and the lower shell 12 can also be connected in a non-detachable manner, for example, assembled by ultrasonic or the like; as shown in fig. 3, the sealing portion 22 is fixed between the upper shell 11 and the lower shell 12 in a pressing manner, so that a receiving cavity is formed between the sealing portion 22 and the lower shell 12; the upper shell 11 is provided with the control position 111, and at least a part of the control part 22 is accommodated in the control position 111.

In the embodiment of the present invention, the operation position 111 can be understood as a through hole penetrating the upper case 11 in any shape, the size of the through hole is adapted to the shape of the manipulation part 22, the manipulation part 22 is at least partially arranged to protrude from the manipulation position 111, so that the manipulation part 22 can be pressed up and down in the manipulation position 111 without being restricted, in a specific example, referring to fig. 2, the operation portion 22 is configured as a kidney-shaped cylinder key, and the material of the operation portion 22 may be selected from silicone, namely, the control part 22 is a silicone key, which is accommodated in the control position 111, and at least part of the operation part 22 is exposed out of the upper surface of the upper shell 11, so as to operate the silica gel key from the outside, of course, the manipulation part 22 may be provided in a cylindrical shape, a cubic column shape, or other shapes, which is not particularly limited herein. If the operation portion 22 is configured as a silicone key, the above-mentioned situation that the operation portion 22 is displaced from the upper shell 11 to the sealed cavity 4 is that the silicone key moves toward the sealed cavity 4 under the downward pressing force. And the silica gel key can rebound to the initial position when releasing the downward pressing force.

The embodiment of the present invention provides an in, sealing portion 21 and control portion 22 can be integrated into one piece or sealing connection to form this elastic sealing element 2, wherein, the embodiment of the present invention provides an integrated into one piece that can understand the same kind of material and/or the double-shot moulding of different materials for the integrated into one piece that describes.

The embodiment of the utility model provides an above-mentioned wireless controller, because the control portion 22 and the sealing 21 of elastic sealing element 2 are connected for a whole, make water-proof effects better, be different from the structural style that the button is separating the waterproof layer and is triggering detection switch 32 among the prior art, through directly with control portion 22 as waterproof seal structure's partly, can directly trigger communication module 3 under the driving force effect and send and predetermine control signal, can not cause wearing and tearing to elastic sealing element 2, the problem of waterproof layer intolerance in the current waterproof switch has been solved.

In some alternative embodiments, it may be that, as shown with reference to fig. 2, the elastic sealing member 2 further comprises at least one buffer connection 23; the sealing part 21 is connected with the control part 22 through the buffer connecting part 23;

the buffer connection 23 is configured to be deformable with displacement of the manipulation part 22, so that the manipulation part is telescopically disposed in the manipulation position. And so that the displacement of the manipulation part 22 is not interfered with by the sealing part 21. The embodiment of the utility model provides an in, this buffering connecting portion 23 has elasticity to when control portion 22 is exerted pressure effect and is produced the displacement, elastic deformation takes place for buffering connecting portion 23, thereby guarantees that control portion 22 can not be interfered by sealing 21 when taking place the displacement, and sealing 21 can not produce great deformation because of control portion 22's displacement yet.

In a specific embodiment, the sealing portion 21, the buffer connecting portion 23 and the manipulation portion 22 of the elastic sealing member 2 are integrally formed. Of course, the buffer connection portion 23 may be hermetically connected to the sealing portion 21 and the manipulation portion 22, respectively.

In the embodiment of the present invention, if the operation portion 22 is implemented as a silicone key, the sealing portion 21 can be implemented as a silicone sleeve, the buffer connecting portion 23 can be configured as an annular silicone membrane, a key hole is formed at a position of the silicone sleeve corresponding to the operation position 111, a circumference of the key hole passes through the annular silicone membrane and is connected to a circumference of the end portion of the silicone key, so that the silicone key is connected to the silicone sleeve to form a waterproof integral structure, and the thickness of the annular silicone membrane is smaller than that of the silicone sleeve, so that the annular silicone membrane has a certain elasticity, and further, when the silicone key is pressed downwards or rebounded upwards, the silicone key cannot be interfered by the silicone sleeve due to the buffer effect of the annular silicone membrane, thereby reducing the resistance of the silicone key pressed downwards, and making the pressing feel smoother, and the user experience degree is improved.

The embodiment of the utility model provides an in, because control portion 22 with the coupling of sealing part 21 is overall structure for water-proof effects is better, directly sets up the button into the silica gel button, has solved the problem that the waterproof layer is not durable in current waterproof switch. In addition, in this scheme, be provided with between control portion 22 and the sealing 21 and be used for buffering buffer connection portion 23 of transition for control portion 22 is smooth and easy degree when the action promotes greatly when promoting waterproof performance.

As a specific implementation manner of the embodiment of the present invention, referring to fig. 2, the elastic sealing element 2 further includes a waterproof portion 211, and correspondingly, referring to fig. 3, the edge of the lower shell 12 is provided with a first pressing portion 121 matched with the waterproof portion 211; the waterproof portion 211 is disposed around the sealing portion 21;

when the upper shell 11 and the lower shell 12 are assembled into a whole, the waterproof part 211 is attached to the first pressing part 121, and the waterproof part 211 is fixed between the upper shell 11 and the first pressing part 121 in a pressing manner.

In the embodiment of the present invention, the waterproof portion 211 and the sealing portion 21 are integrally formed, and specifically, the waterproof portion 211 may be formed by extending the sealing portion 21 outwards; alternatively, the waterproof portion 211 is hermetically connected to the sealing portion 21, and the waterproof portion 211 and the sealing portion 21 are sealed by a fixed connection.

In one embodiment, referring to fig. 4, the waterproof portion 211 includes an abutting edge 2111 connected to the edge of the sealing portion 21, and an attaching edge 2112 perpendicular to the abutting edge and extending toward the lower case 12;

the pressing eaves 2111 are pressed between the upper shell 11 and the first pressing portion 121 to achieve a waterproof effect, and the attaching eaves 2112 are attached to the outer surface of the first pressing portion 121 to further improve the waterproof performance.

In a specific embodiment, a gap between the upper shell 11 and the first pressing portion 121 may be less than or equal to a thickness of the pressing eaves 2111. For example, a preset gap may be formed between the end of the first pressing portion 121 far from the lower shell 12 and the upper shell 11, the width of the preset gap is 0.5mm, and the thickness of the pressing ledge 2111 is 0.7mm, so that an interference fit interference amount of 0.2mm is formed here, so that when the upper shell 11 and the lower shell 12 are assembled into a whole, the waterproof portion 211 can be firmly pressed between the upper shell 11 and the lower shell 12, and a good waterproof effect is achieved. Of course, the sealing portion 21 and the lower shell 12 may be hermetically connected by other means such as adhesion, and is not limited to the manner proposed in the present embodiment.

It can be seen that, in the above scheme, because of the cooperation between the first pressing portion 121 of the lower shell 12 and the waterproof portion 211 of the sealing portion 21, a sealed and waterproof accommodating cavity can be formed between the lower shell 12 and the sealing portion 21, and the waterproof performance of the waterproof cavity is greatly improved through the interference design of the pressing eaves 2111 and the attachment design between the attachment eaves 2112 and the first pressing portion 121.

The embodiment of the utility model provides a wireless controller, it is shown with reference to figure 1, can also include: the power generation module 5 is arranged in the sealed cavity 4;

the manipulation unit 22 is further configured to control the power generation module 5 to supply power to the communication module 3 when a driving force is applied to displace the housing chamber from the housing chamber to the sealed chamber 4.

In the embodiment of the present invention, the power generation module 5 is electrically connected to the communication module 3 for supplying power to the communication module 3.

As a specific implementation manner of the embodiment of the present invention, referring to fig. 1, the communication module 3 includes at least one signal unit 31 and at least one detection switch 32;

the signal unit 31 is electrically connected to the power generation module 5 and the detection switch 32 respectively;

the control part 22 responds to the driving force and controls the detection switch 32 to switch on and off states to generate a detection signal;

the signal unit 31 is configured to generate and externally transmit a preset control signal according to the detection signal.

In the embodiment of the present invention, the signal unit 31 may include necessary devices such as a controller, a wireless transmitter, an antenna, and the like, in one example, the controller employs a single chip, and the wireless transmitter employs a bluetooth module; after the single chip microcomputer is powered on by the power generation module 5, the trigger state of the detection switch 32 is detected, and when the detection switch 32 is triggered, the corresponding detection signal is received, the controlled control part 22 is judged according to the detection signal, a corresponding control message is generated according to the unique ID number corresponding to the controlled control part 22 and a preset protocol, and finally the control message is sent out. Of course, those skilled in the art can reasonably modify the controller and the wireless transmitter of the signal unit 31 and other peripheral circuits according to the requirement, and as long as they depend on the technical principle provided by the embodiment, they should not depart from the protection scope of the present invention.

As a specific implementation manner of the embodiment of the present invention, referring to fig. 1, fig. 3 and fig. 5, the communication module 3 includes at least two detection switches 32, and the elastic sealing member 2 includes at least two operation portions 22 arranged at intervals; at least one supporting portion 122 is disposed on the lower shell 12, the supporting portion 122 is disposed between two adjacent detection switches 32, and an upper end of the supporting portion 122 abuts against a connection portion of two adjacent control portions 22. Therefore, when any one of the manipulating parts 22 is displaced by a downward pressing force, the other manipulating parts 22 are supported by the supporting part 122 and are kept as they are.

In one embodiment, referring to fig. 11, the upper shell 11 is provided with a second pressing portion 112 corresponding to the position of the supporting portion 122; the gap between the second pressing part 112 and the supporting part 122 is less than or equal to the thickness of the sealing part 21. So that the area of the sealing portion 21 at the joint of two adjacent operating portions 22 is tightly pressed by the second pressing portion 112 and the supporting portion 122, where the pressing of the sealing portion 21 between the second pressing portion 112 and the supporting portion 122 can also be understood as an interference fit.

As another specific implementation manner of the embodiment of the present invention, referring to fig. 11, the communication module 3 includes at least two detection switches 32, the elastic sealing element 2 includes at least two operation portions 22 disposed at intervals, and an elastic support element (not shown in the figure) may be disposed between the operation portion 22 of the elastic sealing element 2 and the corresponding detection switch 32. The operation parts 22 are supported by elastic supporting members, so that when any one of the operation parts 22 is displaced by a downward pressing force, the other operation parts 22 are supported by the elastic supporting members and are kept as they are.

In the embodiment of the present invention, the elastic supporting member can adopt an elastic member in the prior art, and the specific implementation manner of the elastic supporting member to support the operation portion 22 can refer to the description in the prior art, which is not specifically limited herein. The elastic support member is, for example, a spring, and the operation unit 22 is supported by fitting the spring to the detection switch 32. One end of the spring is sleeved on the detection switch 32, the other end of the spring is abutted against the control part 22, when the control part 22 is pressed downwards, the spring is compressed downwards, so that the control part 22 can trigger the detection switch 32, other control parts 22 which are not pressed can be kept in an original state due to the support of the corresponding spring, the problem of downward collapse cannot occur, and when the external pressing control is removed, the pressed control part 22 moves upwards to an initial state under the elastic restoring force of the spring. In the embodiment of the present invention, the trigger detection switch 32 may be understood as a state change of the detection switch 32, such as a switch from an on state to an off state, or a switch from an off state to an on state. Of course, other types of switches such as hall switches and piezoelectric switches may be used for the detection switch 32, and the type of state switching should be changed accordingly, and in general, as long as the detection state of the detection switch 32 itself is changed, it should be understood that the state switching is triggered. In the above solution, the spring can provide a supporting force to keep the operation part 22 as it is when not pressed, and can provide an upward elastic force when the operation part 22 is pressed and then the pressing force is removed, so as to achieve two purposes.

In the embodiment of the present invention, the detection switch 32 can be disposed under the control part 22, and is set to be suitable for switching the on/off state in response to the pressing action of the control part 22, and then generates a detection signal. For example, as shown in fig. 2, the manipulation unit 22 may include a detection switch accommodation groove 222, and the detection switch 32 may be accommodated in the detection switch accommodation groove 222.

In one embodiment, the detection switch 32 may be disposed with a predetermined gap from the inner wall of the detection switch receiving groove 222. Therefore, when any one of the operation parts 22 is displaced by a downward pressing force, even if the other operation parts 22 are slightly deformed or displaced, the corresponding detection switch 32 is not touched by mistake.

In one embodiment, the power generation module 5 includes a self-generating motor 51 with reference to fig. 1; a motor mounting part is arranged in the lower shell 12; the self-generating motor 51 is mounted on the motor mounting portion; the manipulation part 22 generates displacement in response to the driving force and exerts a pressure action on the self-generating motor 51; the self-generating motor 51 is configured to convert mechanical energy into electric energy in response to a pressure action.

In the embodiment of the present invention, the self-generating motor 51 is set to be capable of converting mechanical energy into electric energy at least once in response to the pressure action is triggered, so as to supply energy to the signal unit 31. The self-generating motor 51 includes an electromagnetic induction generator, a piezoelectric ceramic generator, or other generator that converts mechanical energy into electrical energy. The self-generating motor 51 further includes a general peripheral circuit such as a rectifying module (e.g., a rectifying bridge), a voltage converting module (e.g., DC-DC), etc. for converting the electric energy generated by the self-generating motor 51 into electric energy capable of supplying power to the signal unit 31.

Of course, in other embodiments, the power generation module 5 may also use a battery; the inside of lower casing 12 is provided with the battery installation department, the battery install in the battery installation department. The battery is understood to be a button battery and the like which are suitable for batteries in narrow spaces. The utility model discloses can not restrict the concrete power supply form of waterproof wireless controller's power module 5.

As a specific implementation manner of the embodiment of the present invention, referring to fig. 1, the power generation module 5 further includes at least one driving reset unit 52;

the manipulation part 22 applies the pressing action to the drive returning unit 52 in response to the driving force;

the driving reset unit 52 is configured to drive the self-generating motor 51 to supply power to the signal unit 31 in response to the pressing action.

In one embodiment, referring to fig. 1, the driving reset unit 52 includes a driving part 521 and a reset part 522; the driving part 521 is configured to be switched from a first position to a second position in response to the pressure action to drive the self-generating motor 51 to supply power to the signal unit 31; the reset portion 522 is configured to abut against the driving portion 521 when the driving portion 521 is in the first position, and to bring the driving portion 521 to rebound and reset to the first position after the driving portion 521 is released from the pressure action when the driving portion 521 is in the second position in response to the pressure action.

In the embodiment of the present invention, referring to fig. 1, the operation portion 22, the driving portion 521 and the reset portion 522 may be sequentially arranged from a designated direction; the driving part 521 can drive the self-generating motor 51 to generate electric energy in response to the pressure action generated by the displacement of the manipulation part 22, and the reset part 522 is used for providing an upward reset elastic force for the driving part 521; wherein the driving part 521 is provided to be switchable from a first position to a second position in response to a pressure action of the manipulation part 22; when the driving part 521 is located at the second position, the self-generating motor 51 is triggered to generate electric energy; the reset portion 522 is configured to abut against the driving portion 521 when the driving portion 521 is in the first position, and when the driving portion 521 moves from the first position to the second position, energy storage is completed under the action of pressure, so that when the pressure is released, elastic potential energy is released to drive the driving portion 521 to rebound and reset to the first position. The above-mentioned designated direction may be a top-down designated direction as shown by the arrow in fig. 1.

In one embodiment, referring to fig. 1-10, the actuation portion 521 is pivotally connected to the lower shell 12; the control unit 22 further includes a driving pressing unit 221, and the driving pressing unit 221 contacts with the driving unit 521;

when a downward pressing force is applied to the manipulating part 22, the manipulating part 22 responds to the driving force, so that the driving pressing part 221 applies a pressing force to the driving part 521, and the driving part 521 is driven to perform a pivoting motion to switch from the first position to the second position. Specifically, as shown in fig. 7, the driving portion 521 may include two driving arms 5211 and a connecting arm 5212 connecting the two driving arms 5211; the two driving arms 5211 are connected at one end thereof by the connecting arm 5212 and at the other end thereof are pivotally connected to the lower case 12. Specifically, referring to fig. 6, a rotating shaft 123 is disposed in the lower shell 12, a rotating hole 52111 is disposed on the driving arm 5211, and the rotating shaft 123 is inserted in the rotating hole 52111 to realize the pivotal connection between the driving part 521 and the lower shell 12; the detection switch 32 is disposed on a side of the connection arm 5212 opposite to the driving arm 5211, so that the detection switch 32 can be triggered when the manipulation part 22 is displaced, and the connection arm 5212 can be driven to drive the driving part 521 to move from the first position to the second position.

In a specific example, the reset portion 522 is configured as a torsion spring, and the torsion spring may be a single torsion spring or a double torsion spring; referring to fig. 6 and 8, a torsion spring mounting structure 124 is provided inside the lower case 12; the connecting arm 5212 is provided with a first pressing portion 52121 and a second pressing portion 52122; the first pressing portion 52121 is used to drive the self-generating motor 51 to supply energy to the signal unit 31, and the second pressing portion 52122 is used to press the torsion spring. Specifically, the self-generating motor 51 may include a driving assembly; the first pressing portion 52121 and the second pressing portion 52122 form a step structure, when the driving portion 521 is at the first position, the second pressing portion 52122 abuts against the torsion spring, and a preset gap is formed between the first pressing portion 52121 and the driving assembly; when the driving part 521 is at the second position, the torsion spring is compressed to store mechanical energy, and the driving assembly is stressed to store mechanical energy and trigger the self-generating motor 51 to output electric energy. Referring to fig. 8, the second pressing portion 52122 is a lower step relative to the first pressing portion 52121, so that when the driving portion 52 moves from the first position to the second position, the self-generating motor 51 is driven by the first pressing portion 52121 to generate power after the torsion spring is pressed down by the second pressing portion 52122 for a certain distance (see fig. 12).

Referring to fig. 9 and 12, in one embodiment, the electromagnetic induction generator 51 includes a coil assembly 512, a drive assembly 513, and a magnet assembly 514 movable relative to the coil assembly 512; the driving assembly 513 includes a resilient spring 5133, the coil assembly 512 is disposed on one side of the magnet assembly 514, and the resilient spring 5133 is disposed on the side opposite to the coil assembly 512; when the electromagnetic induction generator 51 is installed in the accommodating cavity, the position of the elastic spring piece 5133 is matched with the position of the first pressing part 52121, so that when the connecting arm 5212 is at the first position, the second pressing part 52122 is in vertical contact with the torsion spring, and the first pressing part 52121 is not in contact with the elastic spring piece 5133; when the connecting arm 5212 is in the second position, the spring reed 5133 is compressed to store the maximum mechanical energy, thereby restoring the deformation and driving the magnet assembly 514 to displace relative to the coil assembly 512, thereby changing the magnetic flux in the coil assembly 512 to generate an induced current. When the manipulation part 22 moves downwards, the connecting arm 5212 is pushed to move downwards, so that the second pressing part 52122 presses the torsion spring downwards first, and after the torsion spring and the elastic reed 5133 are separated by a certain distance, the first pressing part 52121 starts to press the elastic reed 5133, so that the elastic reed 5133 cannot be affected by the resistance of the torsion spring when being pressed downwards, when the manipulation part 22 moves downwards to a certain extent, the connecting arm 5212 is pressed downwards to a second position, and at this time, the elastic reed 5133 is compressed to a limit state, so that the elastic reed 5133 restores to deform downwards, and drives the magnet assembly 514 to move downwards relative to the coil assembly 512 instantaneously.

For further example, referring to fig. 9, the electromagnetic induction generator 51 mentioned above may be, for example, the generator 51 shown in fig. 9, which is a stand-alone integral module comprising: a magnetically conductive assembly 511, a coil assembly 512, a magnet assembly 514, and a drive assembly 513. The magnetically conductive assembly 511, the coil assembly 512, the magnet assembly 514, and the drive assembly 513 are integrally connected to one another.

The magnetic conduction assembly 511 includes a first magnetic conduction member 5111 and a second magnetic conduction member 5112, and the first magnetic conduction member 5111 is opposite to the second magnetic conduction member 5112. One end of the first magnetic conductive member 5111 is fixedly connected to one end of the second magnetic conductive member 5112 through a connecting member 5113, and an upper contact member 5114 and a lower contact member 5115 are respectively arranged above and below the other end of the first magnetic conductive member 5111.

The coil assembly 512 is disposed inside the magnetic conductive assembly 51, and the coil assembly 512 includes: a fixed structure 5123, a magnetic core 5122, a bobbin 5124 and a coil 5121 surrounding said bobbin 5124; the bobbin 5124 is hollow, and the coil 5121 is wound on the bobbin 5124; after the magnetic core 5122 passes through the bobbin 5124, one end of the magnetic core is fixedly connected to the connecting member 5113, and the other end of the magnetic core passes through the bobbin 5124 and is inserted into the fixing structure 5123 and extends out of the fixing structure 5123 to be placed between the upper contact and the lower contact to form a middle contact. The fixing structure 5123 is used to fix the other ends of the bobbin 5124 and the magnetic core 5122, and the coil 5121 can be electrically connected to the signal unit 32.

Drive assembly 513, it includes the axis of rotation 5131 of two relative settings, and the one end of two axis of rotation 5131 is passed through the mounting bracket 5132 and is connected, and the other end is provided with rotation portion respectively, first magnetic conduction piece 5111 with being close to of second magnetic conduction piece 5112 the one end of connecting piece 5113 is provided with rotation hole 52111 respectively, rotation hole 52111 with rotation portion suits, and two axis of rotation 5131 pass through the rotatable connection of rotation portion is in on the magnetic conduction subassembly 511. One side of the mounting frame 5132, which is away from the coil 5121, is provided with an elastic spring 5133, pressing the elastic spring 5133 can drive the entire driving assembly 513 to displace up and down, and the position of one end of the elastic spring 5133, which is away from the coil assembly 512, is matched with the first pressing portion 52121.

The magnet assembly 514 is disposed on the driving assembly 513, and the magnet assembly 514 includes: the magnet 5141, the first magnetic conductive plate 5142 and the second magnetic conductive plate 5143, wherein the magnet 5141 is disposed in an installation groove formed inside the installation frame 5132, and the first magnetic conductive plate 5142 and the second magnetic conductive plate 5143 are disposed at two ends of the magnet 5141, which have different polarities, oppositely; the driving component 513 is configured to drive the magnet component 514 to relatively displace with respect to the magnetic conductive component 511, so as to generate inductive power.

It can be seen that, in the above scheme, the connecting arm 5212 adopts the design of two splenium of pressing, makes elasticity reed and torsional spring are pressed according to the order of predetermineeing, guarantee can not by when the elasticity reed takes place elastic deformation downwards the restoring force of torsional spring hinders, thereby drives the instantaneous displacement is accomplished to the magnet subassembly, great improvement displacement speed, improved the change speed of magnetic flux promptly for the generated energy is promoted.

In one embodiment, referring to fig. 7 and 8, in the case that the manipulation part 22 is supported by a support part 122 in the wireless controller, a support part avoiding groove 52123 may be further formed on the connection arm 5212, and the position of the support part avoiding groove 52123 corresponds to the support part 122 so as to prevent the connection arm 5212 from being blocked by the support part 122 when pressed downward. Of course, in the embodiment of the present invention, when the spring is used to support the operation portion 22 in the wireless controller, the support portion is not required to be provided on the connecting arm 5212 to avoid the groove 52123 when the operation portion 22 is used to support.

In an embodiment, when the manipulation unit 22 of the wireless controller is provided with the detection switch accommodation groove 222, the connection arm 5212 is further provided with at least one detection switch escape unit 52124, and the detection switch 32 penetrates the detection switch escape unit 52124 to be accommodated in the detection switch accommodation groove 222, so that the detection switch 32 can be triggered when the manipulation unit 22 operates.

In a specific example, as shown in fig. 7, the detection switch avoiding portion 52124 can be provided as a kidney-round hole that penetrates through the connecting arm 5212; in another specific example, the detection switch avoidance portion 52124 is provided as a circular or semi-circular hole that penetrates through the connection arm 5212; of course, the above-described embodiment of the detection switch avoiding portion 52124 is merely an example, and is not intended to limit the present invention.

In one embodiment, as shown in fig. 6 and 10, the lower case 12 is provided with at least one mounting hole 125; the mounting hole 125 is adapted to receive a magnetic element 6 and/or a threaded connector (not shown); the wireless controller further comprises at least one magnetic element 6, when the magnetic element 6 is assembled in the mounting hole 125, the lower shell 12 can be fixed outwards through the magnetic attraction force generated by the magnetic element 6; when the screw is fitted into the mounting hole 125, the lower case 12 can be fixed to the outside by the screw. The magnetic member 6 or the screw connector is selectively fitted to the mounting hole 125. The magnetic element 6 can be understood as any device capable of generating a magnetic attraction force, such as a magnet; the threaded connection is understood to mean a fastening device in which screws, expansion screws or the like are screwed to one another.

In the above scheme, two selectable connection modes of the magnetic part 6 and the threaded connection part are adopted, so that a user can select a proper installation mode according to requirements, for example, the expected installation reference of the user is inconvenient to punch, and then the connection mode of the magnetic part 6 can be selected, so that the installation of the shell 1 is more convenient.

Based on same utility model the design, the utility model discloses still provide a power generation facility's embodiment, this power generation facility includes: a self-generating motor 51 and a drive reset unit 52;

the self-generating motor 51 comprises a driving assembly;

the drive resetting unit 52 is provided to be capable of being applied with a manipulated driving force to switch between a first position and a second position;

the driving reset unit 52 includes a driving part 521 and a reset part 522;

the driving part 521 includes a first pressing part 52121 and a second pressing part 52122, and the first pressing part 52121 and the second pressing part 52122 form a step structure; wherein:

when the driving part 521 is at the first position: a preset gap is formed between the first pressing portion 52121 and the driving assembly; the second pressing portion 52122 abuts against the reset portion 522;

when the driving part 521 is in the second position: the driving assembly stores mechanical energy under the driving force of the first pressing part 52121 and triggers the self-generating motor 51 to output electric energy; the reset part 522 stores mechanical energy under the driving force of the second pressing part 52122 to bring the driving part 521 to rebound and reset to the first position after releasing the driving force.

The embodiment of the utility model provides a from the detailed description of the specific implementation mode of generating motor 51 and drive reset unit 52 among the power generation facility that provides can refer to in the wireless controller that above-mentioned embodiment provided, no longer describe herein.

Based on the same utility model concept, the utility model also provides an embodiment of a wireless control device, which comprises an actuator and the wireless controller; the wireless controller can transmit wireless control signals in the working state, and the actuator can receive the wireless control signals transmitted by the wireless controller in the working state.

In the embodiment of the utility model, the actuator can be at least one of an intelligent closestool, a water heater, a bathroom heater and an intelligent faucet, and the actuator can be an intelligent closestool, so that a control system for controlling the intelligent closestool based on the waterproof wireless controller can be formed; the actuator can also be a water heater, so that a control system for controlling the water heater based on the waterproof wireless controller can be formed; the actuator can also be an intelligent faucet, and a control system for controlling the intelligent faucet based on the waterproof wireless controller can be formed. Of course, the above application of the waterproof wireless controller in the intelligent toilet, the water heater, the bathroom heater and the intelligent faucet is only used as an example, in other embodiments, the actuator may be set as other devices, and the present invention is not limited in this respect.

Based on the same inventive concept, the utility model also provides an embodiment of a hot water system, which comprises the wireless controller and a water heater which is connected with the wireless controller in a communication way; the wireless controller can transmit wireless control signals under the working state, and the water heater can receive the wireless control signals transmitted by the wireless controller.

The embodiment of the utility model provides an in, this hot water system can also include intelligent tap, constitutes a water heater control system based on wireless controller, intelligent tap and the interconnection of water heater intelligence.

The embodiment of the utility model provides an in the described water heater can be gas heater, gas heater adopts two water pipe water supplies (cold water pipe and hot-water line), through the inside water mixing valve of intelligent tap adjusts the water yield of hot and cold water. The traditional gas water heater can only set the temperature of the water heater when water is boiled through the keys on the water heater panel, the water mixing valve of the water faucet controls the water outlet proportion of cold water and hot water to realize the adjustment of the water outlet temperature, and the water boiling temperature of the water heater cannot be dynamically adjusted at the end of the water faucet far away from the water heater. Because traditional gas heater can't dynamic adjustment temperature, when the user adjusted the comparison of tap's water yield, hot and cold water goes out the inhomogeneous temperature that can lead to tap to come out too high of temperature, leads to the user to scald. In addition, during the water consumption peak period, the terminal water pressure of the high-rise users is lower. At the moment, the water pressure of the hot water pipe cannot reach the water boiling threshold value of the water heater, the water heater cannot be started to boil water, and a water faucet of a user home cannot produce hot water. People living in high-rise buildings may experience deeply, when people have a bath at 9 o' clock (peak water consumption period) at night in winter, half of people do not have hot water suddenly after the people wash the bath, and people coming out of a water tap are cold for a while and hot or even cold water all the time. The reason is that the water heater cannot start to boil water due to low water pressure.

Based on the above problems, the present embodiment proposes the above hot water system, which includes an intelligent faucet, a water heater and a wireless controller; a system block diagram is shown in fig. 13.

Referring to fig. 13, the hot water system may be provided with two or more intelligent faucets, when a user opens the intelligent faucet, the user toggles a handle mechanism of a control mechanism of a faucet valve body to drive a self-generating device to act to generate electric energy, and a communication assembly of the intelligent faucet sends an opening signal containing opening information of the intelligent faucet to a heating device in a wireless manner. Similarly, when the user closes the intelligent faucet, the handle mechanism is shifted to drive the self-generating device of the intelligent faucet to act in the opposite direction, electric energy is generated similarly, the controller inside the faucet detects the action direction of the self-generating motor, and then the communication assembly sends a closing signal containing closing information of the intelligent faucet to the heating device in a wireless mode. When the heating device receives a starting signal for opening the intelligent faucet, water boiling is started; and when the heating device receives a closing signal of closing the intelligent faucet, the heating device stops boiling water.

The self-generating motor can generate electric energy regardless of forward action or reverse reset. And the polarity detection module of the communication assembly identifies the action direction of the self-generating device according to the direction of the electric signal. The circuit diagram is as shown in fig. 14, the rectifier module and the energy storage module convert pulse voltage generated by the self-generating motor into direct current electric energy, the voltage reduction and stabilization module adjusts the direct current electric energy to normal working voltage of the processor, the polarity of the self-generating motor is detected after the processor is powered on, if the self-generating motor acts in a forward direction, the processing module transmits a wireless message of opening the faucet through the transmitter, and if the self-generating motor acts in a reverse direction, the processing module transmits a wireless message of closing the faucet through the transmitter. As shown in fig. 15, before the intelligent faucet starts to work, hardware initialization is performed, initialization of hardware related modules includes initialization of a communication component, and then, in the use process of the intelligent faucet, if the self-generating motor acts in a forward direction, a faucet opening message is sent, and if the self-generating motor acts in a reverse direction, a faucet closing message is sent.

The embodiment of the utility model provides an in, this wireless controller can set up in the position that is close to intelligent tap. When a user uses water, the user can select different working modes, such as a hot water mode, a warm water mode and a cold water mode, by pressing the control part of the wireless controller, and can also dynamically adjust the water boiling temperature of the water heater. During the intelligent faucet water outlet period, a user presses the wireless controller, and after the water heater receives a message sent by the first wireless controller, a water outlet mode is set or the water outlet temperature is adjusted according to key values of the wireless controller. As shown in fig. 16, when the intelligent faucet is turned on, a faucet turning-on message, i.e., the above-mentioned turning-on signal, is sent to the heating device, the heating device starts to boil water according to the turning-on signal, and a default temperature value, i.e., the preset operating temperature value, controls the output water temperature; when the intelligent water faucet is closed, sending a water faucet closing message, namely the closing signal, to the heating device, and stopping heating water by the heating device according to the closing signal; in the water boiling process, if the heating device receives a message sent by the first wireless controller, the heating device is a temperature adjusting signal or a working mode signal according to the message, adjusts the water temperature or switches the working mode according to the message, namely the water boiling mode, operates according to the operation temperature value received by temperature adjustment or the switched working mode, and controls the output water temperature.

According to the scheme, the water heater is started/stopped to boil water through self-power-generation wireless data, the wireless controller is used for wirelessly controlling the water boiling temperature, the wireless controller is free of batteries and maintenance, and colleagues have the characteristic of random sticking and are stuck to the wireless controller beside the water faucet, so that the water heater can dynamically adjust the water outlet temperature of the intelligent water faucet through the wireless controller when a user uses water. The start and stop of the water heater do not depend on water pressure any more, and even when the water pressure is low in the water using peak period, the intelligent faucet can continuously output the water temperature desired by a user through the system.

The embodiment of the utility model provides a tap, include: a hot and cold water inlet housing (not shown) and the water inlet control mechanism of the faucet;

the cold and hot water inlet shell is connected with a water mixing valve of the water inlet control mechanism of the water faucet;

wherein:

the water inlet control mechanism of the water faucet comprises the water mixing valve and a control mechanism of a water faucet valve body;

and the valve core of the water mixing valve is connected with the control mechanism of the water faucet valve body.

In order to describe the hot water control system provided by the embodiment of the present invention in more detail, the following describes in detail the specific implementation process of the control mechanism of the faucet valve body of the intelligent faucet shown in fig. 17 to 48 as follows:

referring to fig. 17-31, an embodiment of a control mechanism for a faucet valve body provided by the present invention comprises: a self-generating device 201, a communication assembly 202, a base 203 and a handle mechanism 204;

the self-generating device 201 is electrically connected with the communication assembly 202;

the self-generating device 201 is fixed to the base 203;

the handle mechanism 204 is movably connected with the base 203;

the handle mechanism 204 is configured to be displaced in response to a forward driving force or a reverse driving force to control the self-generating device 201 to output a first electric signal or a second electric signal to the communication assembly 202;

the communication component 202 is configured to be capable of issuing a corresponding first control signal or second control signal in response to the first electrical signal or second electrical signal.

The embodiment of the utility model provides a control mechanism of tap valve body can be used for controlling tap's the case that mixes the water valve and open or close to realize tap play water control. The first control signal may be the on signal, and the second control signal may be the off signal. Or, the first control signal is the above-mentioned opening signal, and then the second control signal is the above-mentioned closing signal.

The embodiment of the utility model provides a control mechanism of tap valve body, produce the displacement through handle mechanism 204 motion, realize triggering from power generation facility 201, and then trigger communication subassembly 202 and send first control signal or second control signal, signal connection through tap and signal reception equipment, can acquire tap and still close the state for going out water state at present according to this first control signal and second control signal with realization signal reception equipment, and then signal reception equipment can carry out corresponding action according to tap's state, thereby guarantee tap's play water stably.

The embodiment of the utility model provides an among the control mechanism of tap valve body, handle mechanism 204 with swing joint between the base 203 can be the hub connection. Specifically, the base 203 may include a rotating shaft 2031, and the handle mechanism 204 may be connected to the base 203 through a shaft; the handle mechanism 204 is arranged to be displaced in rotation about the axis of rotation 2031 by an angle of 0.5 to 10 degrees. In order to ensure that the rotation angle of the handle mechanism 204 does not exceed the necessary limit, a limit portion 2032 may be provided on the base 203, and the rotation angle of the handle mechanism 204 is limited by the limit portion 2032, so as to ensure that the rotation angle of the handle mechanism 204 around the rotation shaft 2031 is always within a predetermined angle range.

The following describes in detail a specific implementation manner of the control mechanism of the faucet valve body according to the embodiments of the present invention, through several specific embodiments:

referring to fig. 17-24, in an embodiment of the control mechanism of the faucet valve body provided in the present invention, the self-generating device 201 may adopt a power generating device in the prior art, for example, a magnetoelectric pulse power generating device, and the self-generating device 201 includes a driving assembly 20113; the handle mechanism 204 is provided with a toggle part 2041; the toggle portion 2041 is configured to respond to the forward driving force or the reverse driving force to drive the driving assembly 20113, and trigger the self-generating device 201 to output the first electrical signal or the second electrical signal. For example, the driving assembly 20113 of the self-generating device 201 may include an elastic reed 201133, and if the toggle portion 2041 responds to the forward driving force or the backward driving force, the elastic reed 201133 may be driven to be elastically deformed, so as to control the self-generating device 201 to convert mechanical energy into electrical energy, and output the first electrical signal or the second electrical signal.

The embodiment of the utility model provides an in, this from power generation facility 201 can also adopt the from generator motor of other types among the prior art, for example, piezoceramics generator or other can be with the generator of mechanical energy conversion for the electric energy. Certainly when adopting this piezoceramics generator or other types from the generator motor, this toggle portion 2041 and this from generator 201's structural relation also can carry out adaptability adjustment according to from generator motor's structural feature, for example when adopting piezoceramics generator, because this piezoceramics generator's drive assembly 20113 is including arranging the shell fragment above the piezoceramics piece usually, then this toggle portion 2041 will act on this shell fragment when responding to forward drive power or reverse drive power, makes this shell fragment take place elastic deformation to act on the elastic piezoelectric ceramic piece of piezoceramics generator with the elastic potential energy of shell fragment, output first signal of telecommunication or second signal of telecommunication.

The embodiment of the utility model provides a from generating motor still includes can rectifier module (for example rectifier bridge), voltage conversion module (for example DC-DC) etc. general peripheral circuit, be used for with the electric energy conversion that from generating motor produced can be for the electric energy of communication subassembly 202 energy supply.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, the handle mechanism 204 may include a housing 2042 and an upper cover 2043 that are fixedly connected; and the housing 2042 and the upper cover 2043 enclose an accommodating space, and the base 203 at least partially extends into the accommodating space enclosed by the housing 2042 and the upper cover 2043, so that the self-generating device 201 and the communication component 202 are accommodated in the accommodating space. Specifically, the upper cover 2043 may have internal threads, the housing 2042 may have external threads, and the upper cover 2043 may be screwed to the housing 2042. Of course, in the embodiment of the present invention, the connection mode between the upper cover 2043 and the housing 2042 can also adopt other fixing modes in the prior art, as long as the fixed connection between the upper cover 2043 and the housing 2042 can be realized, in the embodiment of the present invention, no specific limitation may be made to this.

The embodiment of the utility model provides an in, through arranging in the accommodation space that this casing 2042 and upper cover 2043 enclose from power generation facility 201 and communication subassembly 202, in the tap after the equipment, realize keeping apart the control mechanism of tap valve body and the lower part water route of tap, the water of avoiding flowing through tap causes the damage to this from power generation facility 201 and communication subassembly 202.

In one embodiment, referring to fig. 17 and 18, the housing 2042 includes a fixedly connected lower shell 20421 and a middle cover 20422, the middle cover 20422 is provided with a communication component accommodating hole 204221, and the communication component 202 is accommodated in the communication component accommodating hole 204221. The toggle portion 2041 includes a first contact 20411 disposed on the middle cover 20422 and a second contact 20412 disposed on the lower cover 20421, and a gap with a preset height is formed between the first contact 20411 and the second contact 20412;

the elastic reed 201133 at least partially extends into the gap with the preset height;

the toggle part 2041 responds to the positive driving force, so that the first contact 20411 presses against the elastic reed 201133 to be elastically deformed, and the self-generating device 201 is controlled to output the first electric signal;

the toggle part 2041 responds to the reverse driving force, so that the second contact 20412 presses against the elastic reed 201133 to be elastically deformed, and the self-generating device 201 is controlled to output the second electric signal.

In the embodiment of the present invention, the toggle portion 2041 is implemented as the first contact 20411 of the middle cover 20422 and is disposed on the second contact 20412 of the lower cover 20421, and the elastic reed 201133 of the driving component 20113 of the self-generating device 201 is disposed in the gap formed by the first contact 20411 and the second contact 20412, when the handle mechanism 204 of the faucet is operated, in response to the forward driving force or the backward driving force, the first contact 20411 and the second contact 20412 move simultaneously, and the elastic reed 201133 is driven to generate elastic deformation, so that the self-generating device 201 converts mechanical energy into electrical energy, and outputs the first electrical signal or the second electrical signal.

In the embodiment of the present invention, the middle cover 20422 and the lower cover 20421 may be fixed by bolts, for example, as shown in fig. 19A to 20, three bolt piles 204211 are provided on the lower cover 20421, three screw holes 204222 are provided at corresponding positions of the middle cover 20422, and the bolts pass through the corresponding screw holes 204222 and are screwed into the bolt piles 204211, so as to fix the middle cover 20422 and the lower cover 20421. Of course, in the embodiment of the present invention, the fixing mode of the middle cover 20422 and the lower shell 20421 may also adopt other fixing modes in the prior art, as long as the fixing of the middle cover 20422 and the lower shell 20421 can be realized, and therefore, the embodiment of the present invention may not be specifically limited.

In one embodiment, referring to fig. 21, the base 203 further includes a first fixing bracket 2033 and a second fixing bracket 2034, wherein the first fixing bracket 2033 is provided with a guide rail 20331, the second fixing bracket 2034 is provided with a sliding groove 20341, and the sliding groove 20341 is snapped into the guide rail 20331, so that the first fixing bracket 2033, the second fixing bracket 2034 and the second fixing bracket 2034 are fixedly connected. In order to ensure the firm fixation between the first fixing bracket 2033 and the second fixing bracket 2034, a bolt hole 20332 may be provided in the first fixing bracket 2033, a first through hole 20342 may be provided at a corresponding position of the second fixing bracket 2034, and the first fixing bracket 2033 and the second fixing bracket 2034 may be screwed together by a fixing bolt passing through the first through hole 20342 and screwed into the bolt hole 20332.

Referring to fig. 19A to 20, a rotating shaft 2031 is provided on each side of the first fixing bracket 2033. The housing 2042 is provided with a hinge receiving portion 20423 on each side thereof to cooperate with the hinge 2031 such that the handle mechanism 204 can rotate relative to the hinge 2031 under the action of a forward driving force or a reverse driving force. Specifically, the middle cover 20422 may be provided with a first clamping groove 204231, the lower cover 20421 may be provided with a second clamping groove 204232, and the first clamping groove 204231 and the second clamping groove 204232 may form the rotating shaft accommodating portion 20423. In the embodiment of the present invention, the rotating shaft 2031 of the first fixing bracket 2033 can be disposed at one end away from the first contact 20411 and the second contact 20412, so that the handle mechanism 204 only needs to rotate a small angle, and the amplitude of the movement of the first contact 20411 and the second contact 20412 can satisfy the requirement of driving the elastic reed 201133.

Referring to fig. 18 and 20, the lower shell 20421 is further provided with a receiving hole 204212; the upper end portions of the first and second fixing brackets 2033 and 2034 pass through the accommodation hole 204212 and are placed in the accommodation space. Referring to fig. 21, the second fixing bracket 2034 is provided with two hooking portions 20343, and the self-generating device 201 is caught by the two hooking portions 20343, thereby fixing the self-generating device 201 to a limited area of the first fixing bracket 2033 and the second fixing bracket 2034. During installation, the first fixing bracket 2033 may first pass through the accommodating hole 204212, the self-generating device 201 is then placed above the first fixing bracket 2033, the sliding groove 20341 of the second fixing bracket 2034 is aligned with the guide rail 20331 of the first fixing bracket 2033, the second fixing bracket 2034 is clamped on the first fixing bracket 2033, and then the first fixing bracket 2033 and the second fixing bracket 2034 are screwed and fixed by fixing bolts, so that the two clamping hook portions 20343 of the second fixing bracket 2034 clamp the self-generating device 201.

In one embodiment, a gap of a predetermined distance is formed between a side surface of the first fixing bracket 2033 adjacent to the handle and the receiving hole 204212, and forms a limit portion 2032 of a control mechanism of the faucet valve body. When the handle of the faucet is operated, the handle mechanism 204 moves relative to the base 203 in response to the forward driving force or the reverse driving force, and when the sidewall of the accommodating hole 204212 abuts against the outer wall of the first fixing bracket 2033 during the movement, the handle mechanism 204 cannot rotate relative to the base 203 any more, so that the handle mechanism 204 is limited.

In order to facilitate the arrangement of the self-generating device 201 and the communication assembly 202 in the accommodating space, save space and realize the miniaturization of the control mechanism of the faucet valve body, the communication assembly 202 is arranged above the self-generating device 201.

In an embodiment, in order to ensure the stability of the communication module 202 above the self-generating device 201, referring to fig. 21, the first fixing bracket 2033 includes two limiting ribs 20333 symmetrically disposed, and ends of the two limiting ribs 20333 penetrate through the communication module accommodating hole 204221 of the middle cover 20422, so as to dispose one end of the communication module 202 between the two limiting ribs 20333, and finally, the upper cover 2043 and the lower cover 20421 are fixedly connected, and the communication module 202 is sealed in the accommodating space between the upper cover 2043 and the housing 2042 by the upper cover 2043. In order to ensure the sealing effect between the upper cover 2043 and the lower cover 20421, a first waterproof ring 2044 may be further provided between the upper cover 2043 and the lower cover 20421 for waterproof sealing. The first waterproof ring 2044 may be a rubber ring, a silica gel ring, or a sealing ring made of other materials used in the prior art.

Referring to fig. 17 and 18, the control mechanism of a faucet valve body according to an embodiment of the present invention further includes a waterproof jacket assembly 205, the waterproof jacket assembly 205 is respectively fixedly connected to the lower shell 20421 and the first fixing bracket 2033, the waterproof jacket assembly 205 has a second through hole (not shown in the figure), and the lower end of the first fixing bracket 2033 passes through the second through hole.

In one particular embodiment, referring to FIG. 21, the waterproof jacket assembly 205 comprises a waterproof jacket body 2052, a first fixed rubber ring 2053, and a second fixed rubber ring 2054; the second through hole is formed in the bottom of the waterproof jacket body 2052;

the upper end of the waterproof jacket body 2052 is fixed to the lower shell 20421 by the first fixing rubber ring 2053;

the lower end of the waterproof case body 2052 is fixed to the first fixing bracket 2033 via the second fixing rubber ring 2054.

The embodiment of the utility model provides an in, this waterproof cover body 2052 can be pellosil or rubber membrane, is fixed in this waterproof cover body 2052 in inferior valve 20421 and first fixed bolster 2033 through first fixed rubber ring 2053 and second fixed rubber ring 2054 to prevent when tap uses, the water of tap flows through gets into the accommodation space of the control mechanism of this tap valve body through the clearance between this inferior valve 20421 and the first fixed bolster 2033, cause the damage from power generation facility 201 or communication component 202. The first fixed rubber ring 2053 and the second fixed rubber ring 2054 may be rubber rings, silicone rings, or sealing rings made of other materials as used in the prior art.

The embodiment of the utility model provides an among the control mechanism of tap valve body, this first fixed bolster 2033's lower tip has the case and holds chamber 20334, and tap's the case that mixes the water valve is fixed in this case and holds in the chamber 20334.

In one embodiment, the inner periphery of the valve element receiving cavity 20334 may be square, rectangular, triangular or other non-circular structure, and correspondingly, the cross section of the valve element of the mixing valve of the faucet is square, rectangular, triangular or other non-circular structure, so that the valve element of the mixing valve is received in the valve element receiving cavity 20334, and the opening and closing of the mixing valve is controlled by the control mechanism of the faucet valve body. The specific structure of the case and the case accommodating cavity 20334 of the mixing valve can refer to the structure of the faucet in the prior art, and the embodiment of the present invention does not limit the structure.

Use including the embodiment of the utility model provides a during tap of control mechanism of tap valve body, under tap is in the closed condition, when the user applys forward drive power to the control mechanism's of this tap valve body handle, this handle mechanism 204 rotates predetermined angle for this base 203 earlier, through this spacing portion 2032 block, this handle mechanism 204 is spacing by this spacing portion 2032, then, this base 203 and this handle mechanism 204 drive the case motion of mixing the water valve in this tap jointly, thereby make the valve of this mixing water valve open, realize tap and go out water, when rotating the handle, this handle mechanism 204 and this base 203 rotate simultaneously, thereby drive the case rotation of this mixing water valve, thereby adjust the play water flow of the hot and cold water of mixing the water valve, realize adjusting tap's play water temperature. When the faucet is in a water outlet state, when a user applies a reverse driving force to the handle of the control mechanism of the faucet valve body, the handle mechanism 204 rotates reversely relative to the base 203 by a preset angle, the handle mechanism 204 is limited by the limiting portion 2032 by the blocking of the limiting portion 2032, and then the base 203 and the handle mechanism 204 drive the valve element of the mixing valve in the faucet to move together, so that the valve of the mixing valve is closed.

In the embodiment of the present invention, referring to fig. 22, the communication assembly 202 may include a communication module and a signal detection module;

the signal detection module is respectively connected with the self-generating device 201 and the communication module;

the signal detection module is configured to send a first trigger signal or a second trigger signal to the communication module if the first electrical signal or the second electrical signal output by the self-power generation device 201 is detected;

the communication module is configured to be capable of issuing the corresponding first control signal or the second control signal in response to the first trigger signal or the second trigger signal.

In a specific embodiment, the communication assembly 202 may further include a rectifying module and an energy storage module, where the rectifying module is connected to the energy storage module and then connected between the self-generating device 201 and the communication module, the rectifying module is configured to rectify the first electrical signal or the second electrical signal output by the self-generating device 201, and the energy storage module is configured to store the rectified electrical energy so as to supply power to the communication module. The specific implementation of the rectifying module and the energy storage module in this embodiment can be seen with reference to fig. 22. Of course, based on the example of fig. 22, a person skilled in the art may also implement the rectifying module and the energy storage module in other manners known in the art, and the specific implementation manner of the embodiment of the present invention may not be limited in particular.

Referring to fig. 22, the signal detection module includes a first set of acquisition components and a second set of acquisition components, wherein the first set of acquisition components specifically includes:

the diode D5 is used as an input signal rectifier, wherein the anode of the diode D5 is used as a first input end of the detection device and is connected with a first output port of the power generation device;

the cathode of the diode D5 is connected with one end of a resistor R2, wherein the other end of the resistor R2 is connected with one end of a resistor R4 and then is used as the output end of the detection device to be connected with the first control port of the processing device; the other end of the resistor R4 is grounded and forms a voltage division unit with the resistor R2;

a capacitor C3 may be connected in parallel between the diode D5 and the resistor R2, and the other end of the capacitor C3 is grounded to form a high-frequency filtering branch.

The second set of collection components specifically includes:

the diode D4 is used as an input signal rectifier, wherein the anode of the diode D4 is used as a second input end of the detection device and is connected with a second output port of the power generation device;

the cathode of the diode D4 is connected with one end of a resistor R1, wherein the other end of the resistor R1 is connected with one end of a resistor R3 and then is used as the output end of the detection device to be connected with the second control port of the processing device; the other end of the resistor R3 is grounded and forms a voltage division unit with the resistor R1;

a capacitor C2 may be connected in parallel between the diode D4 and the resistor R1, and the other end of the capacitor C2 is grounded to form a high-frequency filtering branch.

Supposing that when the first electrical signal output by the self-generating device 201 is, the polarity of the electrical energy at the input port of the signal detection module is negative, the capacitor C3 is not charged with electrical energy, the first control signal output by the signal detection module is low level, meanwhile, the electrical energy generated by the self-generating device 201 reaches the energy storage module through rectification, the communication module obtains the electrical energy, and meanwhile, the first control signal of the signal detection module is read; when the second electrical signal is output from the power generation device 201, the polarity of the electrical energy at the input port of the signal detection module is positive, the capacitor C3 is charged, the second control signal output by the signal detection module is high level, meanwhile, the electrical energy generated by the power generation device 201 reaches the energy storage module through rectification, the communication module obtains the electrical energy, and meanwhile, the second control signal of the signal detection module is read. Certainly, when the first electrical signal is output from the self-generating device 201, the polarity of the electrical energy at the input port of the signal detection module is positive, and when the second electrical signal is output from the self-generating device 201, the polarity of the electrical energy at the input port of the signal detection module is negative. The above example is only a specific implementation manner of the signal detection module, and those skilled in the art can also implement the signal detection module by adopting other manners in the prior art based on the example of fig. 22, and the embodiment of the present invention may not be limited in particular.

For further example, referring to fig. 23, the above-mentioned magnetoelectric pulse generating device may be a generator as shown in fig. 23, which is a stand-alone module comprising: a magnetically permeable assembly 20111, a coil assembly 20112, a magnet assembly 20114, and a drive assembly 20113. The magnetically conductive assembly 20111, the coil assembly 20112, the magnet assembly 20114, and the drive assembly 20113 are integrally connected to one another.

The magnetic conductive assembly 20111 includes a first magnetic conductive member 201111 and a second magnetic conductive member 201112, and the first magnetic conductive member 201111 and the second magnetic conductive member 201112 are disposed opposite to each other. The first magnetic conductive member 201111 is fixedly connected to one end of the second magnetic conductive member 201112 through a connecting member 201113, and an upper contact member 201114 and a lower contact member 201115 are respectively disposed above and below the other end of the first magnetic conductive member.

The coil assembly 20112 is disposed inside the magnetic conductive assembly 20111, and the coil assembly 20112 includes: securing structure 201123, magnetic core 201122, bobbin 201124, and coil 201121 surrounding said bobbin 201124; wherein the bobbin 201124 is hollow, and the coil 201121 is wound on the bobbin 201124; after passing through the bobbin 201124, the magnetic core 201122 has one end fixedly connected to the connecting member 201113 and the other end passing through the bobbin 201124 and inserted into the fixing structure 201123 and protruding out of the fixing structure 201123 to be placed between the upper contact and the lower contact to form a middle contact. The fixing structure 201123 is used for fixing the other end of the coil bobbin 201124 and the magnetic core 201122, and the coil 201121 can be electrically connected to the communication module 202.

Drive assembly 20113, its axis of rotation 201131 that includes two relative settings, the one end of two axis of rotation 201131 is passed through mounting bracket 201132 and is connected, and the other end is provided with rotation portion respectively, first magnetic conduction piece 201111 with being close to of second magnetic conduction piece 201112 the one end of connecting piece 201113 is provided with the rotation hole respectively, the rotation hole with rotation portion suits, and two axis of rotation 201131 pass through the rotatable connection of rotation portion is in on the magnetic conduction subassembly 20111. The side of the mounting rack 201132 away from the coil 201121 is provided with an elastic spring 201133, and the entire driving assembly 20113 can be driven to displace up and down by pressing the elastic spring 201133.

The magnet assembly 20114 is disposed on the drive assembly 20113, and the magnet assembly 20114 includes: the magnet 201141, a first magnetic conductive plate 201142 and a second magnetic conductive plate 201143, wherein the magnet 201141 is disposed in a mounting groove disposed inside the mounting frame 201132, and the first magnetic conductive plate 201142 and the second magnetic conductive plate 201143 are disposed opposite to each other at two ends of the magnet 201141, which have different polarities; the driving assembly 20113 is configured to drive the magnet assembly 20114 to displace relative to the magnetic conductive assembly 20111, so as to generate an inductive power.

When the above-described magnetoelectric pulse generating device is fixed to the first fixing bracket 2033 and the second fixing bracket 2034 and is placed in the accommodating space, the end of the spring reed 201133 is located in the gap between the first contact 20411 and the second contact 20412. When a user operates a handle of a control mechanism of the faucet valve body, the first contact 20411 and the second contact 20412 move simultaneously in response to the forward driving force or the reverse driving force, and the elastic reed 201133 is driven to be elastically deformed, so that the self-generating device 201 is controlled to convert mechanical energy into electric energy, and the first electric signal or the second electric signal is output.

Referring to fig. 24 to 28, in an embodiment of the control mechanism of the faucet valve body provided by the present invention, the self-generating device 201 may adopt a power generating device in the prior art, for example, a magnetoelectric pulse power generating device, and the self-generating device 201 includes a driving assembly 20113; the handle mechanism 204 is provided with a toggle part 2041; the toggle portion 2041 is configured to respond to the forward driving force or the reverse driving force to drive the driving assembly 20113, and trigger the self-generating device 201 to output the first electrical signal or the second electrical signal. For example, the driving assembly 20113 of the self-generating device 201 may include an elastic reed 201133, and if the toggle portion 2041 responds to the forward driving force or the backward driving force, the elastic reed 201133 may be driven to be elastically deformed, so as to control the self-generating device 201 to convert mechanical energy into electrical energy, and output the first electrical signal or the second electrical signal.

Similar to the description in the foregoing embodiments, the self-generating device 201 in this embodiment may also adopt other types of self-generating motors in the prior art, and the detailed description of the specific implementation manner of the self-generating device may refer to the detailed description in the foregoing embodiments, and is not repeated herein.

Similar to the description of the above embodiment, the specific structure of the magnetoelectric pulse generating device used in the present embodiment may be the magnetoelectric pulse generating device shown in fig. 24.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, referring to fig. 24, the handle mechanism 204 may include a housing 2042 and an upper cover 2043 which are fixedly connected; and the housing 2042 and the upper cover 2043 enclose an accommodating space, and the base 203 at least partially extends into the accommodating space enclosed by the housing 2042 and the upper cover 2043, so that the self-generating device 201 and the communication component 202 are accommodated in the accommodating space. Specifically, the upper cover 2043 may have internal threads, the housing 2042 may have external threads, and the upper cover 2043 may be threadedly coupled to the housing 2042. Of course, in the embodiment of the present invention, the connection mode between the upper cover 2043 and the housing 2042 can also adopt other fixing modes in the prior art, as long as the fixed connection between the upper cover 2043 and the housing 2042 can be realized, in the embodiment of the present invention, no specific limitation may be made to this.

The embodiment of the utility model provides an in, through arranging in the accommodation space that this casing 2042 and upper cover 2043 enclose from power generation facility 201 and communication subassembly 202, in the tap after the equipment, realize keeping apart the control mechanism of tap valve body and the lower part water route of tap, the water of avoiding flowing through tap causes the damage to this from power generation facility 201 and communication subassembly 202.

In order to facilitate the arrangement of the self-generating device 201 and the communication assembly 202 in the accommodating space, save space and realize the miniaturization of the control mechanism of the faucet valve body, the communication assembly 202 is arranged above the self-generating device 201. When the upper cover 2043 and the housing 2042 are fixedly connected, the communication unit 202 is fixed between the upper cover 2043 and the self-power-generating device 201 via the upper cover 2043. The embodiment of the utility model provides an in, in order to guarantee the sealed effect between casing 2042 and the upper cover 2043, can set up the waterproof circle of second between this casing 2042 and upper cover 2043, carry out waterproof sealing. The second waterproof ring can be a rubber ring, a silica gel ring or a sealing ring made of other materials adopted in the prior art.

In one embodiment, referring to fig. 26, the toggle portion 2041 includes a toggle piece 20421A disposed on the housing 2042; a first long slot 204211A with a preset inclination angle with the horizontal plane is arranged on the shifting piece 20421A, and at least part of the elastic spring 201133 extends into the first long slot 204211A;

the toggle plate 20421A toggles the elastic reed 201133 to be twisted and deformed in response to the forward driving force to control the self-generating device 201 to output the first electric signal, and toggles the elastic reed 201133 to be twisted and deformed in response to the reverse driving force to control the self-generating device 201 to output the second electric signal.

In the embodiment of the present invention, by implementing the toggle portion 2041 as the toggle piece 20421A on the housing 2042, a first long slot 204211A is disposed on the shifting plate 20421A and forms a predetermined inclination angle with the horizontal plane, and the elastic reed 201133 of the driving assembly 20113 of the self-generating device 201 is placed in the first long slot 204211a, when the handle mechanism 204 of the faucet is operated, in response to the forward driving force or the reverse driving force, the shifting piece 20421A moves left and right under the driving of the handle mechanism 204, the left side or the right side of the elastic reed 201133 abuts against the first slot 204211A, because the first slot 204211A of the pick 20421A has a slope, the elastic spring 201133 is twisted and deformed by the pressing of the first long slot 204211a, so as to drive the elastic spring 201133 to move up and down, thereby, the self-generating device 201 converts the mechanical energy into the electrical energy and outputs the first electrical signal or the second electrical signal.

In one embodiment, referring to fig. 24 and 25, the base 203 includes a rotating shaft 2031 and a first self-power-generation-device-fixing bracket 2035, the rotating shaft 2031 is fixedly connected to the first self-power-generation-device-fixing bracket 2035, and the self-power-generation device 201 is fixed to the first self-power-generation-device-fixing bracket 2035. Specifically, the rotating shaft 2031 may be configured as the hollow shaft, the inner wall of the rotating shaft 2031 is provided with threads, the first self-power-generation-device-fixing bracket 2035 is provided with a third through hole 20351, and a fixing bolt passes through the third through hole 20351 and is screwed to the inner wall of the rotating shaft 2031, so as to fixedly connect the first self-power-generation-device-fixing bracket 2035 and the rotating shaft 2031.

In one embodiment, the housing 2042 is provided with a hinge accommodating portion 20423, and the hinge accommodating portion 20423 is matched with the hinge 2031. Specifically, the rotating shaft accommodating portion 20423 may be an annular hole (not shown) provided in the housing 2042, and an upper end portion of the rotating shaft 2031 may pass through the annular hole and extend into the accommodating space, so that the housing 2042 may rotate around the rotating shaft 2031 in the horizontal direction.

In an embodiment, in the control mechanism of the faucet valve body, referring to fig. 27, the position-limiting portion 2032 may include two position-limiting studs 20321 symmetrically disposed on the housing 2042, and the first self-power-generation-device-fixing bracket 2035 is disposed between the two position-limiting studs 20321. When the control mechanism of the faucet valve body is in the initial position, the first self-generating device fixing bracket 2035 is placed in the middle of the two position-limiting studs 20321, the distance between the left and right side walls of the first self-generating device fixing bracket 2035 and the corresponding position-limiting studs 20321 is equal, when the handle of the faucet is operated, the handle mechanism 204 horizontally rotates relative to the rotating shaft 2031 in response to the forward driving force or the reverse driving force, and during the movement, when the side wall of the first self-generating device fixing bracket 2035 abuts against the position-limiting studs 20321, the handle mechanism 204 cannot rotate relative to the rotating shaft 2031 any more, so that the position limitation of the handle mechanism 204 is realized.

In a specific embodiment, the first self-generating device fixing bracket 2035 is symmetrically provided with two buckles 20352, and the self-generating device 201 is clamped and fixed by the buckles 20352. Certainly the embodiment of the utility model provides an in, this from power generation facility 201 can also adopt other modes among the prior art to be fixed in this first from power generation facility fixed bolster 2035, and detailed description among the prior art can be referred to specific implementation mode, and no longer the description is given here.

In one embodiment, referring to fig. 24 and 25, the rotating shaft 2031 has a first step 20311, and a first washer 2036 is disposed at a connection between the first step 20311 of the rotating shaft 2031 and the annular hole. The embodiment of the present invention provides an embodiment, when the handle mechanism 204 rotates relative to the rotating shaft 2031 through the first gasket 2036, the water flowing through the faucet is prevented from entering the accommodating space of the control mechanism of the faucet valve body through the gap between the housing 2042 and the first fixing support 2033, resulting in the damage of the self-generating device 201 or the communication component 202. The first gasket 2036 may be a rubber ring, a silicone ring, or a sealing ring made of other materials used in the prior art.

The embodiment of the utility model provides an among the control mechanism of tap valve body, this pivot 2031's lower tip has the case and holds chamber 20334, and tap's the case that mixes the water valve is fixed in this case and holds in the chamber 20334. Referring to fig. 28, the inner wall of the valve element receiving cavity 20334 of the rotation shaft 2031 may be provided with an internal gear 203341, and an external gear is correspondingly provided on the valve element of the mixing valve of the faucet, so that the mixing valve is geared with the control mechanism of the faucet valve body. A second gasket 2037 can be arranged between the valve core accommodating cavity and the water mixing valve to realize the waterproof function between the rotating shaft and the water mixing valve.

When using the tap that includes the control mechanism of the tap valve body that the embodiment provided, when tap is in the off-state, when the user applyed forward drive power to the control mechanism's of this tap valve body handle, this handle mechanism 204 rotated predetermined angle for this pivot 2031 earlier, through stopping of this spacing portion 2032, this handle mechanism 204 is spacing by this spacing portion 2032, then, this pivot 2031 and this handle mechanism 204 drive the case motion of mixing the water valve in this tap jointly, thereby make the valve of this mixing the water valve open, realize tap and go out water, when continuing forward turning handle, this handle mechanism 204 and this pivot 2031 rotate simultaneously, thereby the case that drives this mixing the water valve through the gear rotates, thereby adjust the play water flow and the temperature regulation of the hot and cold water of mixing the water valve. When the faucet is in a water outlet state, when a user applies a reverse driving force to the handle of the control mechanism of the faucet valve body, the handle mechanism 204 rotates reversely by a preset angle relative to the rotating shaft 2031, the handle mechanism 204 is limited by the limiting portion 2032 by the blocking of the limiting portion 2032, and then the base 203 and the handle mechanism 204 drive the valve element of the mixing valve in the faucet to move together, so that the valve of the mixing valve is closed.

In the embodiment of the present invention, referring to fig. 22, the communication assembly 202 may include a communication module and a signal detection module;

the signal detection module is respectively connected with the self-generating device 201 and the communication module;

the signal detection module is configured to send a first trigger signal or a second trigger signal to the communication module if the first electrical signal or the second electrical signal output by the self-power generation device 201 is detected;

the communication module is configured to be capable of issuing the corresponding first control signal or the second control signal in response to the first trigger signal or the second trigger signal.

In a specific embodiment, the communication assembly 202 may further include a rectifying module and an energy storage module, where the rectifying module is connected to the energy storage module and then connected between the self-generating device 201 and the communication module, the rectifying module is configured to rectify the first electrical signal or the second electrical signal output by the self-generating device 201, and the energy storage module is configured to store rectified electrical energy so as to supply power to the communication module.

Similar to the embodiments described above, the specific implementation of the signal detection module, the rectification module and the energy storage module in the embodiments can also be shown with reference to fig. 22. For a specific implementation process, reference may be made to the detailed description in the foregoing embodiments, which is not described herein again.

Referring to fig. 29-31, in an embodiment of the control mechanism of the faucet valve body provided by the present invention, the self-generating device 201 may adopt a power generating device in the prior art, for example, a magnetoelectric pulse power generating device, and the self-generating device 201 includes a driving assembly 20113; the handle mechanism 204 is provided with a toggle part 2041; the toggle portion 2041 is configured to respond to the forward driving force or the reverse driving force to drive the driving assembly 20113, and trigger the self-generating device 201 to output the first electrical signal or the second electrical signal. For example, the driving assembly 20113 of the self-generating device 201 may include an elastic reed 201133, and if the toggle portion 2041 responds to the forward driving force or the backward driving force, the elastic reed 201133 may be driven to be elastically deformed, so as to control the self-generating device 201 to convert mechanical energy into electrical energy, and output the first electrical signal or the second electrical signal.

Similar to the description in the foregoing embodiments, the self-generating device 201 in this embodiment may also adopt other types of self-generating motors in the prior art, and the detailed description of the specific implementation manner of the self-generating device may refer to the detailed description in the foregoing embodiments, and is not repeated herein.

Similar to the description of the above embodiment, the specific structure of the magnetoelectric pulse generating device used in the present embodiment may be the magnetoelectric pulse generating device shown in fig. 23.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, referring to fig. 29, the handle mechanism 204 may include a housing 2042 and an upper cover 2043 that are fixedly connected; and the housing 2042 and the upper cover 2043 enclose an accommodating space, and the base 203 at least partially extends into the accommodating space enclosed by the housing 2042 and the upper cover 2043, so that the self-generating device 201 and the communication component 202 are accommodated in the accommodating space. Specifically, the upper cover 2043 may have internal threads, the housing 2042 may have external threads, and the upper cover 2043 may be screwed to the housing 2042. Of course, in the embodiment of the present invention, the connection mode between the upper cover 2043 and the housing 2042 may also adopt other fixing modes in the prior art, as long as the fixed connection between the upper cover 2043 and the housing 2042 can be realized, in the embodiment of the present invention, no specific limitation may be made to this.

The embodiment of the utility model provides an in, through arranging in the accommodation space that this casing 2042 and upper cover 2043 enclose from power generation facility 201 and communication subassembly 202, in the tap after the equipment, realize keeping apart the control mechanism of tap valve body and the lower part water route of tap, the water of avoiding flowing through tap causes the damage to this from power generation facility 201 and communication subassembly 202.

In order to facilitate the arrangement of the self-generating device 201 and the communication assembly 202 in the accommodating space, save space and realize the miniaturization of the control mechanism of the faucet valve body, the communication assembly 202 is arranged above the self-generating device 201. When the upper cover 2043 and the housing 2042 are fixedly connected, the communication unit 202 is fixed between the upper cover 2043 and the self-power-generating device 201 via the upper cover 2043. The embodiment of the utility model provides an in, in order to guarantee the sealed effect between casing 2042 and the upper cover 2043, can set up the waterproof circle of second between this casing 2042 and upper cover 2043, carry out waterproof sealing. The second waterproof ring can be a rubber ring, a silica gel ring or a sealing ring made of other materials adopted in the prior art.

In one embodiment, referring to fig. 29, the toggle portion 2041 includes a toggle piece 20421A disposed on the housing 2042; a second long slot 204212a arranged perpendicular to the horizontal plane is arranged on the shifting piece 20421A, and the elastic spring leaf 201133 at least partially extends into the second long slot 204212 a;

the shifting piece 20421A presses the elastic reed 201133 to generate elastic deformation in response to the forward driving force so as to control the self-generating device 201 to output the first electric signal, and presses the elastic reed 201133 to generate elastic deformation in response to the reverse driving force so as to control the self-generating device 201 to output the second electric signal.

The embodiment of the present invention provides an embodiment, through implementing this toggle part 2041 as the plectrum 20421A on this casing 2042, be provided with the second long slotted hole 204212a that is perpendicular to the horizontal plane setting on plectrum 20421A, and place this from the elastic reed 201133 of the drive assembly 20113 of power generation device 201 in this second long slotted hole 204212a, when operating the handle mechanism 204 of tap, in response to this forward driving force or reverse driving force, this plectrum 20421A carries out the side-to-side movement under handle mechanism 204 drives, this shell fragment can butt in this second long slotted hole 204212a, support through this second long slotted hole 204212a and press and make this elastic reed 201133 take place elastic deformation, drive this elastic reed 201133 and remove, thereby make from power generation device 201 convert mechanical energy into the electric energy, output this first signal of electricity or second signal of telecommunication.

In one embodiment, referring to fig. 29 and 30, the base 203 includes a rotating shaft 2031 and a first self-power-generation-device-fixing bracket 2035, the rotating shaft 2031 is fixedly connected to the first self-power-generation-device-fixing bracket 2035, and the self-power-generation device 201 is fixed to the first self-power-generation-device-fixing bracket 2035. Specifically, the rotating shaft 2031 may be configured as the hollow shaft, the inner wall of the rotating shaft 2031 is provided with threads, and the first self-power-generation-device-fixing bracket 2035 is provided with a third through hole (not shown in the figure), and the fixing bolt passes through the third through hole and is screwed to the inner wall of the rotating shaft 2031, so as to fixedly connect the first self-power-generation-device-fixing bracket 2035 and the rotating shaft 2031.

In one embodiment, referring to fig. 31, the first self-generating device fixing bracket 2035 is symmetrically provided with two fasteners 20352, and the self-generating device 201 is fastened and fixed by the fasteners 20352. Certainly the embodiment of the utility model provides an in, this from power generation facility 201 can also adopt other modes among the prior art to be fixed in this first from power generation facility fixed bolster 2035, and detailed description among the prior art can be referred to specific implementation mode, and no longer the description is given here.

In the embodiment of the present invention, the self-generating device 201 is vertically fixed on the first self-generating device fixing bracket 2035 and is integrated with the rotating shaft 2031.

In one embodiment, the housing 2042 is provided with a hinge accommodating portion 20423, and the hinge accommodating portion 20423 is matched with the hinge 2031. Specifically, the rotating shaft accommodating portion 20423 may be an annular hole (not shown) provided in the housing 2042, and an upper end portion of the rotating shaft 2031 may pass through the annular hole and extend into the accommodating space, so that the housing 2042 may rotate around the rotating shaft 2031 in the horizontal direction.

In one embodiment, referring to fig. 31, in the control mechanism of the faucet valve body, the position-limiting portion 2032 may include two position-limiting studs 20321 symmetrically disposed on the housing 2042, and the first self-power-generation-device-fixing bracket 2035 is disposed between the two position-limiting studs 20321. When the control mechanism of the faucet valve body is in the initial position, the first self-generating device fixing bracket 2035 is placed in the middle of the two position-limiting studs 20321, the distance between the left and right side walls of the first self-generating device fixing bracket 2035 and the corresponding position-limiting studs 20321 is equal, when the handle of the faucet is operated, the handle mechanism 204 horizontally rotates relative to the rotating shaft 2031 in response to the forward driving force or the reverse driving force, and during the movement, when the side wall of the first self-generating device fixing bracket 2035 abuts against the position-limiting studs 20321, the handle mechanism 204 cannot rotate relative to the rotating shaft 2031 any more, so that the position limitation of the handle mechanism 204 is realized.

In one embodiment, referring to fig. 29 and 30, the rotating shaft 2031 has a first step 20311, and a first washer 2036 is disposed at a connection between the first step 20311 of the rotating shaft 2031 and the annular hole. The embodiment of the present invention provides an embodiment, when the handle mechanism 204 rotates relative to the rotating shaft 2031 through the first gasket 2036, the water flowing through the faucet is prevented from entering the accommodating space of the control mechanism of the faucet valve body through the gap between the housing 2042 and the first fixing support 2033, resulting in the damage of the self-generating device 201 or the communication component 202. The first gasket 2036 may be a rubber ring, a silicone ring, or a sealing ring made of other materials used in the prior art.

The embodiment of the utility model provides an among the control mechanism of tap valve body, refer to fig. 28 and show, the lower tip of this pivot 2031 has the case and holds chamber 20334, and tap's the case that mixes the water valve is fixed in this case and holds in the chamber 20334.

In one embodiment, referring to fig. 28, the inner wall of the valve core receiving cavity 20334 of the rotating shaft 2031 is provided with an internal gear 203341, and an external gear is correspondingly provided on the valve core of the mixing valve of the faucet, similar to the above description, so as to realize the gear connection between the mixing valve and the control mechanism of the faucet valve body. A second gasket 2037 may be disposed between the valve core accommodating cavity and the water mixing valve to realize a waterproof function between the rotating shaft and the water mixing valve.

Use including the embodiment of the utility model provides a during the tap of the control mechanism of tap valve body, under tap is in the closed condition, when the user applys forward drive power to the control mechanism's of this tap valve body handle, this handle mechanism 204 rotates predetermined angle for this pivot 2031 earlier, through this spacing portion 2032 block, this handle mechanism 204 is spacing by this spacing portion 2032, then, this pivot 2031 and this handle mechanism 204 drive the case motion of mixing the water valve in this tap jointly, thereby make the valve of this mixing water valve open, realize tap and go out water, when continuing forward turning handle, this handle mechanism 204 and this pivot 2031 rotate simultaneously, thereby the case that drives this mixing water valve through the gear rotates, thereby adjust the play water flow and the temperature regulation of the hot and cold water flow volume of mixing the water valve. When the faucet is in a water outlet state, when a user applies a reverse driving force to the handle of the control mechanism of the faucet valve body, the handle mechanism 204 rotates reversely by a preset angle relative to the rotating shaft 2031, the handle mechanism 204 is limited by the limiting portion 2032 by the blocking of the limiting portion 2032, and then the base 203 and the handle mechanism 204 drive the valve element of the mixing valve in the faucet to move together, so that the valve of the mixing valve is closed.

In the embodiment of the present invention, referring to fig. 22, the communication assembly 202 may include a communication module and a signal detection module;

the signal detection module is respectively connected with the self-generating device 201 and the communication module;

the signal detection module is configured to send a first trigger signal or a second trigger signal to the communication module if the first electrical signal or the second electrical signal output by the self-power generation device 201 is detected;

the communication module is configured to be capable of issuing the corresponding first control signal or the second control signal in response to the first trigger signal or the second trigger signal.

In a specific embodiment, the communication assembly 202 may further include a rectifying module and an energy storage module, where the rectifying module is connected to the energy storage module and then connected between the self-generating device 201 and the communication module, the rectifying module is configured to rectify the first electrical signal or the second electrical signal output by the self-generating device 201, and the energy storage module is configured to store rectified electrical energy so as to supply power to the communication module.

Similar to the embodiments described above, the specific implementation of the signal detection module, the rectification module and the energy storage module in the embodiments can also be shown with reference to fig. 22. For a specific implementation process, reference may be made to the detailed description in the foregoing embodiments, which is not described herein again.

Referring to fig. 32-48, the present invention provides an embodiment of a control mechanism for a faucet valve, which includes: a self-generating device 211, a communication module 212, a drive support mechanism 213, and a handle operation mechanism 214;

the self-generating device 211 is electrically connected with the communication component 212;

the self-generating device 211 is fixed to the handle operating mechanism 214;

the handle operating mechanism 214 is movably connected with the driving support mechanism 213;

the handle operating mechanism 214 is arranged and adapted to be displaced relative to the driving support mechanism 213 in response to a first-direction driving force or a second-direction driving force to control the self-generating device 211 to output a first electric signal or a second electric signal to the communication assembly 212;

the communication component 212 is arranged and adapted to be able to issue a corresponding first or second control signal in response to the first or second electrical signal.

The embodiment of the utility model provides a control mechanism of tap valve body can be used for controlling tap's the case that mixes the water valve and open or close to realize tap play water control. The first control signal may be a faucet on signal, and the second control signal may be a faucet off signal. Or, the first control signal is a faucet closing signal, and the second control signal is a faucet opening signal.

The embodiment of the utility model provides a control mechanism of tap valve body, it produces the displacement for drive supporting mechanism 213 motion from power generation facility 211 to drive through handle operating device 214, realize triggering from power generation facility 211, and then trigger communication subassembly 212 and send first control signal or second control signal, signal connection through tap and signal reception equipment, can acquire tap and still be the off-state for going out the water state according to this first control signal and second control signal with realizing signal reception equipment, and then signal reception equipment can carry out corresponding action according to tap's state, thereby guarantee tap's play water stability.

The embodiment of the utility model provides an among the control mechanism of tap valve body, handle operating device 214 with swing joint between drive supporting mechanism 213 can be the hub connection. Specifically, the drive support mechanism 213 may include a rotating shaft 2131, and the handle operating mechanism 214 may be connected to the drive support mechanism 213 through a shaft. In order to ensure that the rotation angle of the handle operating mechanism 214 does not exceed a necessary limit, the drive support mechanism 213 may be provided with a stopper portion 2132, the stopper portion 2132 may limit the rotation displacement of the handle operating mechanism 214 about the rotation shaft 2131 by 0.5 ° to 10 °, and the rotation angle of the handle operating mechanism 214 about the rotation shaft 2131 may be always within a predetermined angle range.

The following describes in detail a specific implementation manner of the control mechanism of the faucet valve body according to the embodiments of the present invention, through several specific embodiments:

referring to fig. 32 and 33, in an embodiment of the control mechanism of the faucet valve body provided in the present invention, the self-generating device 211 may be a power generating device in the prior art, for example, a magnetoelectric pulse power generating device, and the self-generating device 211 includes a driving component 21113; the drive support mechanism 213 is provided with a drive unit 2133; the driving assembly 21113 is configured and adapted to move relative to the driving portion 2133 in response to the first direction driving force or the second direction driving force to trigger the self-generating device 211 to output the first electric signal or the second electric signal. For example, the driving assembly 21113 of the self-generating device 211 may include an elastic reed 211133, and since the driving portion 2133 obstructs the elastic reed 211133, the driving assembly 21113 is adapted to elastically deform the elastic reed 211133 in response to the first direction driving force or the second direction driving force to control the self-generating device 211 to convert mechanical energy into electrical energy and output the first electrical signal or the second electrical signal.

The embodiment of the utility model provides an in, this tap can be lift-up tap, and when this handle mechanism can rotate for this base promptly, this handle mechanism's direction of motion is upwards or downstream, for example when tap is opened to needs, handle mechanism upwards rotates, and when tap was closed to needs, handle mechanism rotates downwards, and at this moment, this first direction drive power is promptly for applying the ascending effort in handle mechanism, and this second direction drive power is promptly for applying the decurrent effort in handle mechanism. Of course, according to the actual use requirement of the faucet, the handle mechanism may be rotated downward when the faucet is opened, and the handle mechanism may be rotated upward when the faucet is closed, where the first direction driving force is the downward force applied to the handle mechanism, and the second direction driving force is the upward force applied to the handle mechanism.

The embodiment of the utility model provides an in, this from power generation facility 211 can also adopt the self-generating motor of other types among the prior art, for example, piezoceramics generator or other can be with the generator of mechanical energy conversion for the electric energy. Certainly, when the piezoelectric ceramic generator or other types of self-generating motors are adopted, the structural relationship between the driving portion 2133 and the self-generating device 211 can also be adaptively adjusted according to the structural characteristics of the self-generating motor, for example, when the piezoelectric ceramic generator is adopted, because the driving component 21113 of the piezoelectric ceramic generator usually comprises an elastic sheet arranged above the piezoelectric ceramic sheet, when the elastic sheet responds to the first-direction driving force or the second-direction driving force, because the driving portion 2133 limits the movement of the elastic sheet, the elastic sheet can be elastically deformed, so that the elastic potential energy of the elastic sheet acts on the elastic piezoelectric ceramic sheet of the piezoelectric ceramic generator, and the first electric signal or the second electric signal is output.

The embodiment of the utility model provides a from generating motor still includes can rectifier module (for example rectifier bridge), voltage conversion module (for example DC-DC) etc. general peripheral circuit, be used for with the electric energy conversion that generates from generating motor can be for the electric energy of communication module 212 energy supply.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, as shown in fig. 33, the handle operating mechanism 214 may include a housing 2141 and an upper cover 2142 that are fixedly connected; and the housing 2141 and the upper cover 2142 enclose a receiving space, the self-generating device 211 and the communication module 212 are received in the receiving space, and the driving part 2133 at least partially extends into the receiving space, so as to cooperate with the elastic spring 211133 of the self-generating device 211 to limit the movement of the elastic spring 211133. Specifically, the upper lid 2142 has an internal thread, the housing 2141 has an external thread, and the upper lid 2142 and the housing 2141 are screwed together. Of course, in the embodiment of the present invention, the connection mode between the upper cover 2142 and the housing 2141 may also adopt other fixing modes in the prior art, as long as the fixing connection between the upper cover 2142 and the housing 2141 can be realized, in the embodiment of the present invention, no specific limitation may be made to this.

The embodiment of the utility model provides an in, through arranging in the accommodation space that this casing 2141 and upper cover 2142 enclose from power generation facility 211 and communication module 212, in the tap after the reassembly, realize keeping apart the control mechanism of tap valve body and the lower part water route of tap, the water of avoiding flowing through tap causes the damage to this from power generation facility 211 and communication module 212.

In order to facilitate the arrangement of the self-generating device 211 and the communication assembly 212 in the accommodating space, save space and realize the miniaturization of a control mechanism of the faucet valve body, the communication assembly 212 is arranged above the self-generating device 211. When the upper cover 2142 and the housing 2141 are fixedly connected, the communication module 212 is fixed between the upper cover 2142 and the self-generating device 211 through the upper cover 2142. In the embodiment of the present invention, referring to fig. 33, in order to ensure the sealing effect between the housing 2141 and the upper cover 2142, a first waterproof ring 2143 may be disposed between the housing 2141 and the upper cover 2142, so as to perform waterproof sealing. The first waterproof ring 2143 may be a rubber ring, a silicone ring, or a sealing ring made of other materials used in the prior art.

Referring to fig. 33 and 34, the handle operating mechanism 214 further includes a motor fixing bracket 2144, the motor fixing bracket 2144 is fixedly connected to the housing 2141, the motor fixing bracket 2144 is provided with at least one buckle 21441, and the self-generating device 211 is fastened to the motor fixing bracket 2144 through the buckle 21441. Certainly the embodiment of the utility model provides an in, this self-generating device 211 can also adopt other modes among the prior art to be fixed in this motor fixed bolster 2144, and specific implementation mode can refer to the detailed description among the prior art, no longer describes here.

In one embodiment, referring to fig. 33, the driving support mechanism 213 further includes a support portion 2134, the driving portion 2133 of the driving support mechanism 213 is fixed on the support portion 2134, the rotating shaft 2131 is disposed on the support portion 2134, the housing 2141 of the handle operating mechanism 214 is disposed with a rotating shaft accommodating portion 21411, and the rotating shaft accommodating portion 21411 is engaged with the rotating shaft 2131. Specifically, as shown in fig. 34 and 35, the supporting portion 2134 may include a shift lever 21341, the driving portion 2133 may include a shift element 21331, and the shift element 21331 may be fixedly connected to the shift lever 21341;

the poking piece 21331 is provided with a first limiting hole 213311, and an elastic reed 211133 of the self-generating device 211 at least partially extends into the first limiting hole 213311, so that the elastic reed 211133 can abut against the upper edge and/or the lower edge of the first limiting hole 213311;

when the elastic reed 211133 responds to the first direction driving force, the elastic reed 211133 abuts against the lower edge of the first limiting hole 213311 to generate elastic deformation so as to control the self-generating device 211 to output the first electric signal, and when the elastic reed 211133 responds to the second direction driving force, the elastic reed 211133 abuts against the upper edge of the first limiting hole 213311 to generate elastic deformation so as to control the self-generating device 211 to output the second electric signal.

In the embodiment of the present invention, by implementing the driving portion 2133 as the stirring member 21331, and placing the elastic reed 211133 of the driving component 21113 of the self-generating device 211 in the first limiting hole 213311 of the stirring member 21331, when the handle operating mechanism 214 of the faucet is operated, the self-generating device 211 generates displacement in response to the first direction driving force or the second direction driving force, because the stirring member 21331 limits the movement of the elastic reed 211133, the elastic reed 211133 is forced to generate elastic deformation, so that the self-generating device 211 converts mechanical energy into electrical energy, and outputs the first electrical signal or the second electrical signal.

Referring to fig. 35, the driving lever 21341 includes a rotating shaft 2131, and the outer surface of the rotating shaft 2131 is a spherical curved surface; the rotating shaft receiving portion 21411 is configured as an annular hole (not shown) on the housing 2141, and an upper end portion of the rotating shaft 2131 passes through the annular hole and extends into the receiving space, so that the housing 2141 can rotate up and down around the rotating shaft 2131.

In an embodiment, the toggle member 21331 includes a toggle piece 213312 and a toggle piece fixing portion 213313, the toggle piece 213312 is provided with the first limiting hole 213311, and the toggle piece fixing portion 213313 is provided with a first through hole (not shown);

the rotating shaft 2131 is a hollow shaft, the inner wall of the rotating shaft 2131 is provided with threads, and the pick fixing part 213313 is fixed with the rotating shaft 2131 in a threaded manner.

In one embodiment, referring to fig. 33, the driving support mechanism 213 further includes a lever cover 21342, the lever cover 21342 is fixedly connected to the housing 2141, and the rotating shaft 2131 is fixed between the lever cover 21342 and the housing 2141, so as to movably connect the driving support mechanism 213 to the handle operating mechanism 214.

The embodiment of the utility model provides an among the control mechanism of tap valve body, this driving lever 21341 still including connect in case connecting portion 213411 of pivot 2131 lower extreme, the case of tap's muddy water valve is fixed in this case connecting portion 213411.

In one embodiment, the inner circumference of the valve core connecting portion 213411 may be a square, rectangle, triangle or other non-circular structure, and correspondingly, the cross section of the valve core of the mixing valve of the faucet may be a square, rectangle, triangle or other non-circular structure, so as to allow the valve core of the mixing valve to be accommodated in the valve core connecting portion 213411, thereby allowing the opening and closing of the mixing valve to be controlled by the control mechanism of the faucet valve body. The concrete structure of case and case connecting portion 213411 of muddy water valve can refer to the structure of the tap among the prior art, in the embodiment of the utility model, can not do specifically and restrict to this.

In one embodiment, a first predetermined gap is formed between a lower end surface of the lever cap 21342 and an upper end surface of the valve plug connecting portion 213411 to form the limiting portion 2132. When the handle of the faucet is operated, the handle operating mechanism 214 moves relative to the drive support mechanism 213 in response to the first direction driving force or the second direction driving force, and during the movement, when the lower end surface of the lever cap 21342 abuts against the upper end surface of the valve element connecting portion 213411, the handle operating mechanism 214 cannot rotate relative to the drive support mechanism 213 any more, so that the handle operating mechanism 214 is restrained.

When the faucet comprising the control mechanism of the faucet valve body provided by the embodiment of the present invention is used, when the faucet is in a closed state, and a user applies a first direction driving force to the handle of the control mechanism of the faucet valve body, the handle operating mechanism 214 drives the self-generating device 211 to rotate up and down by a predetermined angle relative to the driving support mechanism 213, the handle operating mechanism 214 is limited by the limiting portion 2132 by the blocking of the limiting portion 2132, then the driving support mechanism 213 and the handle operating mechanism 214 drive the spool of the mixing valve in the faucet together to move, so as to open the valve of the mixing valve, and realize the outlet of the faucet, when the handle is rotated left and right, the handle operating mechanism 214 and the driving support mechanism 213 rotate simultaneously, so as to drive the spool of the mixing valve to rotate, so as to adjust the outlet flow of the cold water and the hot water of the mixing valve, the outlet water temperature of the faucet can be adjusted. When the faucet is in a water outlet state, when a user applies a second-direction driving force to the handle of the control mechanism of the faucet valve body, the handle operating mechanism 214 rotates reversely by a preset angle relative to the driving support mechanism 213, the handle operating mechanism 214 is limited by the limiting portion 2132 by the blocking of the limiting portion 2132, and then the driving support mechanism 213 and the handle operating mechanism 214 together drive the valve element of the mixing valve in the faucet to move up and down, so that the valve element of the mixing valve is closed.

In one embodiment, as shown with reference to FIG. 33, a first washer 2135 is disposed at the connection of the shifter cap 21342 to the annular aperture. The embodiment of the present invention provides an embodiment, when the handle operating mechanism 214 rotates relative to the rotating shaft 2131 through the first gasket 2135, the water flowing through the faucet is prevented from entering the accommodating space of the control mechanism of the faucet valve body through the gap between the driving lever 21341 and the housing 2141, resulting in the damage of the self-generating device 211 or the communication module 212. The first gasket 2135 may be a rubber ring, a silicone ring, or a sealing ring made of other materials as used in the prior art.

In the embodiment of the present invention, referring to fig. 36, the communication component 212 may include a communication module and a signal detection module;

the signal detection module is respectively connected with the self-generating device 211 and the communication module;

the signal detection module is configured to send a first trigger signal or a second trigger signal to the communication module if the first electrical signal or the second electrical signal output by the self-generating device 211 is detected;

the communication module is arranged and adapted to be able to issue the corresponding first control signal or the second control signal in response to the first trigger signal or the second trigger signal.

In a specific embodiment, the communication component 212 may further include a rectifying module and an energy storage module, the rectifying module is connected to the self-generating device 211 and the communication module after being connected to the energy storage module, the rectifying module is configured to rectify the first electrical signal or the second electrical signal output by the self-generating device 211, and the energy storage module is configured to store the rectified electrical energy so as to supply power to the communication module. The specific implementation of the rectifying module and the energy storage module in this embodiment can be seen with reference to fig. 36. Of course, based on the example of fig. 36, a person skilled in the art may also implement the rectifying module and the energy storage module in other manners known in the art, and the specific implementation manner of the embodiment of the present invention may not be limited in particular.

Referring to fig. 36, the signal detection module includes a first set of acquisition components and a second set of acquisition components, where the first set of acquisition components specifically includes:

the diode D5 is used as an input signal rectifier, wherein the anode of the diode D5 is used as a first input end of the detection device and is connected with a first output port of the power generation device;

the cathode of the diode D5 is connected with one end of a resistor R2, wherein the other end of the resistor R2 is connected with one end of a resistor R4 and then is used as the output end of the detection device to be connected with the first control port of the processing device; the other end of the resistor R4 is grounded and forms a voltage division unit with the resistor R2;

a capacitor C3 may be connected in parallel between the diode D5 and the resistor R2, and the other end of the capacitor C3 is grounded to form a high-frequency filtering branch.

The second set of collection components specifically includes:

the diode D4 is used as an input signal rectifier, wherein the anode of the diode D4 is used as a second input end of the detection device and is connected with a second output port of the power generation device;

the cathode of the diode D4 is connected with one end of a resistor R1, wherein the other end of the resistor R1 is connected with one end of a resistor R3 and then is used as the output end of the detection device to be connected with the second control port of the processing device; the other end of the resistor R3 is grounded and forms a voltage division unit with the resistor R1;

a capacitor C2 may be connected in parallel between the diode D4 and the resistor R1, and the other end of the capacitor C2 is grounded to form a high-frequency filtering branch.

Supposing that, when the first electrical signal is output from the self-generating device 211, the polarity of the electrical energy at the input port of the signal detection module is negative, the capacitor C3 is charged without electrical energy, the first control signal output from the signal detection module is low level, meanwhile, the electrical energy generated from the self-generating device 211 reaches the energy storage module through rectification, the communication module obtains the electrical energy, and meanwhile, the first control signal of the signal detection module is read; when the second electrical signal is output from the power generation device 211, the polarity of the electrical energy at the input port of the signal detection module is positive, the capacitor C3 is charged, the second control signal output by the signal detection module is high level, meanwhile, the electrical energy generated from the power generation device 211 reaches the energy storage module through rectification, the communication module obtains the electrical energy, and meanwhile, the second control signal of the signal detection module is read. Certainly, when the first electrical signal is output from the self-generating device 211, the polarity of the electrical energy at the input port of the signal detection module is positive, and when the second electrical signal is output from the self-generating device 211, the polarity of the electrical energy at the input port of the signal detection module is negative. The above example is only one specific implementation manner of the signal detection module, and those skilled in the art can also implement the signal detection module by adopting other manners in the prior art based on the example of fig. 36, and the specific implementation manner may not be specifically limited in the embodiment of the present invention.

For further example, referring to fig. 37, the above-mentioned magnetoelectric pulse generating device may be a generator as shown in fig. 37, which is a single integral module comprising: a magnetically permeable assembly 21111, a coil assembly 21112, a magnet assembly 21114, and a drive assembly 21113. The magnetically permeable assembly 21111, the coil assembly 21112, the magnet assembly 21114 and the drive assembly 21113 are integrally connected to one another.

The magnetic conductive assembly 21111 includes a first magnetic conductive member 211111 and a second magnetic conductive member 211112, and the first magnetic conductive member 211111 is disposed opposite to the second magnetic conductive member 211112. The first magnetic conductive member 211111 is fixedly connected to one end of the second magnetic conductive member 211112 through a connecting member 211113, and an upper contact member 211114 and a lower contact member 211115 are respectively disposed above and below the other end of the first magnetic conductive member.

The coil assembly 21112 is disposed inside the magnetic conductive assembly 21111, the coil assembly 21112 including: securing structure 211123, magnetic core 211122, bobbin 211124, and coil 211121 surrounding said bobbin 211124; wherein the bobbin 211124 is hollow, and the coil 211121 is wound on the bobbin 211124; after passing through the bobbin 211124, the magnetic core 211122 has one end fixedly connected to the connecting member 211113 and the other end passing through the bobbin 211124 and inserted into the fixing structure 211123 and protruding out of the fixing structure 211123 to be placed between the upper contact and the lower contact to form a middle contact. The fixing structure 211123 is used for fixing the other end of the coil bobbin 211124 and the magnetic core 211122, and the coil 211121 can be electrically connected to the communication component 212.

The driving assembly 21113 includes two rotation shafts 211131 which are arranged oppositely, one ends of the two rotation shafts 211131 are connected through an installation frame 211132, the other ends of the two rotation shafts 211131 are respectively provided with a rotation portion, one ends of the first magnetic conductive member 211111 and the second magnetic conductive member 211112, which are close to the connecting member 211113, are respectively provided with a rotation hole, the rotation holes are adapted to the rotation portions, and the two rotation shafts 211131 are rotatably connected to the magnetic conductive assembly 21111 through the rotation portions. The side of the mounting bracket 211132 away from the coil 211121 is provided with a spring reed 211133, and the entire driving assembly 21113 can be driven to displace up and down by pressing the spring reed 211133.

The magnet assembly 21114 is disposed on the drive assembly 21113, the magnet assembly 21114 comprising: the magnet 211141, a first magnetic conductive plate 211142 and a second magnetic conductive plate 211143, wherein the magnet 211141 is disposed in a mounting groove disposed inside the mounting frame 211132, and the first magnetic conductive plate 211142 and the second magnetic conductive plate 211143 are disposed opposite to each other at two ends of the magnet 211141, which have different polarities; the driving assembly 21113 is configured to drive the magnet assembly 21114 to relatively displace with respect to the magnetic conductive assembly 21111, so as to generate inductive power.

When the above-mentioned magnetoelectric pulse generator is fixed on the motor fixing bracket 2144 and placed in the accommodating space, the end of the resilient reed 211133 is located in the first position-limiting hole 213311 of the toggle member 21331. When a user operates a handle of a control mechanism of the faucet valve body, the self-generating device 211 moves in response to the first direction driving force or the second direction driving force, and the elastic reed 211133 is forced to generate elastic deformation due to the operation limitation of the first limiting hole 213311 on the elastic reed 211133, so that the self-generating device 211 is controlled to convert mechanical energy into electric energy, and the first electric signal or the second electric signal is output.

Referring to fig. 36-41, in an embodiment of the control mechanism of the faucet valve body provided by the present invention, the self-generating device 211 can be a generating device in the prior art, for example, a magnetoelectric pulse generating device, and the self-generating device 211 includes a driving component 21113; the handle operating mechanism 214 is provided with a driving portion 2133; the driving portion 2133 is configured and adapted to respond to the first direction driving force or the second direction driving force to drive the driving assembly 21113, and trigger the self-generating device 211 to output the first electric signal or the second electric signal. For example, the driving assembly 21113 of the self-generating device 211 may include an elastic reed 211133, and if the driving portion 2133 responds to the first direction driving force or the second direction driving force, the elastic reed 211133 may be driven to be elastically deformed to control the self-generating device 211 to convert mechanical energy into electrical energy and output the first electrical signal or the second electrical signal.

The embodiment of the utility model provides an in, this tap can be lift-up tap, and when this handle mechanism can rotate for this base promptly, this handle mechanism's direction of motion is upwards or downstream, for example when tap is opened to needs, handle mechanism upwards rotates, and when tap was closed to needs, handle mechanism rotates downwards, and at this moment, this first direction drive power is promptly for applying the ascending effort in handle mechanism, and this second direction drive power is promptly for applying the decurrent effort in handle mechanism. Of course, according to the actual use requirement of the faucet, the handle mechanism may be rotated downward when the faucet is opened, and the handle mechanism may be rotated upward when the faucet is closed, where the first direction driving force is the downward force applied to the handle mechanism, and the second direction driving force is the upward force applied to the handle mechanism.

Similar to the descriptions in the foregoing embodiments, the self-generating device 211 in this embodiment may also adopt other types of self-generating motors in the prior art, and the detailed description of the specific implementation manner of the self-generating device may refer to the detailed descriptions in the foregoing embodiments, and is not repeated herein.

Similar to the description of the above embodiment, the specific structure of the magnetoelectric pulse generating device used in the present embodiment may be the magnetoelectric pulse generating device shown in fig. 37.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, the handle operating mechanism 214 may include a housing 2141 and an upper cover 2142 that are fixedly connected; the housing 2141 and the upper cover 2142 enclose an accommodation space, and the driving support mechanism 213 at least partially extends into the accommodation space enclosed by the housing 2141 and the upper cover 2142, so that the self-generating device 211 and the communication module 212 are accommodated in the accommodation space. Specifically, the upper lid 2142 has an internal thread, the housing 2141 has an external thread, and the upper lid 2142 and the housing 2141 are screwed together. Of course, in the embodiment of the present invention, the connection mode between the upper cover 2142 and the housing 2141 may also adopt other fixing modes in the prior art, as long as the fixing connection between the upper cover 2142 and the housing 2141 can be realized, in the embodiment of the present invention, no specific limitation may be made to this.

The embodiment of the utility model provides an in, through arranging in the accommodation space that this casing 2141 and upper cover 2142 enclose from power generation facility 211 and communication module 212, in the tap after the equipment, realize keeping apart the control mechanism of tap valve body and the lower part water route of tap, the water of avoiding flowing through tap causes the damage to this from power generation facility 211 and communication module 212.

In order to facilitate the arrangement of the self-generating device 211 and the communication assembly 212 in the accommodating space, save space and realize the miniaturization of a control mechanism of the faucet valve body, the communication assembly 212 is arranged above the self-generating device 211. When the upper cover 2142 and the housing 1 are fixedly connected, the communication module 212 is fixed between the upper cover 2142 and the self-generating device 211 through the upper cover 2142. The embodiment of the utility model provides an in, in order to guarantee the sealed effect between casing 2141 and upper cover 2142, can set up first waterproof circle 2143 between this casing 2141 and upper cover 2142, carry out waterproof sealing. The first waterproof ring 2143 may be a rubber ring, a silicone ring, or a sealing ring made of other materials used in the prior art.

Referring to fig. 38 and 39, the handle operating mechanism 214 further includes a motor fixing bracket 2144, the motor fixing bracket 2144 is fixedly connected to the housing 2141, the motor fixing bracket 2144 is provided with at least one buckle 21441, and the self-generating device 211 is fastened to the motor fixing bracket 2144 through the buckle 21441. Certainly the embodiment of the utility model provides an in, this self-generating device 211 can also adopt other modes among the prior art to be fixed in this motor fixed bolster 2144, and specific implementation mode can refer to the detailed description among the prior art, no longer describes here.

In one embodiment, referring to fig. 39, the driving support mechanism 213 further includes a support portion 2134, the driving portion 2133 of the driving support mechanism 213 is fixed on the support portion 2134, the rotating shaft 2131 is disposed on the support portion 2134, the housing 2141 of the handle operating mechanism 214 is disposed with a rotating shaft accommodating portion 21411, and the rotating shaft accommodating portion 21411 is engaged with the rotating shaft 2131. Specifically, as shown in fig. 38 to 41, the supporting portion 2134 may include a shift lever 21341, the driving portion 2133 may include a shift element 21331, and the shift element 21331 may be fixedly connected to the shift lever 21341;

the poking piece 21331 is provided with a first limiting hole 213311, and an elastic reed 211133 of the self-generating device 211 at least partially extends into the first limiting hole 213311, so that the elastic reed 211133 can abut against the upper edge and/or the lower edge of the first limiting hole 213311;

when the elastic reed 211133 responds to the first direction driving force to move, the elastic reed 211133 abuts against the lower edge of the first limiting hole 213311 to generate elastic deformation so as to control the self-generating device 211 to output the first electric signal, and when the elastic reed 211133 responds to the second direction driving force to move, the elastic reed 211133 abuts against the upper edge of the first limiting hole 213311 to generate elastic deformation so as to control the self-generating device 211 to output the second electric signal.

In the embodiment of the present invention, by implementing the driving portion 2133 as the stirring member 21331, and placing the elastic reed 211133 of the driving component 21113 of the self-generating device 211 in the first limiting hole 213311 of the stirring member 21331, when the handle operating mechanism 214 of the faucet is operated, the self-generating device 211 generates displacement in response to the first direction driving force or the second direction driving force, because the stirring member 21331 limits the movement of the elastic reed 211133, the elastic reed 211133 is forced to generate elastic deformation, so that the self-generating device 211 converts mechanical energy into electrical energy, and outputs the first electrical signal or the second electrical signal.

Referring to fig. 41, the shift lever 21341 includes a rotating shaft 2131, the rotating shaft accommodating portion 21411 is disposed as at least one rotating shaft accommodating hole 214111 in the housing 2141, and the rotating shaft 2131 penetrates through the rotating shaft accommodating hole 214111, so that the housing 2141 can rotate around the rotating shaft 2131 up and down.

In one embodiment, referring to fig. 39, the shifting member 21331 includes a transmission pin 213314, the transmission pin 213314 and the rotating shaft 2131 are respectively disposed at two ends of the shifting lever 21341, and the transmission pin 213314 is disposed with the first limiting hole 213311;

the housing 2141 is provided with a transfer pin receiving hole (not shown) through which an upper end portion of the transfer pin 213314 passes, protruding into the receiving space.

Referring to fig. 39, the housing 2141 is symmetrically provided with two hinge receiving holes 214111 at a side thereof away from the handle of the handle operating mechanism 214, the hinge 2131 of the handle operating mechanism 214 penetrates the two hinge receiving holes 214111, the housing 2141 is provided with a transfer pin receiving hole at a side thereof close to the handle, and an upper end of the transfer pin 213314 penetrates the transfer pin receiving hole and extends into the receiving space. When the handle operating mechanism 214 of the faucet is operated, the self-generating device 211 is displaced in response to the first direction driving force or the second direction driving force, and since the rotating shaft 2131 is disposed at a side away from the handle, the handle operating mechanism 214 rotates a small angle relative to the rotating shaft accommodating hole 214111, so that the elastic spring 211133 is elastically deformed, and the self-generating device 211 converts mechanical energy into electrical energy and outputs the first electrical signal or the second electrical signal.

In one embodiment, referring to fig. 39, the support portion 2134 further includes a sealing cap 21343, the sealing cap 21343 is fixed to an outer wall of the transmission pin receiving hole, and the transmission pin 213314 passes through the sealing cap 21343.

In an embodiment, referring to fig. 39, the transmission pin 213314 has a first step portion 2133141, a second predetermined gap is formed between the first step portion 2133141 and the housing 2141, and a third predetermined gap is formed between the lower end surface of the sealing cover 21343 and the upper end surface of the shift lever 21341 to form the limiting portion 2132. When the handle of the faucet is operated, the handle operating mechanism 214 moves upwards relative to the driving support mechanism 213 in response to the first direction driving force, and during the movement, when the upper end surface of the shift lever 21341 abuts against the lower end surface of the sealing cover 21343, the handle operating mechanism 214 cannot rotate relative to the driving support mechanism 213 any more, so that the limit of the handle operating mechanism 214 is realized; in response to the second direction driving force, the handle operating mechanism 214 moves downward relative to the driving support mechanism 213, and during the movement, when the first stepped portion 2133141 of the transmission pin 213314 abuts against the housing 2141, the handle operating mechanism 214 cannot rotate relative to the driving support mechanism 213 any more, so that the handle operating mechanism 214 is limited.

In one embodiment, a second waterproof ring 2136 is disposed between the transfer pin receiving hole and the seal cover 21343. The embodiment of the utility model provides an in, can prevent through this waterproof circle 2136 that the water of flowing through tap from getting into the control mechanism's of this tap valve body accommodation space through the clearance between this transmission round pin 213314 and the casing 2141 when handle operating device 214 rotates for this pivot 2131, cause the damage from power generation facility 211 or communication module 212. The second waterproof ring 2136 may be a rubber ring, a silica gel ring, or a sealing ring made of other materials used in the prior art.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, as shown in fig. 39, the lower end of the shift lever 21341 has a valve plug connecting portion 213411, and the valve plug of the mixing valve of the faucet is fixed to the valve plug connecting portion 213411.

In one embodiment, the inner periphery of the valve core connecting portion 213411 may be a square, rectangle, triangle or other non-circular structure, and correspondingly, the cross section of the valve core of the mixing valve of the faucet is a square, rectangle, triangle or other non-circular structure, so that the valve core of the mixing valve is accommodated in the valve core connecting portion 213411, and the opening and closing of the mixing valve is controlled by the control mechanism of the faucet valve body. The concrete structure of case and case connecting portion 213411 of muddy water valve can refer to the structure of the tap among the prior art, in the embodiment of the utility model, can not do specifically and restrict to this.

When the faucet comprising the control mechanism of the faucet valve body provided by the embodiment of the present invention is used, when the faucet is in a closed state, and a user applies a first direction driving force to the handle of the control mechanism of the faucet valve body, the handle operating mechanism 214 drives the self-generating device 211 to rotate up and down by a predetermined angle relative to the driving support mechanism 213, the handle operating mechanism 214 is limited by the limiting portion 2132 by the blocking of the limiting portion 2132, then the driving support mechanism 213 and the handle operating mechanism 214 drive the spool of the mixing valve in the faucet together to move, so as to open the valve of the mixing valve, and realize the outlet of the faucet, when the handle is rotated left and right, the handle operating mechanism 214 and the driving support mechanism 213 rotate simultaneously, so as to drive the spool of the mixing valve to rotate, so as to adjust the outlet flow of the cold water and the hot water of the mixing valve, the outlet water temperature of the faucet can be adjusted. When the faucet is in a water outlet state, when a user applies a second-direction driving force to the handle of the control mechanism of the faucet valve body, the handle operating mechanism 214 rotates reversely by a preset angle relative to the driving support mechanism 213, the handle operating mechanism 214 is limited by the limiting portion 2132 by the blocking of the limiting portion 2132, and then the driving support mechanism 213 and the handle operating mechanism 214 together drive the valve element of the mixing valve in the faucet to move up and down, so that the valve element of the mixing valve is closed.

In the embodiment of the present invention, referring to fig. 36, the communication component 212 may include a communication module and a signal detection module;

the signal detection module is respectively connected with the self-generating device 211 and the communication module;

the signal detection module is configured to send a first trigger signal or a second trigger signal to the communication module if the first electrical signal or the second electrical signal output by the self-generating device 211 is detected;

the communication module is arranged and adapted to be able to issue the corresponding first control signal or the second control signal in response to the first trigger signal or the second trigger signal.

In a specific embodiment, the communication component 212 may further include a rectifying module and an energy storage module, the rectifying module is connected to the self-generating device 211 and the communication module after being connected to the energy storage module, the rectifying module is configured to rectify the first electrical signal or the second electrical signal output by the self-generating device 211, and the energy storage module is configured to store the rectified electrical energy so as to supply power to the communication module.

Similar to the embodiments described above, the specific implementation of the signal detection module, the rectification module and the energy storage module in the embodiments can also be shown with reference to fig. 36. For a specific implementation process, reference may be made to the detailed description in the foregoing embodiments, which is not described herein again.

Referring to fig. 42-45, in an embodiment of the control mechanism of the faucet valve body provided in the present invention, the self-generating device 211 may be a power generating device in the prior art, for example, a magnetoelectric pulse power generating device, and the self-generating device 211 includes a driving component 21113; the handle operating mechanism 214 is provided with a driving portion 2133; the driving portion 2133 is configured and adapted to respond to the first direction driving force or the second direction driving force to drive the driving assembly 21113, and trigger the self-generating device 211 to output the first electric signal or the second electric signal. For example, the driving assembly 21113 of the self-generating device 211 may include an elastic reed 211133, and if the driving portion 2133 responds to the first direction driving force or the second direction driving force, the elastic reed 211133 may be driven to be elastically deformed to control the self-generating device 211 to convert mechanical energy into electrical energy and output the first electrical signal or the second electrical signal.

The embodiment of the utility model provides an in, this tap can be rotation type tap, and when this handle mechanism can rotate for this base promptly, this handle mechanism's direction of motion is left or right motion, for example when tap is opened to needs, handle mechanism rotates to the left, and when tap was closed to needs, handle mechanism rotated to the right, and at this moment, this first direction drive power is the effort left that is applyed in handle mechanism promptly, and this second direction drive power is the effort right that is applyed in handle mechanism promptly. Of course, according to the actual usage requirement of the faucet, the handle mechanism may be rotated to the right when the faucet is opened, and the handle mechanism may be rotated to the left when the faucet is closed, at this time, the first direction driving force is the right acting force applied to the handle mechanism, and the second direction driving force is the left acting force applied to the handle mechanism.

Similar to the descriptions in the foregoing embodiments, the self-generating device 211 in this embodiment may also adopt other types of self-generating motors in the prior art, and the detailed description of the specific implementation manner of the self-generating device may refer to the detailed descriptions in the foregoing embodiments, and is not repeated herein.

Similar to the description of the above embodiment, the specific structure of the magnetoelectric pulse generating device used in the present embodiment may be the magnetoelectric pulse generating device shown in fig. 37.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, as shown in fig. 42 and 43, the handle operating mechanism 214 may include a housing 2141 and an upper cover 2142 that are fixedly connected; the housing 2141 and the upper cover 2142 enclose an accommodating space, and the driving support mechanism 213 at least partially extends into the accommodating space enclosed by the housing 2141 and the upper cover 2142, so that the self-generating device 211 and the communication module 212 are accommodated in the accommodating space. Specifically, the upper lid 2142 has an internal thread, the housing 2141 has an external thread, and the upper lid 2142 and the housing 2141 are screwed together. Of course, in the embodiment of the present invention, the connection mode between the upper cover 2142 and the housing 2141 may also adopt other fixing modes in the prior art, as long as the fixing connection between the upper cover 2142 and the housing 2141 can be realized, in the embodiment of the present invention, no specific limitation may be made to this.

The embodiment of the utility model provides an in, through arranging in the accommodation space that this casing 2141 and upper cover 2142 enclose from power generation facility 211 and communication module 212, in the tap after the equipment, realize keeping apart the control mechanism of tap valve body and the lower part water route of tap, the water of avoiding flowing through tap causes the damage to this from power generation facility 211 and communication module 212.

In order to facilitate the arrangement of the self-generating device 211 and the communication assembly 212 in the accommodating space, save space and realize the miniaturization of a control mechanism of the faucet valve body, the communication assembly 212 is arranged above the self-generating device 211. When the upper cover 2142 and the housing 2141 are fixedly connected, the communication module 212 is fixed between the upper cover 2142 and the self-generating device 211 by the upper cover 2142. The embodiment of the utility model provides an in, in order to guarantee the sealed effect between casing 2141 and upper cover 2142, can set up first waterproof circle 2143 between this casing 2141 and upper cover 2142, carry out waterproof sealing. The first waterproof ring 2143 may be a rubber ring, a silicone ring, or a sealing ring made of other materials used in the prior art.

Referring to fig. 42 and 43, the handle operating mechanism 214 further includes a motor fixing bracket 2144, the motor fixing bracket 2144 is fixedly connected to the housing 2141, the motor fixing bracket 2144 is provided with at least one buckle 21441, and the self-generating device 211 is fastened to the motor fixing bracket 2144 through the buckle 21441. For example, the motor fixing bracket 2144 is symmetrically provided with two buckles 21441, and the self-generating device 211 is clamped and fixed by the two buckles 21441. Certainly the embodiment of the utility model provides an in, this self-generating device 211 can also adopt other modes among the prior art to be fixed in this motor fixed bolster 2144, and specific implementation mode can refer to the detailed description among the prior art, no longer describes here.

In one embodiment, referring to fig. 42 and 43, the driving support mechanism 213 further includes a support portion 2134, the driving portion 2133 of the driving support mechanism 213 is fixed on the support portion 2134, the rotating shaft 2131 is disposed on the support portion 2134, the housing 2141 of the handle operating mechanism 214 is disposed with a rotating shaft accommodating portion 21411, and the rotating shaft accommodating portion 21411 is engaged with the rotating shaft 2131.

Specifically, as shown in fig. 42 and 43, the support portion 2134 may include the rotating shaft 2131, the driving portion 2133 may include a toggle piece 21331, and the toggle piece 21331 may be fixedly connected to the rotating shaft 2131;

the toggle piece 21331 is provided with a first long slot 213315 which forms a preset inclination angle with the horizontal plane, and the elastic reed 211133 is at least partially clamped in the first long slot 213315;

the elastic reed 211133 is adapted to generate torsional deformation by forward motion along the first long slot 213315 in response to the first direction driving force to control the self-generating device 211 to output the first electric signal, and generate torsional deformation by reverse motion along the first long slot 213315 in response to the second direction driving force to control the self-generating device 211 to output the second electric signal.

In the embodiment of the present invention, the driving portion 2133 is implemented as the stirring member 21331, and the elastic reed 211133 of the driving component 21113 of the self-generating device 211 is placed in the first limiting hole 213311 of the stirring member 21331, when the handle operating mechanism 214 of the faucet is operated, the self-generating device 211 generates displacement in response to the first direction driving force or the second direction driving force, because the stirring member 21331 limits the movement of the elastic reed 211133, the elastic reed 211133 is forced to generate elastic deformation, so that the self-generating device 211 converts mechanical energy into electric energy, and outputs the first electric signal or the second electric signal.

In the embodiment of the present invention, the rotation shaft receiving portion 21411 is configured as an annular hole (not shown in the figure) on the housing 2141, and the upper end of the rotation shaft 2131 passes through the annular hole and extends into the receiving space, so that the housing 2141 can rotate around the rotation shaft 2131 up and down.

In one embodiment, referring to fig. 42, the toggle member 21331 includes a toggle piece 213312 and a toggle piece fixing portion 213313, the toggle piece 213312 is provided with the first long slot hole 213315, and the toggle piece fixing portion 213313 is provided with a second through hole (not shown);

the rotating shaft 2131 is provided as a hollow shaft, the inner wall of the rotating shaft 2131 is provided with a thread, and a bolt is fixed to the inner wall of the rotating shaft 2131 through the second through hole, so that the plectrum fixing part 213313 is screwed and fixed to the rotating shaft 2131.

In a specific embodiment, the rotating shaft 2131 has a second step portion 21311, and a second gasket 2137 is disposed at a connection between the second step portion 21311 of the rotating shaft 2131 and the annular hole 214111. The embodiment of the present invention provides an embodiment, when the handle operating mechanism 214 rotates relative to the rotating shaft 2131 through the second gasket 2137, the water flowing through the faucet is prevented from entering the accommodating space of the control mechanism of the faucet valve body through the gap between the driving lever 21341 and the housing 2141, resulting in the damage of the self-generating device 211 or the communication module 212. The second gasket 2137 may be a rubber ring, a silicone ring, or a sealing ring made of other materials as used in the prior art.

In one embodiment, referring to fig. 44, the motor fixing bracket 2144 is provided with a dial receiving groove 21441, and the dial fixing portion 213313 of the dial 21331 is received in the dial receiving groove 21441. In one embodiment, a fourth predetermined gap is formed between two sides of the pick fixing portion 213313 and the pick receiving groove 21441 to form a limiting portion 2132 of the control mechanism of the faucet valve body. When the control mechanism of the faucet valve body is in the initial position, the pick fixing portion 213313 is disposed in the middle of the pick receiving groove 21441, the distance between the left and right sidewalls of the pick fixing portion 213313 and the pick receiving groove 21441 is equal, when the handle of the faucet is operated, the handle operating mechanism 214 horizontally rotates relative to the rotating shaft 2131 in response to the first direction driving force or the second direction driving force, and during the movement, when the sidewall of the pick fixing portion 213313 abuts against the pick receiving groove 21441, the handle operating mechanism 214 cannot rotate relative to the rotating shaft 2131 any more, thereby limiting the handle operating mechanism 214.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, referring to fig. 45, the driving lever 21341 further includes a valve plug connecting portion 213411 connected to the lower end of the rotating shaft 2131, and the valve plug of the mixing valve of the faucet is fixed to the valve plug connecting portion 213411.

Referring to fig. 45, the inner wall of the valve body connecting part 213411 of the rotating shaft 2131 may be provided with an internal gear 2134111, and an external gear may be provided corresponding to the valve body of the mixing valve of the faucet, so as to realize the gear connection between the mixing valve and the control mechanism of the faucet valve body.

When the faucet comprising the control mechanism of the faucet valve body provided by the embodiment of the present invention is used, when the faucet is in a closed state, and a user applies a first direction driving force to the handle of the control mechanism of the faucet valve body, the handle operating mechanism 214 drives the self-generating device 211 to rotate left and right by a predetermined angle relative to the driving support mechanism 213, the handle operating mechanism 214 is limited by the limiting portion 2132 by the blocking of the limiting portion 2132, then the driving support mechanism 213 and the handle operating mechanism 214 drive the spool of the mixing valve in the faucet together to move, so as to open the valve of the mixing valve, so as to realize water outlet of the faucet, when the handle is continuously rotated, the handle operating mechanism 214 and the driving support mechanism 213 rotate simultaneously, so as to drive the spool of the mixing valve to rotate, so as to adjust the water outlet flow of the cold water and the hot water of the mixing valve, the outlet water temperature of the faucet can be adjusted. When the faucet is in a water outlet state, when a user applies a second-direction driving force to the handle of the control mechanism of the faucet valve body, the handle operating mechanism 214 rotates reversely by a preset angle relative to the driving support mechanism 213, the handle operating mechanism 214 is limited by the limiting portion 2132 by the blocking of the limiting portion 2132, and then the driving support mechanism 213 and the handle operating mechanism 214 drive the valve element of the mixing valve in the faucet to rotate horizontally together, so that the valve element of the mixing valve is closed.

In the embodiment of the present invention, referring to fig. 36, the communication component 212 may include a communication module and a signal detection module;

the signal detection module is respectively connected with the self-generating device 211 and the communication module;

the signal detection module is configured to send a first trigger signal or a second trigger signal to the communication module if the first electrical signal or the second electrical signal output by the self-generating device 211 is detected;

the communication module is arranged and adapted to be able to issue the corresponding first control signal or the second control signal in response to the first trigger signal or the second trigger signal.

In a specific embodiment, the communication component 212 may further include a rectifying module and an energy storage module, the rectifying module is connected to the self-generating device 211 and the communication module after being connected to the energy storage module, the rectifying module is configured to rectify the first electrical signal or the second electrical signal output by the self-generating device 211, and the energy storage module is configured to store the rectified electrical energy so as to supply power to the communication module.

Similar to the embodiments described above, the specific implementation of the signal detection module, the rectification module and the energy storage module in the embodiments can also be shown with reference to fig. 36. For a specific implementation process, reference may be made to the detailed description in the foregoing embodiments, which is not described herein again.

Referring to fig. 46-48, in an embodiment of the control mechanism of the faucet valve body provided in the present invention, the self-generating device 211 may be a power generating device in the prior art, for example, a magnetoelectric pulse power generating device, and the self-generating device 211 includes a driving component 21113; the handle operating mechanism 214 is provided with a driving portion 2133; the driving portion 2133 is configured and adapted to respond to the first direction driving force or the second direction driving force to drive the driving assembly 21113, and trigger the self-generating device 211 to output the first electric signal or the second electric signal. For example, the driving assembly 21113 of the self-generating device 211 may include an elastic reed 211133, and if the driving portion 2133 responds to the first direction driving force or the second direction driving force, the elastic reed 211133 may be driven to be elastically deformed so as to control the self-generating device 211 to convert mechanical energy into electrical energy and output the first electrical signal or the second electrical signal.

The embodiment of the utility model provides an in, this tap can be rotation type tap, and when this handle mechanism can rotate for this base promptly, this handle mechanism's direction of motion is left or right motion, for example when tap is opened to needs, handle mechanism is to the left turn, and when tap was closed to needs, handle mechanism rotated right, and at this moment, this first direction drive power is for applying the effort left in handle mechanism promptly, and this second direction drive power is for applying the effort right in handle mechanism promptly. Of course, according to the actual usage requirement of the faucet, the handle mechanism may be rotated to the right when the faucet is opened, and the handle mechanism may be rotated to the left when the faucet is closed, at this time, the first direction driving force is the right acting force applied to the handle mechanism, and the second direction driving force is the left acting force applied to the handle mechanism.

Similar to the descriptions in the foregoing embodiments, the self-generating device 211 in this embodiment may also adopt other types of self-generating motors in the prior art, and the detailed description of the specific implementation manner of the self-generating device may refer to the detailed descriptions in the foregoing embodiments, and is not repeated herein.

Similar to the description of the above embodiment, the specific structure of the magnetoelectric pulse generating device used in the present embodiment may be the magnetoelectric pulse generating device shown in fig. 37.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, as shown in fig. 47 and 48, the handle operating mechanism 214 may include a housing 2141 and an upper cover 2142 that are fixedly connected; the housing 2141 and the upper cover 2142 enclose an accommodation space, and the driving support mechanism 213 at least partially extends into the accommodation space enclosed by the housing 2141 and the upper cover 2142, so that the self-generating device 211 and the communication module 212 are accommodated in the accommodation space. Specifically, the upper lid 2142 has an internal thread, the housing 2141 has an external thread, and the upper lid 2142 and the housing 2141 are screwed together. Of course, in the embodiment of the present invention, the connection mode between the upper cover 2142 and the housing 2141 may also adopt other fixing modes in the prior art, as long as the fixing connection between the upper cover 2142 and the housing 2141 can be realized, in the embodiment of the present invention, no specific limitation may be made to this.

The embodiment of the utility model provides an in, through arranging in the accommodation space that this casing 2141 and upper cover 2142 enclose from power generation facility 211 and communication module 212, in the tap after the equipment, realize keeping apart the control mechanism of tap valve body and the lower part water route of tap, the water of avoiding flowing through tap causes the damage to this from power generation facility 211 and communication module 212.

In order to facilitate the arrangement of the self-generating device 211 and the communication assembly 212 in the accommodating space, save space and realize the miniaturization of a control mechanism of the faucet valve body, the communication assembly 212 is arranged above the self-generating device 211. When the upper cover 2142 and the housing 2141 are fixedly connected, the communication module 212 is fixed between the upper cover 2142 and the self-generating device 211 by the upper cover 2142. The embodiment of the utility model provides an in, in order to guarantee the sealed effect between casing 2141 and upper cover 2142, can set up first waterproof circle 2143 between this casing 2141 and upper cover 2142, carry out waterproof sealing. The first waterproof ring 2143 may be a rubber ring, a silicone ring, or a sealing ring made of other materials used in the prior art.

Referring to fig. 46 and 47, the handle operating mechanism 214 further includes a motor fixing bracket 2144, the motor fixing bracket 2144 is fixedly connected to the housing 2141, the motor fixing bracket 2144 is provided with at least one buckle 21441, and the self-generating device 211 is fastened to the motor fixing bracket 2144 through the buckle 21441. For example, the motor fixing bracket 2144 is symmetrically provided with two buckles 21441, and the self-generating device 211 is clamped and fixed by the two buckles 21441. Certainly the embodiment of the utility model provides an in, this from power generation facility 211 can also adopt other modes among the prior art to be fixed in this motor fixed bolster 2144, and concrete implementation can refer to the detailed description among the prior art, and no longer gives details here.

In one embodiment, referring to fig. 46 and 47, the driving support mechanism 213 further includes a support portion 2134, the driving portion 2133 of the driving support mechanism 213 is fixed on the support portion 2134, the rotating shaft 2131 is disposed on the support portion 2134, the housing 2141 of the handle operating mechanism 214 is disposed with a rotating shaft accommodating portion 21411, and the rotating shaft accommodating portion 21411 is engaged with the rotating shaft 2131.

Specifically, as shown in fig. 46 and 47, the support portion 2134 may include the rotating shaft 2131, the driving portion 2133 may include a toggle piece 21331, and the toggle piece 21331 may be fixedly connected to the rotating shaft 2131;

the toggle piece 21331 is provided with a second limit hole 213316 which is perpendicular to the horizontal plane, and the elastic spring 211133 at least partially extends into the second limit hole 213316;

the elastic reed 211133 is adapted to elastically deform in response to the first direction driving force, abutting against a first edge of the second limiting hole 213316, to control the self-generating device 211 to output the first electric signal, and in response to the second direction driving force, abutting against a second edge of the second limiting hole 213316, to control the self-generating device 211 to output the second electric signal.

The embodiment of the utility model provides an in, through implementing this stirring portion as the stirring piece 21331 on this drive support portion 2134, be provided with the spacing hole 213316 of second that the perpendicular to horizontal plane set up on stirring piece 21331, and place this from generating unit 211's drive assembly 21113's elasticity reed 211133 in this spacing hole 213316 of second, when operating tap's handle operating device 214, from generating unit 211 responds to this first direction drive power or second direction drive power and produces the displacement, because this stirring piece 21331 has restricted the motion of elasticity reed 211133, force this elasticity reed 211133 to take place elastic deformation, thereby make from generating unit 211 convert mechanical energy into the electric energy, export this first electric signal or second electric signal.

In the embodiment of the present invention, the rotation shaft receiving portion 21411 is configured as an annular hole (not shown in the figure) on the housing 2141, and the upper end of the rotation shaft 2131 passes through the annular hole and extends into the receiving space, so that the housing 2141 can rotate around the rotation shaft 2131 up and down.

In one embodiment, the toggle member 21331 includes a toggle piece 213312 and a toggle piece fixing portion 213313, the toggle piece 213312 is provided with the second limiting hole 213316, and the toggle piece fixing portion 213313 is provided with a second through hole (not shown);

the rotating shaft 2131 is provided as a hollow shaft, the inner wall of the rotating shaft 2131 is provided with a thread, and a bolt is fixed to the inner wall of the rotating shaft 2131 through the second through hole, so that the plectrum fixing part 213313 is screwed and fixed to the rotating shaft 2131.

In a specific embodiment, the rotating shaft 2131 has a second step portion 21311, and a second gasket 2137 is disposed at a connection position of the second step portion 21311 of the rotating shaft 2131 and the annular hole. The embodiment of the present invention provides an embodiment, when the handle operating mechanism 214 rotates relative to the rotating shaft 2131 through the second gasket 2137, the water flowing through the faucet is prevented from entering the accommodating space of the control mechanism of the faucet valve body through the gap between the driving lever 21341 and the housing 2141, resulting in the damage of the self-generating device 211 or the communication module 212. The second gasket 2137 may be a rubber ring, a silicone ring, or a sealing ring made of other materials as used in the prior art.

In one embodiment, referring to fig. 48, the motor fixing bracket 2144 is provided with a pick receiving groove 21441, and the pick fixing portion 213313 of the pick 21331 is received in the pick receiving groove 21441. In one embodiment, a fourth predetermined gap is formed between two sides of the pick fixing portion 213313 and the pick receiving groove 21441 to form a limiting portion 2132 of the control mechanism of the faucet valve body. When the control mechanism of the faucet valve body is in the initial position, the pick fixing portion 213313 is disposed in the middle of the pick receiving groove 21441, the distance between the left and right sidewalls of the pick fixing portion 213313 and the pick receiving groove 21441 is equal, when the handle of the faucet is operated, the handle operating mechanism 214 horizontally rotates relative to the rotating shaft 2131 in response to the first direction driving force or the second direction driving force, and during the movement, when the sidewall of the pick fixing portion 213313 abuts against the pick receiving groove 21441, the handle operating mechanism 214 cannot rotate relative to the rotating shaft 2131 any more, thereby limiting the handle operating mechanism 214.

In the control mechanism of the faucet valve body provided in the embodiment of the present invention, referring to fig. 45, the driving lever 21341 further includes a valve plug connecting portion 213411 connected to the lower end of the rotating shaft 2131, and the valve plug of the mixing valve of the faucet is fixed to the valve plug connecting portion 213411.

Referring to fig. 45, the inner wall of the valve body connecting part 213411 of the rotating shaft 2131 may be provided with an internal gear 2134111, and the valve body of the mixing valve of the faucet may be provided with an external gear corresponding thereto, so as to realize the gear connection between the mixing valve and the control mechanism of the faucet valve body.

When the faucet comprising the control mechanism of the faucet valve body provided by the embodiment of the present invention is used, when the faucet is in a closed state, and a user applies a first direction driving force to the handle of the control mechanism of the faucet valve body, the handle operating mechanism 214 drives the self-generating device 211 to rotate left and right by a predetermined angle relative to the driving support mechanism 213, the handle operating mechanism 214 is limited by the limiting portion 2132 by the blocking of the limiting portion 2132, then the driving support mechanism 213 and the handle operating mechanism 214 drive the spool of the mixing valve in the faucet together to move, so as to open the valve of the mixing valve, so as to realize water outlet of the faucet, when the handle is continuously rotated, the handle operating mechanism 214 and the driving support mechanism 213 rotate simultaneously, so as to drive the spool of the mixing valve to rotate, so as to adjust the water outlet flow of the cold water and the hot water of the mixing valve, the outlet water temperature of the faucet can be adjusted. When the faucet is in a water outlet state, when a user applies a second-direction driving force to the handle of the control mechanism of the faucet valve body, the handle operating mechanism 214 rotates reversely by a preset angle relative to the driving support mechanism 213, the handle operating mechanism 214 is limited by the limiting portion 2132 by the blocking of the limiting portion 2132, and then the driving support mechanism 213 and the handle operating mechanism 214 drive the valve element of the mixing valve in the faucet to rotate horizontally together, so that the valve element of the mixing valve is closed.

In the embodiment of the present invention, referring to fig. 36, the communication component 212 may include a communication module and a signal detection module;

the signal detection module is respectively connected with the self-generating device 211 and the communication module;

the signal detection module is configured to send a first trigger signal or a second trigger signal to the communication module if the first electrical signal or the second electrical signal output by the self-generating device 211 is detected;

the communication module is arranged and adapted to be able to issue the corresponding first control signal or the second control signal in response to the first trigger signal or the second trigger signal.

In a specific embodiment, the communication component 212 may further include a rectifying module and an energy storage module, the rectifying module is connected to the self-generating device 211 and the communication module after being connected to the energy storage module, the rectifying module is configured to rectify the first electrical signal or the second electrical signal output by the self-generating device 211, and the energy storage module is configured to store the rectified electrical energy so as to supply power to the communication module.

Similar to the embodiments described above, the specific implementation of the signal detection module, the rectification module and the energy storage module in the embodiments can also be shown with reference to fig. 36. For a specific implementation process, reference may be made to the detailed description in the foregoing embodiments, and details are not described here again.

The embodiment of the utility model provides an above-mentioned intelligent tap all has from the electricity generation, need not the battery, need not the advantage of maintaining. In addition, it is worth mentioning that: the structure and principle of the intelligent faucet in the above embodiments can be applied to the intelligent faucet in the water heater control system, and the present invention is not limited thereto in this respect.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This application is intended to cover any variations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

It will be understood that the present disclosure is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (25)

1. A wireless controller, comprising:

the device comprises a shell, a control unit and a control unit, wherein the shell is provided with a control position;

a communication module disposed within the housing;

the control part is matched with the control position and is suitable for being applied with a driving force to trigger the communication module to send out a control signal;

the sealing part is coupled with the at least one control part, at least part of the sealing part is arranged in the shell, and a sealing cavity is formed by the sealing part and at least part of the area of the shell; the communication module is arranged in the sealing cavity.

2. The wireless controller of claim 1, wherein the sealing portion is hermetically connected to or integrally formed with the at least one manipulation portion; and the control part at least partially protrudes out of the control position.

3. The wireless controller of claim 2, further comprising at least one buffer connection;

the sealing part is connected with the control part through the buffer connecting part;

the buffer connecting part is arranged to be capable of deforming along with the displacement of the control part, so that the control part is arranged in the control position in a telescopic mode.

4. The wireless controller according to claim 3, wherein the sealing portion, the buffer connecting portion, and the manipulation portion are integrally formed;

or the like, or, alternatively,

the buffer connecting part is respectively connected with the sealing part and the control part in a sealing manner.

5. The wireless controller of claim 2, wherein the housing comprises an upper shell and a lower shell, the upper shell and the lower shell enclosing a receiving cavity; at least part of the sealing part is arranged in the accommodating cavity and forms the sealing cavity with at least part of the area of the lower shell.

6. The wireless controller according to claim 5, wherein a waterproof part is further arranged around the sealing part, and a first pressing part matched with the waterproof part is arranged at the edge of the lower shell;

the waterproof part is attached to the first abutting part and fixedly abutted between the upper shell and the first abutting part.

7. The wireless controller of claim 6, wherein the waterproof portion is formed by the sealing portion extending outwardly; or the like, or, alternatively,

the waterproof part is connected with the sealing part in a sealing manner.

8. The wireless controller of claim 6, wherein the waterproof portion includes an abutting edge connected to an edge of the sealing portion and an attaching edge perpendicular to the abutting edge and extending toward the lower case;

the pressing eaves are arranged between the upper shell and the first pressing portion in a pressing mode, and the attaching eaves are attached to the outer surface of the first pressing portion.

9. The wireless controller according to claim 8, wherein a gap between the upper case and the first pressing portion is smaller than or equal to a thickness of the pressing eaves.

10. The wireless controller of any of claims 5-9, further comprising: the power generation module is arranged in the sealing cavity;

the control part is further arranged to control the power generation module to supply power to the communication module when a driving force is applied to enable the control part to displace from the accommodating cavity to the sealing cavity.

11. The wireless controller of claim 10, wherein the communication module comprises at least one signal unit and at least one detection switch;

the signal unit is respectively and electrically connected with the power generation module and the detection switch;

the control part responds to the driving force and controls the detection switch to switch on-off state to generate a detection signal;

the signal unit is configured to generate and externally transmit a preset control signal according to the detection signal.

12. The wireless controller according to claim 11, wherein the communication module comprises at least two detection switches, and the wireless controller comprises at least two control parts arranged at intervals;

the lower shell is provided with at least one supporting part, the supporting part is arranged between two adjacent detection switches, and the upper end part of the supporting part is abutted against the joint of two adjacent control parts; or the like, or, alternatively,

an elastic supporting piece is arranged between the control part and the detection switch.

13. The wireless controller according to claim 12, wherein a second pressing portion is provided at a position of the upper case corresponding to the supporting portion;

the gap between the second pressing part and the supporting part is smaller than or equal to the thickness of the sealing part.

14. The wireless controller of claim 12, wherein the power generation module comprises a self-generating motor; a motor mounting part is arranged in the lower shell; the self-generating motor is mounted on the motor mounting part;

the control part responds to the driving force to generate displacement and exerts a pressure effect on the self-generating motor;

the self-generating motor is configured to convert mechanical energy into electrical energy in response to the pressure action.

15. The wireless controller of claim 14, wherein the power generation module further comprises at least one drive reset unit;

the manipulation part responds to the driving force and applies the pressure action to the driving reset unit;

the driving reset unit is arranged to drive the self-generating motor to supply energy to the signal unit in response to the pressure action.

16. The wireless controller of claim 15, wherein the driving reset unit comprises a driving part and a reset part;

the driving part is arranged to be switched from a first position to a second position in response to the pressure action so as to drive the self-generating motor to supply energy to the signal unit;

the reset part is arranged to abut against the driving part under the condition that the driving part is at the first position, and the driving part is driven to rebound and reset to the first position after the pressure action is released under the condition that the driving part is at the second position in response to the pressure action.

17. The wireless controller of claim 16, wherein the driving part is pivotally connected to the lower case;

the control part also comprises a driving pressing part which is in contact with the driving part;

the control part responds to the driving force, the driving pressing part applies the pressure effect to the driving part, the driving part is driven to do pivoting motion, and the first position is switched to the second position.

18. The wireless controller of claim 17, wherein the driving portion comprises two driving arms and a connecting arm connecting the two driving arms; the two drive arms are pivotally connected to the housing.

19. The wireless controller of claim 18, wherein the reset portion is provided as a torsion spring; the connecting arm is provided with a first pressing part and a second pressing part;

the first pressing part is used for driving the self-generating motor to supply energy to the signal unit;

the second pressing portion is used for pressing the torsion spring.

20. The wireless controller according to claim 19, wherein the self-generating motor includes a driving assembly;

the first pressing part and the second pressing part form a step structure, when the driving part is located at a first position, the second pressing part is abutted against the torsion spring, and a preset gap is formed between the first pressing part and the driving assembly; when the driving part is located at the second position, the torsion spring is compressed to store mechanical energy, the driving assembly is stressed to store the mechanical energy, and the self-generating motor is triggered to output electric energy.

21. The wireless controller according to claim 18, wherein the connecting arm is provided with a support portion avoiding groove, and the position of the support portion avoiding groove corresponds to the position of the support portion.

22. The wireless controller according to claim 18, wherein the connecting arm is provided with at least one detection switch avoiding portion, and the control portion includes a detection switch accommodating groove, and the detection switch penetrates through the detection switch avoiding portion to be accommodated in the detection switch accommodating groove.

23. The wireless controller of claim 22, wherein the detection switch has a predetermined gap from an inner wall of the detection switch receiving groove.

24. A wireless control device comprising an actuator and a wireless controller according to any of claims 1-23; the wireless controller can transmit wireless control signals in the working state, and the actuator can receive the wireless control signals transmitted by the wireless controller in the working state.

25. A hot water system, comprising a wireless controller of any one of claims 1-23 and a water heater communicatively connectable to the wireless controller; the wireless controller can transmit wireless control signals under the working state, and the water heater can receive the wireless control signals transmitted by the wireless controller.

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