CN112020196B - Hidden signal receiving device, wireless control lamp and lamp installation implementation method - Google Patents

Abstract

The invention provides a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the hidden signal receiving device is suitable for being paired with a corresponding wireless controller to receive a control signal sent by the wireless controller and control the corresponding lamp according to the control signal so as to realize wireless control installation or refitting of the lamp without damage in a state that the hidden signal receiving device is installed in a high-depth command box and a state that the lamp is installed in a ceiling, the hidden signal receiving device is set to be of a box body structure with a size suitable for being embedded into the high-depth command box, so that when the lamp is an existing installed lamp, the wireless control refitting method of the lamp corresponds to the installation of the hidden signal receiving device in the corresponding high-depth command box and the connection of corresponding lines, without causing changes to the external shape and occupation of internal space of the existing lamp.

Description

Hidden signal receiving device, wireless control lamp and lamp installation implementation method

Technical Field

The invention relates to the field of illumination, in particular to a hidden signal receiving device of a wireless control lamp, the wireless control lamp and a lamp installation implementation method.

Background

In the building field, the control switch of the traditional wired ceiling lamp is often set to the installation position on the ceiling of a house by designers or decorators before the house is installed and repaired, and a high-depth commander box (or a shell with an accommodating space such as a fixed line box) is preset at the installation position and wires are laid, so that the ceiling lamp is fixedly installed by using the high-depth commander box in the future.

Later, in order to solve the trouble of the user, lamp enterprises have introduced ceiling lamps with remote controllers, thereby partially solving the problem of the user to a certain extent, but simultaneously bringing about a plurality of new problems for the user, such as damage of the remote controller or damage of a remote control signal receiver embedded in the lamp, the user is often difficult to purchase corresponding accessories separately, the whole lamp needs to be replaced to recover normal use, which causes great money and resource waste, in addition, the battery needs to be replaced regularly by using a common remote controller, the use amount of the battery is increased, and the environmental pollution is aggravated to a certain extent.

Even so, for users who have installed the wired controller ceiling lamp or use the lamp with exquisite and expensive antique value, there is no better solution for them to choose at present except that the users still suffer from the inconvenience of the wired controller lamp or sacrifice the antique value and cost to replace the lamp with a new lamp with wireless control function.

The passive wireless switch is used to solve the above problems, which is undoubtedly a good choice, for example, the switches disclosed in the patents with publication numbers CN104407522B and CN106972780A, although the passive wireless switch products produced according to the patent are widely used in buildings, the technical scheme disclosed in the patent still has the technical defects of large driving force required during driving and low power generation efficiency, and further causes the defects of insufficient power, weak penetrating power and the like of the passive wireless switch for transmitting control signals, so that if the signal receiver directly connected with the lamp and controlling the lamp is mounted in a hidden manner, the signal receiver may not be stably controlled, and the signal receiver mounted in an un-hidden manner may affect the appearance and presentation effect of the lamp. Simultaneously, along with the continuous development of intelligent house industry, people are more and more high to the requirement of the experience effect of passive wireless product, need feel soft, the noise is minimum to the thickness of passive wireless switch has proposed the requirement, thickness promptly will with the thickness (standard thickness) phase-match of traditional wall socket, it is thinner even, just so better with socket together supporting use in house fitment, make can be with passive wireless switch and socket together supporting installation, make the house environment more pleasing to the eye. However, after the thickness of the passive wireless switch is reduced, the internal space of the passive wireless switch is reduced by times and becomes narrower, so that the existing micro generator cannot be used, even if the micro generator is installed reluctantly, the corresponding power supply efficiency cannot be achieved, the signal transmitting circuit cannot be normally supplied with power, and the wireless control is not realized.

Meanwhile, when the electric appliance is wirelessly controlled in a building by additionally installing a signal receiver, the problem that the installation and fixing position of the proper signal receiver is difficult to find is always solved, and if a developer installs the signal receiver at a hidden position, subsequent maintenance is difficult, and after the house is handed over, the owner cannot find out where the signal receiver is installed; if the signal receiver is arranged in the lamp, the signal receiver and the receiving device are easily thrown away together once the lamp is replaced, so that the wireless control function is lost; if the signal receiver is arranged beside the lamp, the appearance is hindered; if the signal receiver is installed in the electric box, a special line must be installed on each street lamp, which causes waste and increases higher installation cost. Since the problem of difficult installation of the signal receiver is not solved well, the wireless control mode is difficult to be implemented in a local production project, and developers still adopt the traditional mechanical switch as the standard for building handing over.

In view of the above inconveniences, a user needs a technical solution that can add or move a controller of a lamp at any position in a room without affecting the appearance, the look and feel, the presentation effect and the control habit of the conventional ceiling lamp, and the technical solution should enable the user to easily and simply complete installation at any place in the room where the user wants to install the controller of the lamp, for example, at any position in the room such as at a bedside, beside a bathtub or on a balcony, and simultaneously should have an aesthetic effect and conveniently control the lamp at any place in the room, so as to adjust the mode of the lamp.

Disclosure of Invention

The invention aims to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the hidden signal receiving device is suitable for being arranged in a high-depth command box for hidden installation, so that the hidden signal receiving device can be found only when the lamp is detached, and the hidden signal receiving device is beneficial to maintenance; meanwhile, the hidden signal receiving device is installed separately from the lamp, so that the hidden signal receiving device can be kept even if the lamp is replaced; furthermore, hidden signal receiver is suitable for being arranged in the high and deep commander box and is favorable to the debugging when the batch installation construction in the building for the progress of installation and debugging, has fine economic nature.

The invention aims to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the hidden signal receiving device is suitable for various lamps and has good universality.

One objective of the present invention is to provide a hidden signal receiving device and wireless control lamp and lamp installation implementation method, wherein the wireless control lamp comprises a lamp, a hidden signal receiving device and a wireless controller, the hidden signal receiving device can be hidden and installed in a high-depth command box preset on a ceiling, the wireless controller is set to be activated to send a control signal, the hidden signal receiving device is set to be paired with the wireless controller to receive the control signal and control the lamp according to the received control signal, so that when the lamp is an existing lamp installed, the wireless control modification of the lamp corresponds to the installation of the hidden signal receiving device on the corresponding high-depth command box and the connection of the corresponding line without changing the appearance and occupying the internal space of the existing lamp.

An object of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the hidden signal receiving device has a size suitable for being embedded in the high-depth signaling box and extends with at least one fixing arm, wherein the fixing arm is provided with at least one fixing hole, such as but not limited to a round hole, an oval hole and a half hole, so as to form a hidden fixed installation of the hidden signal receiving device in the high-depth signaling box by fixing the fixing arm of the hidden signal receiving device inside the high-depth signaling box in a screw fixing manner based on the fixing column or the fixing nut that is inherent inside the high-depth signaling box in a state that the hidden signal receiving device is embedded in the high-depth signaling box.

An object of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the number of the fixing arms of the hidden signal receiving device is one, so as to facilitate the flexibility of single-hole fixing and the reduction of the size of the hidden signal receiving device while reducing the size of the hidden signal receiving device, thereby improving the adaptability of the hidden signal receiving device to the high-depth command boxes of different specification types.

One objective of the present invention is to provide a hidden signal receiving device and wireless control lamp and lamp installation implementation method, wherein the hidden rear signal receiving device is provided with an antenna, wherein the antenna is led out from the hidden signal receiving device, so as to be beneficial to further reducing the size of the hidden signal receiving device, based on the leading-out arrangement of the antenna from the hidden signal receiving device, the signal receiving capability of the hidden signal receiving device is improved when the hidden signal receiving device is hidden and fixed in the high-depth command box, the applicability of the wireless control light fixture is improved corresponding to the improvement of the effective installation distance of the wireless controller under the limit of the transmitting power of the wireless controller, and the power consumption of the wireless controller is reduced under the limit of the fixed installation distance of the wireless controller.

An object of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the antenna of the hidden signal receiving device is led out in a biased manner in a fixing direction of the fixing arm, so that in a state where the hidden signal receiving device is fixed to the high-depth signaling box through the fixing arm, a state where the antenna faces the inside of the high-depth signaling box and a state where the antenna is close to a sidewall of the high-depth signaling box are formed, and thus, a signal receiving capability of the hidden signal receiving device in a state where the hidden signal receiving device is fixed to the high-depth signaling box is improved in a manner that an installation depth of the hidden signal receiving device in the high-depth signaling box is reduced and a state where the antenna is close to the sidewall of the high-depth signaling box.

An object of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the hidden signal receiving device further includes a docking button, wherein the docking button is used to switch the hidden signal receiving device to a pairing state and is adapted to complete the pairing between the hidden signal receiving device and the wireless controller in the pairing state.

An object of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the docking button is installed on the hidden signal receiving device in a direction opposite to the fixing direction of the fixing arm, and a state where the docking button faces the installation position of the lamp is formed corresponding to a state where the hidden signal receiving device is fixed to the high-depth command box through the fixing arm, so as to facilitate the matching setup of the hidden signal receiving device after being installed, and further simplify the matching setup of the hidden signal receiving device when being installed and the matching setup when replacing/adding the corresponding wireless controller.

An object of the present invention is to provide a hidden signal receiving device and a wireless control lamp and a lamp installation implementation method, wherein the hidden signal receiving device further includes at least one status lamp disposed adjacent to the docking button, wherein the status lamp is configured to indicate the corresponding status of the hidden signal receiving device, including the pairing status of the hidden signal receiving device, based on the corresponding flashing rule and/or color, so as to facilitate the clear pairing process of the hidden signal receiving device and the wireless controller.

An object of the present invention is to provide a hidden signal receiving device and a wireless control lamp and a lamp installation implementation method, wherein the hidden signal receiving device further includes an output terminal and an input terminal, wherein the input terminal is used for connecting an external power supply, and the output terminal is used for connecting the lamp, i.e. when the lamp is an existing lamp which is installed, the line modification in the wireless control modification process of the lamp corresponds to disconnecting the lamp and the external power supply, and connecting the input terminal to the external power supply and connecting the output terminal to the lamp, so that the method is simple and easy.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a method for implementing the installation of the lamp, wherein the thickness of the wireless controller is 17 mm or less, and the wireless controller can generate enough energy to control the signal transmitting module to perform wireless communication with the hidden signal receiving device hidden in the high-depth command box as usual, so as to control the lamp through the hidden signal receiving device.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the wireless controller is configured in a self-powered manner for economy and environmental protection, and specifically, a slingshot type power generator is used to supply power to a signal transmitting circuit control module based on an electromagnetic power generation principle, so that sufficient power can still be provided in a narrow space of the wireless controller to supply the signal transmitting circuit control module with power, so that the wireless controller can send out a wireless control signal to wirelessly communicate with the hidden signal receiving device hidden in the high-depth command box, and further control the lamp through the hidden signal receiving device.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the wireless control lamp has consistent appearance, appearance and beauty before and after being modified, and the use and ornamental value of the lamp are not affected by the modification.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the wireless control lamp is wirelessly controlled, and meanwhile, the battery is not used and replaced, which is more energy-saving and environment-friendly.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the wireless control lamp can be optionally provided with additional wireless controllers according to the number of users' requirements, and the users can easily and simply complete installation at any place in a room where the users want to install the controller, for example, at any position in the room such as a bedside, beside a bathtub, on a balcony, etc., so as to conveniently realize that the users can control the ceiling lights at any place in the room, and realize adjustment of the ceiling light mode.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the passive wireless signal receiving processor has a multi-channel control function, which not only increases the number of control lamps, but also can realize the adjustment of the on/off, brightness, light color, mode and state of the lamp through multi-channel control, and can also realize the control of different modes of the same lamp, such as stepless dimming and light color setting.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a method for implementing the installation of the lamp, wherein the thickness of the wireless controller is equivalent to that of a common wired switch or a conventional wall socket, and the wireless controller is not obtrusive and does not affect the overall aesthetic property when installed in parallel.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the wireless controller is further provided with a control lamp for feeding back the use or operation status to the user through the light signal.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein each component in the wireless controller is fixed in a snap-fit manner, so as to greatly reduce the assembly difficulty in the production process, reduce the technical requirements on assembly workers, save the production cost, facilitate the future disassembly and part replacement when the wireless controller is damaged, and reduce the use and maintenance cost of users.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the generator is an electromagnetic generator, the driving board has a pressing end for bearing the pressure applied to the driving board by the key board, the driving board also has a supporting end for supporting the driving board to pivotally swing, the driving board also has an accommodating groove for accommodating the generator, the driving board is an integrally formed metal plate to further enhance the magnetic field density around the magnet in the generator, and further improve the electrical energy conversion efficiency.

Another object of the present invention is to provide a hidden signal receiving device and a wireless control lamp and a lamp installation method, wherein the swing angle of the driving board is less than 24 °, and the slingshot type catapulting power generation device can still generate high energy by utilizing the slingshot effect.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation method, wherein the microprocessor is preset to temporarily store the electric energy generated by pressing the keypad, and when the keypad is reset to generate electric energy again, the two electric energies are superposed and then outputted to the control signal transmitting module to enhance the signal transmitting power.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation method, wherein a portion of the power generated by pressing the keypad is supplied to the microprocessor to enter a standby state, so as to reduce the startup time of the microprocessor before entering a normal operating state.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the signal transmitting circuit control module further includes a control lamp, and light of the control lamp can penetrate through the keypad to send a flashing signal, so as to prompt a user to operate through flashing light.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation method, wherein the generator is an electromagnetic generator, and the clip is a metal clip with a clamping force, so as to fix the magnetic assembly and enhance the magnetic induction line density around the magnet, thereby further improving the electrical energy conversion efficiency of the generator.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the generator can be a piezoelectric generator.

Another objective of the present invention is to provide a hidden signal receiving device, a wireless control lamp and a lamp installation implementation method, wherein the number of key boards is multiple, and the multiple key boards share one set of the slingshot type catapult power generation device and the signal transmission circuit control module.

According to an aspect of the present invention, there is provided a hidden signal receiving device, wherein the hidden signal receiving device is adapted to be paired with a corresponding wireless controller to receive a control signal sent from the wireless controller and control a corresponding lamp according to the control signal, so as to implement wireless control installation or retrofitting without damage to the lamp in a state where the hidden signal receiving device is installed in a high-depth command box and in a state where the lamp is installed on top, the hidden signal receiving device is configured to have a box structure with a size suitable for being embedded in the high-depth command box, and includes:

the fixing arm extends from the box body structure and is provided with at least one fixing hole, so that the fixing arm is suitable for fixing the fixing arm of the hidden signal receiving device inside the high-depth command box in a screw fixing mode to form hidden fixed installation of the hidden signal receiving device in the high-depth command box based on the design of a nut structure inherent in the high-depth command box in a state that the hidden signal receiving device is embedded into the high-depth command box;

the antenna is led out from the box body structure and ensures the signal receiving capability of the hidden signal receiving device in a state that the hidden signal receiving device is hidden and fixed in the high-depth command box;

an input end, wherein the input end is suitable for being connected with an external power supply; and

and the output end is suitable for being electrically connected with the lamp.

In an embodiment, the antenna is led out from the box body structure in the fixing direction of the fixing arm, and a state that the antenna faces the inside of the high-depth command box is formed corresponding to a state that the hidden signal receiving device is fixed to the high-depth command box through the fixing arm, so that the signal receiving capability of the hidden signal receiving device in a state that the hidden signal receiving device is fixed to the high-depth command box in a hidden manner is improved in a manner that the installation depth of the hidden signal receiving device in the high-depth command box is reduced.

In an embodiment, the antenna is biased and led out from the box body structure, and a state that the antenna is close to the side wall of the high-depth signaling box is formed corresponding to a state that the hidden signal receiving device is fixed to the high-depth signaling box through the fixing arm, so that the signal receiving capability of the hidden signal receiving device in a state that the antenna is hidden and fixed to the high-depth signaling box is improved in a state that the antenna is close to the side wall of the high-depth signaling box.

In an embodiment, the fixing hole of the fixing arm is provided as one of a circular hole, an elliptical hole, and a half hole.

In an embodiment, the number of the fixing arms is one, so that the size of the box body of the hidden signal receiving device is reduced, and meanwhile, the adaptability of the hidden signal receiving device to the high-depth command boxes with different specification types is improved based on the reduction of the size of the box body of the hidden signal receiving device and the flexibility of single-hole fixing.

In an embodiment, the hidden signal receiving device further comprises a docking button, wherein the docking button is configured to be operated to control the hidden signal receiving device to a pairing state and is adapted to complete pairing of the hidden signal receiving device and the wireless controller in the pairing state.

In an embodiment, the docking button is disposed on the box structure in a direction opposite to the fixing direction of the fixing arm, and the docking button faces the installation position of the light fixture corresponding to a state where the hidden signal receiving device is fixed to the high-depth signaling box through the fixing arm.

In an embodiment, the hidden signal receiving device further comprises at least one status light arranged adjacent to the docking button, wherein the status light is arranged to indicate a respective status of the hidden signal receiving device comprising the pairing status based on a respective flashing rule and/or color.

According to another aspect of the present invention, there is provided a wireless control light fixture, comprising:

a light fixture, wherein said light fixture is adapted to be ceiling mounted;

a wireless controller, wherein the wireless controller is configured in a self-powered mode and is enabled to be activated to send a control signal; and

the hidden signal receiving device is matched with the wireless controller to receive the control signal sent by the wireless controller and control the lamp according to the control signal, and is provided with a box body structure with the size suitable for embedding a high-depth command box, so that the lossless installation control of the lamp is realized in a state that the hidden signal receiving device is embedded into the high-depth command box and a state that the lamp is installed in a ceiling mode to shield the high-depth command box.

In an embodiment, the hidden signal receiving device is configured as a box structure having a size suitable for being embedded in the high-depth command box and includes at least one fixed arm, an antenna, an input end and an output end, wherein the fixed arm extends from the box structure and is provided with at least one fixed hole, so that the hidden signal receiving device is hidden and fixed in the high-depth command box by fixing the fixed hole inside the high-depth command box with a screw in a state that the hidden signal receiving device is embedded in the high-depth command box based on a nut structure design inherent in the high-depth command box, wherein the input end is electrically connected to a power line hidden in the high-depth command box, and the output end is electrically connected to the lamp.

In one embodiment, the antenna is biased out from the box structure in the fixing direction of the fixing arm.

In an embodiment, the concealed signal receiving device further includes a docking button, wherein the docking button is configured to be operated to control the concealed signal receiving device to a mated state and is adapted to complete the mating of the concealed signal receiving device and the wireless controller in the mated state, and the docking button is disposed on the box structure in a direction opposite to the fixing direction of the fixing arm, corresponding to a state where the docking button faces the installation position of the light fixture.

In one embodiment, the thickness of the wireless controller is less than or equal to 17 mm, the wireless controller comprises a casing, a slingshot type ejection power generation device, a signal transmission circuit control module and a reset element, wherein the casing comprises at least a key board and a bottom shell, a plurality of pressing protrusions are arranged on the inner side of the key board, the slingshot type ejection power generation device, the signal transmission circuit control module and the reset element are fixed on the bottom shell, so that the key board can drive the slingshot type ejection power generation device to generate electric energy through the pressing protrusions when being operated and pressed, and the generated electric energy is further supplied to the signal transmission circuit control module to send the control signal, wherein the slingshot type ejection power generation device comprises a driving board, an energy storage and a generator, and the generator is fixed on the bottom shell, the generator is electrically connected with the signal emission circuit control module, the generator is connected with one end of the energy accumulator, the other end of the energy accumulator is connected with the driving plate, the driving plate is pivotally and swingably fixed on the bottom case, so that when the key board is operated and pressed, the corresponding pressing protrusions of the key board can drive the driving plate, the driving plate is driven to apply pressure to the energy accumulator to enable the energy accumulator to generate deformation and accumulate mechanical potential energy, and after the mechanical potential energy accumulated by the energy accumulator reaches a certain value, one end of the energy accumulator connected with the generator instantly drives the generator to move by utilizing a slingshot effect to generate electric energy to be supplied to the signal emission circuit control module, wherein the slingshot type catapult power generation device can generate 20 muJ-300 muJ electric energy in one driving and pressing power generation process, the driving plate is provided with a pressing end for bearing the pressure applied to the driving plate by the key plate, the driving plate is also provided with a supporting end for supporting the driving plate to swing pivotally, the swing angle of the driving plate is smaller than 24 degrees, the generator comprises a coil, an iron core and a magnetic group, the iron core is sleeved with the coil, the time of one relative movement of the iron core and the magnetic group is less than 1/50 seconds, the driving plate is provided with a pressing end, a connecting end and a supporting end, the driving plate swings pivotally by taking a rotating shaft formed by the supporting end as a fulcrum, and the ratio of the length of the pressing end to the fulcrum to the length of the connecting end to the fulcrum is greater than 1.

In an embodiment, the reset element is supported between the driving board and the bottom case, so that the driving board can be restored to an initial state after being pressed and driven by the key board, and the generator can generate 20 muj-300 muj of electric energy again when being reset.

In an embodiment, the driving plate further has a receiving groove for receiving the generator, and the driving plate is an integrally formed metal plate.

According to another aspect of the present invention, the present invention further provides an installation implementation method of a wireless control lamp, wherein the wireless control lamp comprises a lamp, a hidden signal receiving device and a wireless controller, wherein the hidden signal receiving device is adapted to be paired with the wireless controller to receive a control signal sent from the wireless controller and control the lamp according to the control signal, so as to implement wireless control installation or retrofit of the lamp without damage in a state where the hidden signal receiving device is installed in a high-depth signaling box and in a state where the lamp is fixed in the high-depth signaling box, the installation implementation method comprising the following steps:

(A) electrically connecting an input end of the hidden signal receiving device to a power line hidden in the high-depth command box;

(B) electrically connecting an output end of the hidden signal receiving device with the lamp; and

(C) pairing the hidden receiving device and the wireless controller.

In an embodiment, wherein the retrofitting method further comprises the steps of:

(D) the hidden signal receiving device is embedded into the high-depth command box, and a fixing arm of the hidden signal receiving device is fixed on the high-depth command box in a screw fixing mode in the state that the hidden signal receiving device is embedded into the high-depth command box, so that the hidden signal receiving device is hidden and fixedly installed on the high-depth command box.

In an embodiment, in the step (D), after the hidden signal receiving device is mounted on the high-depth command box, a plane of a box body of the hidden signal receiving device does not exceed a plane of an opening of the high-depth command box.

In an embodiment, after the step (a), the step (B), the step (C), and the step (D) are completed, the method further comprises the steps of: and fixedly installing the lamp at the position of the opening of the high-depth command box, so that the high-depth command box, the hidden signal receiving device and the lamp are arranged in a stacked manner.

In an embodiment, wherein the step (C) comprises the steps of:

(C1) operating a pairing button on the hidden signal receiving device to control the hidden signal receiving device to be in a pairing state;

(C2) actuating the wireless controller to transmit the wireless control signal; and

(C3) the hidden signal receiving device receives and records the identity code and the control information corresponding to the wireless controller in the wireless control signal transmitted by the wireless controller so as to complete the pairing with the wireless controller.

According to another aspect of the present invention, the present invention further provides a method for installing and controlling a hidden lighting device control device, wherein the hidden lighting device control device includes a hidden signal receiving device, a high-depth signaling box, a lighting device and a wireless controller, wherein the hidden signal receiving device is configured to have a box structure with a size suitable for being embedded in the high-depth signaling box, the method for installing and controlling the hidden lighting device control device includes the following steps:

a. embedding the high-depth commander box in a ceiling;

b. embedding the hidden signal receiving device into the high-depth command box;

c. installing the lamp below the hidden signal receiving device;

d. electrically connecting an input end of the hidden signal receiving device to a power line;

e. electrically connecting an output end of the hidden signal receiving device to the lamp;

f. the wireless controller sends a control signal to the hidden signal receiving device, so that the hidden signal receiving device can control the working state of the lamp.

In one embodiment, the hidden signal receiving device has at least one fixing arm, wherein the fixing arm extends from the box structure and is provided with at least one fixing hole.

In an embodiment, the fixing arm is fixed inside the high-depth command box through the fixing hole to form a hidden fixed installation of the hidden signal receiving device on the high-depth command box.

In one embodiment, the wireless controller is configured in a self-powered mode and is enabled to be activated to send the control signal.

In one embodiment, the wireless controller includes a housing, a catapult-type catapult power generation device, and a signal transmission circuit control module, wherein the housing includes at least a key board and a bottom case, the catapult-type catapult power generation device and the signal transmission circuit control module are fixed on the bottom case, so that the key board can drive the catapult-type catapult power generation device to generate electric energy when being operated and pressed, and further supply the generated electric energy to the signal transmission circuit control module to send the control signal, wherein the catapult-type catapult power generation device includes a driving board, an energy storage device, and a generator, the generator is fixed on the bottom case, the generator is electrically connected with the signal transmission circuit control module, the generator is connected with one end of the energy storage device, and the other end of the energy storage device is connected with the driving board, the driving plate is fixed on the bottom shell in a pivoting and swinging manner, so that when the key plate is operated and pressed, the key plate can drive the driving plate, the driving plate is driven to apply pressure to the energy accumulator to store mechanical potential energy in a deformation manner, after the mechanical potential energy stored by the energy accumulator reaches a certain value, one end of the energy accumulator connected with the generator instantaneously drives the generator to move by utilizing a slingshot effect to generate electric energy to be supplied to the signal transmitting circuit control module, the slingshot type ejection power generation device can generate 20 muJ-300 muJ of electric energy in one-time driving and pressing power generation process, the driving plate is provided with a pressing end to bear the pressure applied to the driving plate by the key plate, and the driving plate is also provided with a supporting end to support the driving plate to swing pivotally, the swing angle of the driving plate is smaller than 24 degrees, the generator is an electromagnetic generator and comprises a coil, an iron core and a magnetic group, the iron core is sleeved with the coil, and the time of relative movement of the iron core and the magnetic group is less than 1/50 seconds.

In one embodiment, the driving plate is provided with a pressing end, a connecting end and a supporting end, the driving plate can swing in a pivoting mode by taking a rotating shaft formed by the supporting end as a fulcrum, and the ratio of the length of the pressing end to the fulcrum to the length of the connecting end to the fulcrum is larger than 1.

In one embodiment, the hidden signal receiving device is designed to be shell-shaped, semicircular, square or circular, so as to be convenient for installation and fully utilize the space inside the high-depth command box.

In an embodiment, the hidden signal receiving device is provided with a docking button, and the docking button is arranged on the box body structure in a direction towards the lamp in a hidden fixed installation state of the hidden signal receiving device in the high-depth command box, so as to facilitate installation and debugging.

In one embodiment, the docking button is operated to effect control of the state of the light fixture in a state where the light fixture is not secured to the high-depth signaling box or a position below the high-depth signaling box opening or the ceiling.

Drawings

Fig. 1 is a schematic diagram of the control and operation of a wireless control lamp according to a preferred embodiment of the invention.

FIG. 2 is a schematic diagram of the parallel installation of a wireless controller and a conventional wired switch, a conventional wall socket, and a control panel according to a preferred embodiment of the present invention.

Fig. 3A is a schematic front view of a hidden signal receiving device according to a preferred embodiment of the invention.

Fig. 3B is a schematic diagram of the back side of the hidden signal receiving apparatus according to the above preferred embodiment of the invention.

Fig. 4A is a schematic view of a hidden signal receiving device being hidden and mounted on an inner fixed post of a deep command box by screws according to a preferred embodiment of the present invention.

FIG. 4B is a schematic view of the hidden signal receiving device being hidden and mounted on the fixing post in the high-depth command box by screws according to the above preferred embodiment of the present invention

Fig. 5 is a schematic view of the light fixture installed on the deep signaling box with the hidden signal receiving device installed inside according to a preferred embodiment of the invention.

Fig. 6A is a schematic diagram of a wireless controller according to the above preferred embodiment of the present invention.

Fig. 6B is a schematic diagram of a power generation module of the wireless controller according to the above preferred embodiment of the invention.

Fig. 6C is a schematic view of another perspective of the power generation module of the wireless controller according to the above preferred embodiment of the present invention.

Fig. 6D is a schematic view of a generator of the power generation module according to the above preferred embodiment of the present invention.

Fig. 6E is a schematic application diagram of the power generation module according to the above preferred embodiment of the present invention.

Fig. 7 is a schematic cross-sectional view of the wireless controller according to the above preferred embodiment of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced devices or components must be in a particular orientation, constructed and operated in a particular orientation, and thus the above terms are not to be construed as limiting the present invention.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

Referring to fig. 1 to 7, a wireless control light fixture according to a preferred embodiment of the present invention is explained. Wherein the wireless control lamp comprises a lamp 1, a hidden signal receiving device 2, a wireless controller 3, wherein the hidden signal receiving device 2 can be hidden and installed in a high-depth command box 8 preset on the ceiling, the wireless controller 3 is configured to be activated to send a control signal, the hidden signal receiving device 2 is configured to be paired with the wireless controller 3 to receive the control signal and control the lamp 1 according to the received control signal, so that when the lamp 1 is an existing lamp installed already, a wireless control refitting method of the lamp 1 corresponds to the installation of the hidden signal receiving device 2 in the corresponding high-depth command box 8 and the connection of the corresponding line, corresponding to fig. 1, the lamp 1 is fixedly installed on the high-depth command box 8 preset on the ceiling 7, the hidden signal receiving device 2 is installed in the high-depth command box 8 in a hidden manner, so that the installation control of the lamp 1 is realized under the condition that the normal installation of the lamp 1 is not influenced, and the change of the appearance, the appearance and the attractiveness of the lamp 1 and the occupation of the internal space are not caused.

It is understood that the luminaire 1 may also be directly fixedly mounted to the ceiling 7 to achieve a ceiling-mounted state of the luminaire 1.

Specifically, the hidden signal receiving device 2 is implemented as a box structure having a size suitable for being embedded in the high-depth command box 8, and extends with at least one fixing arm 21, wherein the fixing arm 21 is provided with at least one fixing hole 211, such as but not limited to a round hole, an oval hole and a half hole, so as to be provided based on a fixing column or a fixing nut inherent in the high-depth command box 8, in a state that the hidden signal receiving device 2 is embedded in the high-depth command box 8, the hidden signal receiving device 2 is suitable for being fixed inside the high-depth command box 8 by the fixing arm 21 in a screw fixing manner, thereby forming a hidden fixed mounting of the hidden signal receiving device 2 on the high-depth command box 8.

It should be noted that in this preferred embodiment of the present invention, the number of the fixing arms 21 of the hidden signal receiving device 2 is one, so as to reduce the size of the box body of the hidden signal receiving device 2, and at the same time, facilitate flexibility of single-hole fixing and reduction of the box body size of the hidden signal receiving device 2, and improve adaptability of the hidden signal receiving device 2 to the high-depth command boxes 8 with different specification types.

It will be appreciated that the number of said fixing arms 21 may be one or more.

Further, the hidden signal receiving device 2 is provided with an antenna 24, wherein the antenna 24 is led out from the hidden signal receiving device 2, so as to facilitate further reducing the size of the box body of the hidden signal receiving device 2, and at the same time, based on the led-out arrangement of the antenna 24 from the hidden signal receiving device 2, in the state that the hidden signal receiving device 2 is hidden and fixed in the high-depth command box 8, the signal receiving capability of the hidden signal receiving device 2 is improved, the applicability of the wireless control lamp is improved corresponding to the improvement of the effective installation distance of the wireless controller 3 under the limitation of the transmission power of the wireless controller 3, and the power consumption of the wireless controller 3 is reduced under the limitation of the fixed installation distance of the wireless controller 3.

It should be noted that the antenna 24 may be disposed externally or internally, and may also be disposed inside the box structure.

In particular, in the preferred embodiment of the present invention, the antenna 24 of the hidden signal receiving device 2 is biased and drawn out in the fixing direction of the fixing arm 21, so that in the state that the hidden signal receiving device 2 is fixed to the high-depth signaling box 8 through the fixing arm 21, the state that the antenna 24 faces the inside of the high-depth signaling box 8 and the state that the antenna 24 is close to the side wall of the high-depth signaling box 8 are formed, thereby improving the signal receiving capability of the hidden signal receiving device 2 in the state that the hidden signal receiving device 2 is fixed to the high-depth signaling box 8 in a manner of reducing the installation depth of the hidden signal receiving device 2 in the high-depth signaling box 8 and the state that the antenna 24 is close to the side wall of the high-depth signaling box 8.

In detail, the extension of the antenna 24 from the box of the hidden signal receiving device 2 is beneficial to reduce the box size and avoid/reduce the antenna blockage caused by the receiver box, so as to make the signal better, and the signal strength requirement sent to the wireless controller 3 can be set farther or can be reduced to reduce the power consumption requirement on the wireless controller 3 corresponding to the wireless controller 3.

In more detail, the antenna 24 extending into the high-depth command box 8 can make full use of the space of the high-depth command box to enable the hidden signal receiving device 2 to be fixed in a state of being close to the mouth of the high-depth command box 8, so that on one hand, the box body of the hidden signal receiving device 2 can be fixedly installed by using the existing structure of the high-depth command box 8, and on the other hand, the situation that the hidden signal receiving device 2 is close to the mouth of the high-depth command box 8 is beneficial to the setting of the hidden signal receiving device 2 and the receiving of signals, because the equal plates of the lamp are generally metal structures, the signal receiving of the antenna 24 can be obstructed, and especially when the antenna 24 is close to the lamp panel, the antenna 24 extending into the high-depth command box 8 will enable the receiving of the antenna signals to have a better effect.

In more detail, the offset of the antenna 24 in the box of the hidden signal receiving device 2 is close to the box wall of the high-depth commander box 8 after the hidden signal receiving device 2 is installed in the high-depth commander box 8, and the close to the box wall will make the blocking of the antenna 24 by the box wall smaller, because the blocking area close to the antenna 24 becomes smaller, and the antenna 24 is offset to generate better signal transceiving effect regardless of the box of the hidden signal receiving device 2, the high-depth commander box 8 or the ceiling lamp.

Further, the hidden signal receiving apparatus 2 further comprises a docking button 22, wherein the docking button 22 is used for switching the hidden signal receiving apparatus 2 to a pairing state, so as to complete the pairing of the hidden signal receiving apparatus 2 and the wireless controller 3 in the pairing state.

Specifically, the docking button 22 is disposed on the hidden signal receiving device 2 in a direction opposite to the fixing direction of the fixing arm 21, and a state in which the docking button 22 faces the installation position of the lamp 1 is formed corresponding to a state in which the hidden signal receiving device 2 is fixed to the high-depth command box 8 through the fixing arm 21, so as to facilitate the matching of the hidden signal receiving device 2, and further simplify the matching of the hidden signal receiving device 2 when it is installed and the matching when the corresponding wireless controller 3 is replaced/added.

It is worth mentioning that the docking button 22 faces the installation position of the luminaire 1, which is beneficial for installation and debugging, and subsequent maintenance.

In particular, the hidden signal receiving device 2 further comprises at least one status light 23 disposed adjacent to the docking button 22, wherein the status light 23 is configured to indicate the corresponding status of the hidden signal receiving device 2, including the pairing status of the hidden signal receiving device 2, based on the corresponding flashing rule and/or color, so as to facilitate the process of pairing the hidden signal receiving device 2 with the wireless controller 3.

Further, the hidden signal receiving device 2 further comprises an output end 26 and an input end 25, wherein the input end 25 is used for connecting an external power supply, and the output end is used for connecting the lamp 1, that is, when the lamp 1 is an existing lamp which is installed, the circuit modification in the wireless control modification process of the lamp 1 corresponds to the disconnection of the lamp 1 and the external power supply, and the input end 25 is connected to the external power supply and the output end 26 is connected to the lamp 1, so that the hidden signal receiving device is simple and easy to implement.

In particular, as shown in fig. 2, in this preferred embodiment of the present invention, the thickness of the wireless controller 3 is comparable to that of the conventional wired switch 4 or the conventional wall socket 5 and control panel 6, and the side-by-side installation is not obtrusive and does not affect the overall aesthetics.

In detail, the thickness of the conventional common wired switch 4 or the conventional wall socket 5 is generally 17 mm (standard thickness), and the thickness of the wireless controller 3 is less than or equal to 17 mm, so that the wireless controller and the common wired switch 4 or the conventional wall socket 5 cannot be too obtrusive when being installed in parallel, and the overall appearance is not affected. In other words, the wireless controller 3 is a wireless controller 3 that does not exceed a standard thickness.

It should be noted that, in the preferred embodiment of the present invention, the wireless controller 3 is configured in a self-powered manner to be economical and environmentally friendly, and specifically, converts mechanical energy into electrical energy by an electromagnetic power generation principle, and then supplies the generated electrical energy to the signal transmitting circuit to send out a wireless signal. The thickness of the controller is limited below 17 mm, which means that the movement stroke of the power generation device is severely limited in the prior art, the generated electric energy is severely weakened, and the transmission power of the signal transmission circuit is reduced, so that the signal penetration capacity is weakened.

In the present invention, in order to keep the appearance, appearance and beauty of the lamp 1 from being affected by the modification, the hidden signal receiving device 2 is hidden and installed in the high-depth command box 8, in other words, the hidden signal receiving device 2 is actually embedded and installed in the ceiling 7 which may be poured by cement, if the thickness of the self-generating switch in the prior art is directly reduced to less than 17 mm, the internal space is narrowed, the stroke of the generator is reduced, the power supply capability of the generator is reduced, and the control signal cannot be effectively transmitted to the hidden signal receiving device, that is, the control of the hidden signal receiving device cannot be effectively realized.

Referring to fig. 6A to 6E, in a preferred embodiment of the present invention, when the wireless controller 3 is made to be less than 17 mm thick, the keypad 311 can provide 20 μ J to 300 μ J of energy for transmitting the wireless control signal in one pressing and resetting, respectively, that is, the keypad 311 can provide 40 μ J to 600 μ J of energy for transmitting the wireless control signal in one pressing and resetting cycle, thereby ensuring that the wireless controller 3 can effectively control the hidden signal receiving apparatus 2.

In more detail, for an electromagnetic generator, according to the principle of electromagnetic induction, if the faster the core wound by a coil moves relative to the magnetic groups or the faster the magnetic groups move relative to the core wound by a coil, the greater the magnetic flux change and the greater the energy generated in the coil, in other words, the faster the relative movement between the core wound by a coil and the magnetic groups occurs, the greater the energy generated. However, if the overall thickness of the switch is less than 17 mm, which means that the movement stroke of the generator 324 does not exceed 6 mm, it is very difficult to increase the relative movement speed between the iron core 3242 and the magnet 32444 set in such a narrow space, the narrow space directly results in a reduction in the acceleration stroke and a reduction in the acceleration time, and if the relative movement speed between the iron core 3242 and the magnet 3244 is increased to increase the acceleration again, it is only possible to obtain a larger relative movement speed in a limited time.

In the above preferred embodiment of the present invention, the wireless controller 3 includes: the device comprises a shell 31, a catapult type ejection power generation device 32, a signal transmitting circuit control module 33 and a reset element 34. Wherein the slingshot power generation device 32 further comprises a drive plate 321, an energy storage 323, and a generator 324.

Further, the housing 31 includes: a key board 311, a middle case 313, the catapult-type ejection power generation device 32, the signal emission circuit control module 33, and the reset element 34 are fixed in the space formed by the middle case 313 and the bottom case 312, the key board 311 is pivotally fixed on the middle case 313, wherein a plurality of pressing protrusions are arranged on the inner side of the key board 311, the corresponding positions of the pressing protrusions on the middle case 313 are hollowed-out slotted holes 3131, so that the catapult-type ejection power generation device 32, the signal emission circuit control module 33, and the like in the space can be operated and controlled through the pressing protrusions when a key is pressed.

It should be understood that the middle case 313 is not necessary, and the key sheet may be directly pivotally engaged with the bottom case 312 without the middle case 313, and the catapult-type ejection power generation device 32, the signal transmission circuit control module 33, and the reset element 34 are fixed to the bottom case 312.

Optionally, the housing 31 further includes a soft shell 314, and the soft shell 314 is installed between the middle shell 313 and the bottom shell 312, so as to form a sealed space between the soft shell 314 and the bottom shell 312 by blocking the middle shell 313, and the catapult-type catapulting power generation device 32, the signal transmitting circuit control module 33, and the reset element 34 are located in the sealed space, so as to perform waterproof and dustproof functions, thereby preventing the wireless controller 3 from being affected by environmental changes, and prolonging the life of the wireless controller 3.

Alternatively, the key sheet 311 and the middle case 313 may be fixed by snap fit or hinge.

Alternatively, the middle shell 313 and the bottom shell 312 may be fixed by a snap fit or a screw.

It is understood that, in some embodiments, by adjusting the design of the bottom casing 312, the key board 311 can also be directly fixed to the bottom casing 312 by snap-fitting, without the middle casing 313 and the soft casing 314.

Further, the bottom housing 312 further has a generator 324 fixing groove 3121 for clamping and fixing the generator 324, so as to facilitate the installation and detachment of the generator 324.

Further, the bottom housing 312 further has a driving plate engaging groove 3122 for engaging with the driving plate 321, and the driving plate 321 can pivotally swing within a certain angle range with a portion of the driving plate 321 connected to the driving plate engaging groove 3122 as a fulcrum.

Furthermore, as shown in fig. 6B, the driving board clamping groove 3122 further has a fulcrum positioning portion 31221 and a clamping portion 31222, the fulcrum positioning portion 31221 is used for positioning an installation position of the driving board 321, and the clamping portion 31222 is used for stably installing the driving board 321 at a corresponding position within a certain angle range of the swing of the driving board 321 after the driving board 321 is installed, so that the situation that the wireless controller 3 cannot be normally used due to the dropping of the driving board 321 in the use process is avoided.

Optionally, the bottom case 312 further has a circuit board positioning portion for fixing the circuit board formed by the signal transmitting circuit control module 33 in a snap-fit manner.

Preferably, the soft shell 314 is further provided with a driving element, a buffering element, and the like at a position corresponding to the slotted hole, so that each device is within a proper acting force bearing range or kept at a proper position through adjustment of the driving element and the buffering element according to the stress condition of each device. For example, the soft glue thickness of the soft shell 314 at the position corresponding to the position where the key presses the driving board 321 through the slot on the soft shell 314 can be increased to increase the stressed area, increase the contact sensitivity, and prolong the service life of the driving board 321 and the key. Meanwhile, the soft shell 314 is provided with a protrusion to jack up the key through the slot hole, so that the key forms a certain buffer when pressed downwards, the damage of the pressing force to the device is reduced, and other keys which are not influenced by external force can keep a jacked static state and are not influenced by the pressed key.

Preferably, the soft shell 314 is made of flexible plastic or rubber, so that the sealed space can be waterproof and dustproof and can transmit the beneficial effect of mechanical force.

Further, the bottom housing 312 further has a reset element 34 positioning and locking portion to lock the reset element 34.

Fig. 6D shows one of the generators 324 of the above preferred embodiment of the present invention, including: the coil 3241, the core 3242, the fixing member 3243, the magnetic assembly 3244, the swing frame 3245, and a surrounding magnetic conductive member 3246, wherein the coil 3241 is sleeved on the core 3242, the core 3242 is fixedly fixed to the surrounding magnetic conductive member 3246 by the fixing member 3243, and the core 3242 is in direct contact with the surrounding magnetic conductive member 3246. For example, the surrounding flux guide 3246 is implemented as a U-shaped clad iron 32461, the U-shaped clad iron 32461 is composed of a transverse plate and two longitudinal plates, the central part of the transverse plate is hollowed into a first stabilizing groove according to the area which is slightly larger than or equal to the end surface of the iron core 3242 facing one end of the transverse plate, so that one end of the iron core 3242 facing the transverse plate can be clamped into the U-shaped iron clad 32461, the securing member 3243 is implemented as a securing plate, the central portion of which is hollowed out to form a second securing groove with an area slightly larger than or equal to the end surface of the core 3242 facing one end of the securing plate, so that one end of the iron core 3242 facing the stabilizing plate can be clamped into the second stabilizing groove, the stabilizing plate can be clamped in the U-shaped iron clad 32461, and the stable installation of the iron core 3242 is realized by clamping the stable plate and the U-shaped iron clad 32461.

It is worth mentioning that the surrounding magnetic conductive member 3246 is made of a metal magnetic conductive material, and since denser magnetic induction lines pass through the metal magnetic conductive material, the surrounding magnetic conductive member surrounds the coil 3241 to further enhance the density of the magnetic induction lines around the coil 3241, so as to enhance the magnetic induction intensity around the coil 3241. Phi is used as magnetic flux, B is magnetic induction intensity, S is area, and the magnetic flux can be known according to the Gauss magnetic field law: BS, that is, after the magnetic induction around the coil 3241 is increased, the magnetic flux is increased accordingly, so that when the iron core 3242 sleeved by the coil 3241 is switched to contact different magnetic poles, the amount of change of the magnetic flux is multiplied. Taking n as the number of turns of the coil 3241, Δ Φ as the amount of change of magnetic flux, Δ t as the time taken for the change to occur, and ε as the induced electromotive force generated, it can be known according to the Faraday's law of electromagnetic induction: because of the increased amount of flux change, the generator 324 can generate a larger induced electromotive force, and accordingly, the generator 324 will generate more energy to the signal transmission circuit control module 33 to increase its transmission power.

Further, the magnet assembly 3244 includes a magnet 32444, a first magnetic conductive plate 32441, a second magnetic conductive plate 32442, and a clip 32443, the swing frame 3245 includes a fixed frame and two swing arms, the fixed frame has mounting positions corresponding to the magnet 32444, the first magnetic conductive plate 32441, and the second magnetic conductive plate 32442, the magnet 32444, the first magnetic conductive plate 32441, and the second magnetic conductive plate 32442 are clamped and fixed to the fixed frame by the clip 32443 after being mounted in the mounting positions corresponding thereto, the two swing arms of the swing frame 3245 are respectively clamped and connected to the surrounding magnetic conductive member 3246, and the swing frame 3245 can swing with the clamping point as a pivot point, in other words, after the two swing arms of the swing frame 3245 are respectively clamped and connected to the surrounding magnetic conductive member 3246, the swing frame 3245 can swing pivotally, so that the magnet 444, the first magnetic conductive plate 32441, the second magnetic conductive plate 32442, and the clip 32443 further enable the swing frame 3245 to swing, The second magnetic conductive plate 32442 swings together with the swing frame 3245.

Preferably, the first magnetic conductive plate 32441 and the second magnetic conductive plate 32442 are respectively installed in contact with two ends of the magnet 32444, corresponding areas of the first magnetic conductive plate 32441 and the second magnetic conductive plate 32442 are the same and are larger than a contact area between the first magnetic conductive plate 32441 and the second magnetic conductive plate 32442, a groove is formed on a face, opposite to the iron core 3242, of the magnet 32444, the first magnetic conductive plate 32441 and the second magnetic conductive plate 32442, and the iron core 3242 extends into the groove through the fixing member 3243.

Further, when the generator 324 is in a stationary state, the iron core 3242 is in contact with the first magnetic conductive plate 32441, and when the swing frame 3245 is synchronously swung during operation of the generator 324, the iron core 3242 can be switched to be in contact with the second magnetic conductive plate 32442.

Preferably, the clip 32443 is a metal clip with a clamping force to further enhance the magnetic field strength around the magnet.

Preferably, the two clamping pieces 32443 are respectively clamped at two ends of the fixing frame of the swing frame 3245, so as to fix the magnet 32444, the first magnetic conductive plate 32441, and the second magnetic conductive plate 32442 to the swing frame 3245.

Preferably, the coil 3241 is made of a self-adhesive wire or a glue adhesive winding. Therefore, the coil 3241 can be directly wound and formed, and the coil 3241 does not need to be wound by using a coil 3241 framework, so that the space occupied by the generator 324 is further saved, and contribution is made to reducing the thickness of the wireless controller 3.

In the above preferred embodiment of the present invention, one end of the swing frame 3245 of the generator 324 is disposed facing the driving plate 321, and is fixed in the generator 324 fixing groove 3121 of the bottom case 312.

In the above preferred embodiment of the present invention, the driving plate 321 has a pressing end 3211 to bear the driving force applied to the driving plate 321 by the key plate 311, the driving plate 321 further has a supporting end 3212, the supporting end 3212 has a pressing fulcrum portion 32121 to cooperate with the fulcrum positioning portion 31221 and the latching portion 31222 of the driving plate latching groove 3122 on the bottom shell 312, so as to position the pressing fulcrum portion 32121 by the fulcrum positioning portion 31221 and engage and fix the pressing fulcrum portion 32121 by the latching portion 31222, so that the driving plate 321 can perform a pivoting motion around an axis formed by the latching portion 31222, in other words, the driving plate 321 can perform a swinging motion with its own lever and with a contact point between the pressing fulcrum portion 32121 and the latching portion 31222 as a fulcrum, in other words, the supporting end 3212 is configured to support the driving plate 321 in a state of being suspended and being capable of being pressed, the driving plate 321 can swing pivotally around a pivot formed by the supporting end 3212.

Further, the driving plate 321 further has a receiving groove 3214, so that when the driving plate 321 is installed on the bottom casing 312, the receiving groove 3214 corresponds to the generator 324 fixing groove 3121 on the bottom casing 312, and is used for receiving the generator 324 together, one end of the receiving groove 3214 facing the swing frame 3245 of the generator 324 forms a connecting end 3215 and has a connecting element 3213 for connecting and shifting one end of the energy storage 323, and the other end of the energy storage 323 is connected with the swing frame 3245, so that while the space occupied by the catapult-type catapult power generation apparatus 32 is saved, the length of the arm of force of the lever can be maintained to form a labor-saving lever, and a high power output can be realized.

Preferably, the bottom case 312 has two fulcrum positioning portions 31221 and two locking portions 31222, and the support end 3212 of the driving plate 321 has four pressing fulcrum portions 32121, wherein two pressing fulcrum portions 32121 are located at two ends of the support end 3212, and the other two pressing fulcrum portions 32121 are located at two sides of the notch of the accommodating groove 3214 and are respectively matched with the positions of the two fulcrum positioning portions 31221 and the two locking portions 31222, so as to mount and fix the driving plate 321 and enable it to swing up and down.

Preferably, the connecting member 3213 is implemented as a clamping groove 32131, and the clamping groove 32131 has a locking protrusion 32132 therein to firmly lock and fix an end of the energy accumulator 323 facing the driving plate 321 therein, so as to reduce energy loss during operation and improve power conversion efficiency.

Preferably, the drive plate 321 is implemented as an integrally formed metal plate. The metal plate formed as an integral body can enhance the stress strength of the driving plate 321; on the other hand, since the generator 324 is accommodated in the accommodating groove 3214 of the driving plate 321, the density of magnetic induction lines around the core 3242 can be increased to some extent by using a metal plate, thereby further improving the power conversion efficiency and generating more power.

Further, the driving plate 321 is connected to the energy storage 323 and the reset element 34, respectively, and the energy storage 323 is firmly connected to the swing frame 3245 of the generator 324, so that when the driving plate 321 is pressed, the energy storage 323 is firstly driven to accumulate mechanical energy, and at a moment when the energy storage 323 is full of mechanical energy, the energy storage 323 drives the magnetic group 3244 fixed on the swing frame 3245 of the generator 324 to move relative to the iron core 3242.

It is worth mentioning that the driving board 321 has the pressing end 3211 and the accommodating groove 3214 is disposed at an end facing the swing frame 3245 of the generator 324 to form a connecting end 3215 connected to the energy storage device 323, so as to achieve a labor-saving effect, that is, when the force input from the key board 311 is input to the energy storage device 323 via the driving board 321, the driving force can be saved by at least 10% by using the labor-saving design of the driving board 321. In other words, the driving plate 321 has a lever action, and the ratio of the length of the pressing end from the fulcrum to the length of the connecting end 3215 from the fulcrum is greater than or equal to 1.

More specifically, according to the law of conservation of energy and newton's law, the accumulated mechanical energy is instantaneously released, so that the energy storage 323 and, therefore, the swing frame 3245 connected thereto have greater acceleration, and the magnetic group 3244 fixed to the swing frame 3245 can complete the switching between the iron core 3242 and the contact magnetic pole in a shorter time under the same stroke, in other words, the iron core 3242 is switched from being in contact with the first magnetic conductive plate 32441 to being in contact with the second magnetic conductive plate 32442 in a shorter time, and further, according to the faraday's law of electromagnetic induction, a greater induced electromotive force, that is, more electric energy can be generated.

More specifically, in the above-described preferred embodiment of the present invention, the principle of the slingshot effect is utilized, the slingshot acceleration is employed, and the slingshot power generation device 32 composed of the drive plate 321, the energy storage 323, and the power generator 324 is used, so that when the slingshot effect of the slingshot power generation device 32 is utilized in a narrow space in the wireless controller 3, mechanical energy is first accumulated, and then the mechanical energy is accumulated to a certain amount, the iron core 3242 and the magnetic group 3244 are instantaneously driven to complete one rapid magnetic pole switching within a time period of less than 1/50 seconds. In other words, the time for one relative movement of the core 3242 and the magnet assembly 3244 is less than 1/50 seconds. In other words, the switching time from the original attraction of the iron core 3242 with the first magnetic conductive plate 32441 to the attraction of the iron core 3242 with the second magnetic conductive plate 32442 is accelerated to less than 1/50 seconds by utilizing the slingshot effect, so that a higher pulse power is generated in the coil 3241. Under the condition that the number of turns of the coil 3241 and the magnetic field intensity are not changed, increasing the relative speed of the iron core 3242 and the magnetic group 3244 is an effective method for increasing energy, and the preferred embodiment of the invention can well solve the technical problem that the power generation device generates high energy in a narrow space by utilizing the slingshot effect.

In other words, the slingshot type catapult power generation device 32 further includes a driving plate 321, an energy storage 323, and a power generator 324, the power generator 324 is fixed to the bottom case 31, the power generator 324 is electrically connected to the signal transmission circuit control module 33, the power generator 324 is connected to one end of the energy storage 323, the other end of the energy storage 323 is connected to the driving plate 321, the driving plate 321 is pivotally and swingably fixed to the bottom case 31, so that when the key board 311 is pressed, the corresponding pressing protrusion of the key board 311 can drive the driving plate 321, so that the driving plate 321 further applies pressure to the energy storage 323 to generate deformation and accumulate mechanical energy, and after the energy storage 323 is filled with the preset mechanical energy, the end of the energy storage 323 connected to the power generator 324 instantaneously drives the power generator 324 to generate electric energy to supply to the signal transmission circuit control module by using the slingshot effect.

It is worth mentioning that the arrangement of the driving plate 321, the connecting member 3213 of the driving plate 321, the energy storage 323 and the generator 324 improves the electric energy conversion efficiency of the generator 324 as much as possible, and also reduces the requirement for the swing angle of the driving plate 321 to meet the requirement for the thickness of the wireless controller 3.

Preferably, the energy accumulator is a Y-shaped elastic sheet.

Alternatively, the swing angle of the driving plate 321 may be controlled to be less than 24 °. That is, an angle of the pressing end 3211 of the driving plate 321 swinging around a contact point of the pressing fulcrum portion 32121 with the blocking portion 31222 may be less than 24 °.

Further, the reset element 34 is disposed at the reset element 34 positioning and locking portion of the bottom case 312, and one end of the reset element 34 is connected to the bottom case 312, and the other end is connected to the driving board 321.

Further, when the driving plate 321 is a metal plate formed integrally, the reset element 34 can be a single torsion spring, and can still keep the driving plate 321 stably swinging within an angle range less than 24 ° when the pressing end 3211 of each portion is pressed.

It should be noted that, in the above preferred embodiment of the present invention, different positions on the driving board 321 can correspond to the pressing protrusions of the plurality of key boards 311 at the same time, so that the plurality of key boards 311 can be powered by only one set of the catapult-type catapulting power generation device 32 to control the transmission signal circuit. In other words, the plurality of key sheets 311 represent different control signals, but the pressing protrusions of the plurality of key sheets 311 pressing the driving plate 321 are all pressed on the same driving plate 321, so that the plurality of key sheets 311 share one set of catapult-type catapult power generation device 32, and the control signals sent by the key sheets 311 may be different.

It is worth mentioning that the reset element 34 is supported between the housing 31 and the driving plate 321 to reset the driving plate 321 to the initial state. After the driving plate 321 is pressed and drives the generator 324 to complete power generation, the reset element 34 is pressed by the driving plate 321 to deform, so as to reset the driving plate 321, and further, when the driving plate 321 is reset, the catapult-type catapult power generation device 32 composed of the driving plate 321, the energy storage 323 and the generator 324 generates power again, so that a user generates electric energy twice in one pressing process.

It should be noted that the slingshot type catapult power generation device 32 of the present invention converts mechanical energy into electrical energy, and since the mechanical energy is firstly accumulated by the energy accumulator 323 and is released once at a moment when the mechanical energy is fully accumulated, stable mechanical energy output is generated during each pressing and resetting, and further the electrical energy generated by the generator 324 during each power generation is stable, thereby reducing the circuit design requirement on the signal transmission circuit control module 33 and reducing the production cost.

It should be noted that, although the generator 324 can generate power without installing the energy storage 323, the power generated by the generator 324 is unstable due to different forces of different people operating the key pad 311 each time, and the design difficulty and hardware cost of the signal transmitting circuit control module 33 are greatly increased if the signal transmitting circuit control module 33 is to keep normal operation.

It is understood that the generator 324 may also be a piezoelectric generator or other mechanical energy collecting generator, and together with the energy storage 323 and the driving plate 321, forms the catapult-type catapulting power generation device 32.

It should be noted that, in fact, the magnitude of the load current also affects the relative movement speed of the iron core 3242 and the magnetic group 3244, and if the current consumed by the load is large, the speed of switching the magnetic poles is reduced, so that, in a narrow space of the passive switch, in order to ensure that the time for switching the magnetic poles of the power generation device can be controlled within 1/50 seconds, the power consumption of the signal transmission circuit control module 33 should be less than 3V 10mA 10mS 300 μ J (microjoule).

Further, the signal transmitting circuit control module 33 is electrically connected to the generator 324, and the signal transmitting circuit control module 33 includes a command detecting element 331, a circuit management module, a control signal transmitting module, and a control lamp 334.

Preferably, the signal transmitting circuit control module 33 is installed below the generator 324, the generator 324 further has two electrode antennae with opposite polarities, the signal transmitting circuit control module 33 has two power input terminals with opposite polarities, and the electrode antennae and the power input terminals can be electrically connected in a matched contact manner, so that the generator 324 can supply electric energy to the signal transmitting circuit control module 33.

Preferably, the signal transmission circuit control module 33 is integrated on an integrated circuit board.

Preferably, the command detecting element 331 is implemented as a micro switch 3311.

Alternatively, the command detection element 331 may also be implemented as one or more of a magnetic-powered switch, a reed switch, a tact switch, and the like.

In detail, when the key sheet 311 of the wireless controller 3 is pressed, a part of the pressing protrusions of the key sheet 311 will first press the detection element to connect the coding circuits corresponding to the detection element, and then another part of the pressing protrusions will drive the driving plate 321 to drive the entire catapult-type catapult power generation device 32 to generate power to the signal transmitting circuit control module 33 when the key sheet 311 is further pressed downward, and the circuit management module of the signal transmitting circuit control module 33 generates a wireless control command according to the connected coding circuit, and further transmits a wireless control signal through the control signal transmitting module.

It can be understood that in the above preferred embodiment of the present invention, the layout design of the slingshot type catapult power generation device will greatly improve the energy conversion efficiency of converting mechanical energy into electric energy under the condition of unchanged material, and the specific output electric energy of the slingshot type catapult power generation device can be determined by the used material of the magnet and the used material of the energy accumulator, so that the production cost can be further saved through material selection on the basis of meeting the use purpose.

Further, the light of the control light 334 can emit a flashing signal through the soft shell 314, the middle shell 313 and the key board 311, in other words, the control light 334 can penetrate through the key board to emit a flashing signal, so as to remind the user of operation through the flashing of the light.

Optionally, the control light 334 is implemented as an LED light or light emitting diode.

It should be noted that, in the above preferred embodiment of the present invention, since the wireless controller 3 is limited below 17 mm, it is difficult for a common micro power generation device to provide enough power to the control signal transmitting module for transmitting wireless signals, let alone additionally providing power to the control lamp, within the thickness range, and after the arrangement design of the catapult type catapult power generation device is adopted, the generated power can be not only sufficiently provided for the control signal transmitting module, but also provided for the control lamp to provide more rich functions.

Preferably, the circuit control module comprises a microprocessor for determining and managing the supply of electrical energy in the circuit.

Preferably, the microprocessor is a single chip microcomputer.

Further, by cooperating with electronic components such as a diode, a transistor, a capacitor, etc., and according to the property that the current direction in the circuit is opposite when the generator 324 is pressed and reset, the microprocessor 3321 can determine whether the generated power is generated when the generator is pressed or reset, and then determine how to use the power according to the preset mode. For example, the management manner of the microprocessor 3321 for the electric energy may be preset such that when the electric energy is generated by pressing, the generated electric energy is temporarily stored, a part of the electric energy is supplied to the microprocessor 3321 to make it enter a standby state, when the electric energy is generated again by resetting, two times of electric energy are superposed and outputted with higher electric energy together to the control signal transmitting module to enhance the signal transmitting power thereof, in other words, the electric energy generated when the key board 311 is pressed is temporarily stored by presetting the microprocessor 3321, and when the key board 311 is reset to generate the electric energy again, the two times of electric energy are superposed and outputted together to the control signal transmitting module 33.

Preferably, the microprocessor can be preset according to operation requirements, so that the microprocessor can send out state or operation prompts to a user according to corresponding conditions.

It should be noted that in the above preferred embodiment of the present invention, the casing 31, the catapult-type catapult power generation device 32, the signal transmitting circuit control module 33, the reset element 34 of the wireless controller 3, and the driving plate 321, the energy accumulator 323, and the generator 324 of the catapult-type catapult power generation device 32 all adopt a snap-fit mounting structure, so as to facilitate the replacement and installation of parts in the maintenance of the wireless controller 3 in the future.

According to another aspect of the present invention, the present invention further provides an installation implementation method of the wireless control lamp, wherein the wireless control lamp comprises a lamp 1, a hidden signal receiving device 2, a wireless controller 3; the outer surface of the receiver is provided with a butt joint button 22 and a state lamp 23; the wireless controller 3 further comprises a housing 31, a catapult type ejection power generation device 32, a signal transmission circuit control module 33, and a reset element 34, the housing 31 further comprises a key board 311 and a bottom case 312, the catapult type ejection power generation device 32, the signal transmission circuit control module 33, and the reset element 34 are arranged and mounted on the bottom case 312, when the key board 311 is operated, the key board 311 can drive the catapult type ejection power generation device 32 to generate electric energy, the reset element 34 is supported between the catapult type ejection power generation device 32 and the bottom case 312 to reset the catapult type ejection power generation device 32 to return to an initial state, the catapult type ejection power generation device 32 is electrically connected with the signal transmission circuit control module 33 to supply electric energy to the signal transmission circuit control module 33 to transmit a wireless control signal, the retrofitting method comprises the following steps:

(A) electrically connecting the input end 25 of the hidden signal receiving device 2 to a power line hidden in a high-depth command box 8, wherein the high-depth command box 8 is fixedly preset for fixedly mounting the lamp 1;

(B) electrically connecting the output end 26 of the hidden signal receiving device 2 with the lamp 1; and

(C) pairing the hidden reception device 2 and the wireless controller 3.

It is understood that, in the step (a), the input terminal 25 of the hidden signal receiving device 2 is electrically connected to the power line hidden in the high-depth command box 8, and in the state that the hidden signal receiving device 2 is not set in the single-hot-wire power supply structure, the hidden signal receiving device 2 is powered to allow the hidden signal receiving device 2 and the wireless controller 3 to be paired, that is, in some embodiments of the present invention, the step (C) is allowed to be performed before the step (B), which is not a limitation of the present invention, and in the installation implementation method, the sequence and number of the steps do not constitute a limitation of the sequence of the steps of the retrofitting method of the present invention.

It is worth mentioning that the retrofitting method further comprises the steps of:

(D) the hidden signal receiving device 2 is embedded into the high-depth command box 8, and a fixing arm 21 of the hidden signal receiving device 2 is fixed to the high-depth command box 8 in a screw fixing mode in a state that the hidden signal receiving device 2 is embedded into the high-depth command box 8, so that the hidden fixed installation of the hidden signal receiving device 2 on the high-depth command box 8 is formed.

Further, as shown in fig. 4B, in the step (D), after the hidden signal receiving device 2 is installed in the high-depth command box 8, the plane of the box body of the hidden signal receiving device 2 does not exceed the plane of the opening of the high-depth command box 8. In other words, in order not to change the installation form of the lamp 1, the hidden signal receiving device is embedded in the high-depth signaling box 8 and does not protrude from the opening of the high-depth signaling box 8, so as to avoid affecting the installation of the lamp 1. Further, when the luminaire 1 is an existing luminaire installed before the step (a), the method further comprises the steps of: disconnecting the lamp 1 from the power line hidden in the high-depth command box 8; and further comprising, after the step (A), the step (B), the step (C) and the step (D) are completed: and fixedly installing the lamp 1 at the position of the opening of the high-depth command box 8, so that the high-depth command box 8, the hidden signal receiving device 2 and the lamp 1 are arranged in a stacking manner.

Specifically, the step (C) includes the steps of:

(C1) operating the docking button 22 on the hidden signal receiving device 2 to control the hidden signal receiving device 2 to a mated state;

(C2) actuating the key sheet 311 of the wireless controller 3, wherein the key sheet 311 drives the catapult-type catapult power generation device 32, the catapult-type catapult power generation device 32 is driven to generate electric energy and supply the electric energy to the signal transmitting circuit control module 33, and the signal transmitting circuit control module 33 transmits a wireless control signal; and

(C3) the hidden signal receiving device 2 receives and records the identity code and control information corresponding to the wireless controller 3 in the wireless control signal transmitted by the wireless controller 3 to complete the pairing with the wireless controller 3.

It can be understood that the number of the status lights 23 of the hidden signal receiving apparatus 2 can be determined according to the number of the circuit controls of the hidden signal receiving apparatus 2, for example, the wireless controller 3 is a 3-way controller, i.e. has 3 key pads 311, the hidden signal receiving apparatus 2 is connected to control 3 lights, and accordingly the status lights 23 of the hidden signal receiving apparatus 2 can be set to 3, by the operation of the docking button 22, when matching a first light, the first status light 23 flickers, when matching a second light, the second status light 23 flickers, when matching a third light, the third status light 23 flickers, and so on.

Optionally, in the step (C2), the catapult-type catapult power generation device 32 further includes a driving plate 321, an energy storage 323, and a power generator 324, where the driving plate 321 is connected to one end of the energy storage 323, the other end of the energy storage 323 is connected to the power generator 324, and when the key pad 311 is pressed by operation, the driving plate 321 is driven to move, and the driving plate 321 further presses the end of the energy storage 323 connected thereto to accumulate mechanical energy, and releases the mechanical energy accumulated in the energy storage 323 at the instant when the energy storage 323 is full of the mechanical energy, and drives the power generator 324 to move at a high speed, so that the power generator 324 rapidly converts the mechanical energy accumulated in the energy storage 323 into electrical energy, and then supplies the electrical energy to the signal transmission circuit control module 33 to enable the signal transmission circuit to operate normally.

Optionally, after the key pad 311 is pressed, the reset element 34 resets the driving board 321 to an initial state, and the end of the energy accumulator 323 connected to the driving board 321 accumulates mechanical energy again, and releases the accumulated mechanical energy at the moment when the energy accumulator 323 is full of mechanical energy, and drives the generator 324 to move at a high speed, so that the generator 324 generates electric energy again.

Alternatively, the thickness of the wireless controller 3 can be controlled to be less than or equal to 17 mm.

Alternatively, the swing angle of the driving plate 321 can be controlled to be less than or equal to 24 °.

Optionally, the generator 324 is an electromagnetic generator, the generator 324 includes a coil 3241, and the coil 3241 is formed by bonding and winding a self-adhesive wire or glue, so that the coil 3241 can be directly wound and formed, thereby further saving a space occupied by the generator 324 and reducing the thickness of the wireless controller 3.

Alternatively, the generator 324 may be an electromagnetic generator, a piezoelectric element generator, or other mechanical energy harvesting generator.

Optionally, the power consumption of the signal transmission circuit control module 33 is less than 300 μ J.

Preferably, the signal transmitting circuit control module 33 includes a command detecting element 331, a circuit management module, and a control signal transmitting module.

Optionally, the signal transmitting circuit control module 33 further comprises a control lamp 334.

Optionally, in the step (C1), the manipulation lamp 334 is blinked to prompt the user that the matching state has been entered.

It is understood that more than one of the operation lamps 334 may correspond to different operations of different key pads 311.

Optionally, in the step (C3), after the hidden signal receiving apparatus 2 receives the identity code and the control information, the status light 23 presents a special display status, such as changing from blinking to constant brightness or presenting a different color.

According to another aspect of the present invention, the present invention further provides a method for installing and controlling a hidden lighting fixture control device, the hidden lighting fixture control device includes a hidden signal receiving device 2, a high-depth signaling box 8, a lighting fixture 1, and a wireless controller 3, the hidden signal receiving device 2 is configured with a box structure having a size suitable for being embedded in the high-depth signaling box 8, and the method specifically includes the following steps:

a. embedding the high-depth commander box 8 in the ceiling;

b. embedding the hidden signal receiving device 2 into the high-depth command box 8;

c. the lamp 1 is arranged below the hidden signal receiving device 2;

d. electrically connecting an input terminal 25 of the hidden signal receiving device 2 to a power line;

e. electrically connecting an output end 26 of the hidden signal receiving device 2 to the lamp 1;

f. the wireless controller 3 sends a control signal to the hidden signal receiving device 2, so that the hidden signal receiving device 2 can control the working state of the lamp 1.

It is worth mentioning that the arrangement and the number of the steps in the installation and control method do not constitute a limitation to the order of the steps of the retrofitting method of the invention.

It can be understood that, as shown in fig. 4A, fig. 4B and fig. 5, the hidden signal receiving device 2 is embedded in the high-depth command box 8, that is, the hidden signal receiving device 2 is completely accommodated in the high-depth command box 8, so that it does not affect the normal installation of the lamp.

Further, the hidden signal receiving device 2 has at least one fixing arm 21, wherein the fixing arm 21 extends from the box structure and is provided with at least one fixing hole 211.

It can be understood that the fixing arm 21 is fixed inside the high-depth command box 8 through the fixing hole 211 to form a hidden fixed installation of the hidden signal receiving device 2 on the high-depth command box 8.

Further, the wireless controller 3 is configured to be powered by an electromagnetic generator or a piezoelectric generator or other mechanical energy collection generator and send a control signal.

Specifically, the wireless controller 3 includes a housing 31, a catapult-type ejection power generation device 32, a signal transmission circuit control module 33, wherein the housing 31 includes at least a key board 311 and a bottom case 312, wherein the catapult-type ejection power generation device 32 and the signal transmission circuit control module 33 are fixed to the bottom case 312, so that the key board 311 can drive the catapult-type ejection power generation device 32 to generate electric energy when being operated and pressed, and further supply the generated electric energy to the signal transmission circuit control module 33 to transmit the control signal, wherein the catapult-type ejection power generation device 32 includes a driving board 321, an energy storage 323 and a generator 324, the generator 324 is fixed to the bottom case 312, the generator 324 is electrically connected to the signal transmission circuit control module 33, and the generator 324 is connected to one end of the energy storage 323, the other end of the energy accumulator 323 is connected to the driving plate 321, the driving plate 321 is pivotally and swingably fixed to the bottom case 312, so that when the key board 311 is operated and pressed, the key board 311 can drive the driving plate 321, wherein the driving plate 321 is driven to apply pressure to the energy accumulator 323 to deform the energy accumulator 323 to accumulate mechanical potential energy, and after the mechanical potential energy accumulated by the energy accumulator 323 reaches a certain value, one end of the energy accumulator 323 connected to the generator 324 instantaneously drives the generator 324 to generate electric energy to be supplied to the signal transmission circuit control module 33 by using a slingshot effect, wherein the slingshot type catapult power generation device 32 can generate 20 muj to 300 muj of electric energy in one driving and pressing power generation process, wherein the driving plate 321 has a pressing end 3211 to bear the pressure applied to the driving plate 321 by the key board 311, the driving plate 321 further has a supporting end 3212 to support the driving plate 321 to swing pivotally, and a swing angle of the driving plate 321 is smaller than 24 °;

the generator 324 is an electromagnetic generator and comprises a coil 3241, an iron core 3242 and a magnetic group 3244, the coil 3241 is sleeved on the iron core 3242, and the time of one relative movement between the iron core 3242 and the magnetic group 3244 is less than 1/50 seconds.

It should be noted that the driving plate 321 has a pressing end 3211, a connecting end 3215 and a supporting end 3212, the driving plate 321 can pivotally swing around a pivot formed by the supporting end 3212, and a ratio of a length of the pressing end 3211 from the pivot to a length of the connecting end 3215 from the pivot is greater than 1, so as to save a driving force by at least 10% by using a labor-saving design of the driving plate 321.

In particular, the concealed signal receiving device 2 is designed to be shell-shaped, semicircular, square or circular, so as to facilitate installation and make full use of the space inside the tall and deep command box 8.

In particular, the hidden signal receiving device 2 is provided with a docking button 22, and in a state that the hidden signal receiving device 2 is hidden and fixedly installed in the high-depth command box 8, the docking button 22 is arranged in the box structure in a direction towards the lamp 1, so as to facilitate installation and debugging.

In particular, the docking button 22 is provided to allow to be operated in a state in which the light fixture 1 is not fixed to the high-depth signaling box 8 or to a position below the opening of the high-depth signaling box 8 or to the ceiling 7, to enable the control of the state of the light fixture 1.

In detail, the direct control of the state of the lamp 1 is realized through the docking button 22, so that the input end 25, the power line and the output end 26 of the hidden signal receiving device 2 are electrically connected to the lamp 1, and whether the control of the hidden signal receiving device 2 on the lamp 1 is normal is tested, so as to determine whether to continue the next installation and debugging.

It is understood by those skilled in the art that the embodiments of the present invention described above and shown in the drawings are given by way of example only and are not limiting of the present invention, which can be combined as desired within the inventive concept. The objects of the invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the examples, and any variations or modifications of the embodiments of the present invention may be made without departing from the principles.

Claims (13)

1. Wireless control lamps and lanterns, its characterized in that includes:

a light fixture, wherein said light fixture is adapted to be ceiling mounted;

a wireless controller, wherein the wireless controller is configured in a self-powered mode and is enabled to be activated to send a control signal; and

a hidden signal receiving device, wherein the hidden signal receiving device is paired with the wireless controller to receive the control signal sent by the wireless controller and control the lamp according to the control signal, and is provided with a box body structure with a size suitable for embedding a high-depth command box, so that the installation control of the lamp without damage is realized when the hidden signal receiving device is embedded into the high-depth command box and the lamp is installed in a ceiling-mounted manner to shield the high-depth command box;

wherein the thickness of the wireless controller is less than or equal to 17 mm, the wireless controller comprises a shell, a slingshot type ejection power generation device, a signal transmission circuit control module and a reset element, wherein the shell comprises at least a key board and a bottom shell, a plurality of pressing protrusions are arranged on the inner side of the key board, the slingshot type ejection power generation device, the signal transmission circuit control module and the reset element are fixed on the bottom shell, so that the key board can drive the slingshot type ejection power generation device to generate electric energy through the pressing protrusions when being operated and pressed, the generated electric energy is further supplied to the signal transmission circuit control module to send the control signal, the slingshot type ejection power generation device comprises a driving board, an energy storage device and a generator, and the generator is fixed on the bottom shell, the generator is electrically connected with the signal emission circuit control module, the generator is connected with one end of the energy accumulator, the other end of the energy accumulator is connected with the driving plate, the driving plate is pivotally and swingably fixed on the bottom case, so that when the key board is operated and pressed, the corresponding pressing protrusions of the key board can drive the driving plate, the driving plate is driven to apply pressure to the energy accumulator to enable the energy accumulator to generate deformation and accumulate mechanical potential energy, and after the mechanical potential energy accumulated by the energy accumulator reaches a certain value, one end of the energy accumulator connected with the generator instantly drives the generator to move by utilizing a slingshot effect to generate electric energy to be supplied to the signal emission circuit control module, wherein the slingshot type catapult power generation device can generate 20 muJ-300 muJ electric energy in one driving and pressing power generation process, the driving plate is provided with a pressing end for bearing the pressure applied to the driving plate by the key plate, the driving plate is also provided with a supporting end for supporting the driving plate to swing pivotally, the swing angle of the driving plate is smaller than 24 degrees, the generator comprises a coil, an iron core and a magnetic group, the iron core is sleeved with the coil, the time of one relative movement of the iron core and the magnetic group is less than 1/50 seconds, the driving plate is provided with a pressing end, a connecting end and a supporting end, the driving plate swings pivotally by taking a rotating shaft formed by the supporting end as a fulcrum, and the ratio of the length of the pressing end to the fulcrum to the length of the connecting end to the fulcrum is greater than 1.

2. The wireless control lamp as claimed in claim 1, wherein the hidden signal receiving device is configured as a box structure having a size suitable for being embedded in the high-depth command box and comprises at least a fixed arm, an antenna, an input end and an output end, wherein the fixing arm extends from the box structure and is provided with at least one fixing hole so as to be designed based on a nut structure inherent in the high-depth command box, in the state that the hidden signal receiving device is embedded into the high-depth command box, the fixing hole is fixed inside the high-depth command box in a screw fixing mode to form hidden fixed installation of the hidden signal receiving device on the high-depth command box, the input end is electrically connected with a power line concealed in the high-depth command box, and the output end is electrically connected with the lamp.

3. The wireless control light fixture of claim 2 wherein the antenna is biased away from the box structure in the direction of attachment of the attachment arm.

4. The wireless control light fixture of claim 2, wherein the hidden signal receiving device further comprises a docking button, wherein the docking button is configured to be operated to control the hidden signal receiving device to a mated state suitable for completing the mating of the hidden signal receiving device with the wireless controller in the mated state, and wherein the docking button is configured on the box structure in a direction opposite to the fixing direction of the fixing arm, corresponding to a state where the docking button faces the installation position of the light fixture.

5. The wireless control lamp as claimed in any one of claims 1 to 4, wherein the reset element is supported between the driving board and the bottom case, so that the driving board can be restored to an initial state after being pressed and driven by the keypad, and the generator can generate 20 μ J-300 μ J of power again when being reset.

6. The wireless control lamp as claimed in any one of claims 1 to 4, wherein the driving board further has a receiving slot for receiving the generator, and the driving board is a metal plate formed integrally.

7. A method for installing and controlling a hidden lamp control device, the hidden lamp control device comprises a hidden signal receiving device, a high-depth command box, a lamp and a wireless controller, wherein the hidden signal receiving device is configured to have a box structure with a size suitable for being embedded into the high-depth command box, the wireless controller is configured in a self-powered mode and allows to be activated to send a control signal, the wireless controller comprises a housing, a catapult-type ejection power generation device, a signal transmission circuit control module, the housing comprises at least a key board and a bottom shell, the catapult-type ejection power generation device and the signal transmission circuit control module are fixed on the bottom shell, so that the catapult board can drive the catapult-type power generation device to generate electric energy when being pressed by operation, and then supplying the generated electric energy to the signal transmitting circuit control module to send the control signal, wherein the slingshot type ejection power generation device comprises a driving plate, an energy accumulator and a generator, the generator is fixed on the bottom shell, the generator is electrically connected with the signal transmitting circuit control module, the generator is connected with one end of the energy accumulator, the other end of the energy accumulator is connected with the driving plate, the driving plate is pivotally and swingably fixed on the bottom shell, so that when the key plate is operated and pressed, the key plate can drive the driving plate, the driving plate is driven to apply pressure to the energy accumulator to enable the energy accumulator to generate deformation and accumulate mechanical potential energy, and after the mechanical potential energy accumulated by the energy accumulator reaches a certain value, one end of the energy accumulator connected with the generator instantly drives the generator to generate electric energy by utilizing a slingshot effect to supply the electric energy to the signal generating device The transmission circuit control module, wherein the slingshot type catapult power generation device can generate 20 muJ-300 muJ of electric energy in a driving and pressing power generation process, the driving plate is provided with a pressing end to bear the pressure applied to the driving plate by the key plate, the driving plate is also provided with a supporting end to support the driving plate to swing pivotally, the swing angle of the driving plate is less than 24 degrees, the power generator is an electromagnetic power generator and comprises a coil, an iron core and a magnetic group, the coil is sleeved on the iron core, the time of one relative motion of the iron core and the magnetic group is less than 1/50 seconds, and the installation and control method comprises the following steps:

a. embedding the high-depth commander box in a ceiling;

b. embedding the hidden signal receiving device into the high-depth command box;

c. installing the lamp below the hidden signal receiving device;

d. electrically connecting an input end of the hidden signal receiving device to a power line;

e. electrically connecting an output end of the hidden signal receiving device to the lamp;

f. the wireless controller sends a control signal to the hidden signal receiving device, so that the hidden signal receiving device can control the working state of the lamp.

8. The mounting and control method of claim 7, wherein the hidden signal receiving device has at least one fixed arm, wherein the fixed arm extends from the box structure and is provided with at least one fixed hole.

9. The mounting and control method according to claim 8, wherein the fixing arm is fixed inside the high-depth command box through the fixing hole to form a hidden fixed mounting of the hidden signal receiving device on the high-depth command box.

10. The mounting and control method according to claim 7, wherein the driving plate has a pressing end, a connecting end and a supporting end, the driving plate is pivotally swung with a rotating shaft formed at the supporting end as a fulcrum, and a ratio of a length of the pressing end from the fulcrum to a length of the connecting end from the fulcrum is greater than 1.

11. The mounting and control method according to claim 7, wherein the hidden signal receiving device is designed to be shell-shaped, semicircular, square or circular to facilitate mounting and fully utilize the space inside the high-depth command box.

12. The installation and control method as claimed in claim 7, wherein the hidden signal receiving device is provided with a docking button, and the docking button is arranged on the box structure in a direction towards the light fixture in a hidden and fixed installation state of the hidden signal receiving device on the high-depth signaling box, so as to facilitate installation and debugging.

13. The mounting and control method according to claim 12, wherein the docking button is operated in a state where the light fixture is not fixed to the high-depth signaling box or a position below the high-depth signaling box opening or the ceiling to achieve state control of the light fixture.

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