TWM583968U - Modular kinetic energy scenario panel control device for smart integrated control system - Google Patents

Abstract

A modular kinetic energy situation panel control device includes an automatic power generation wireless remote control and a radio frequency conversion transmitter. The automatic power generation wireless remote control includes a housing, a pressing portion, a micro-generator, and a radio frequency module. The micro-generator generates an induced current that energizes the radio frequency module and transmits a radio frequency signal. The RF conversion transmitter includes a casing, a signal receiving unit, a signal conversion unit, and a signal transmitting unit. The signal receiving unit receives the wireless radio frequency signal. The signal conversion unit converts the wireless RF signal into an electronic device control signal. The signal transmitting unit transmits the electronic device control signal to the central gateway processing device. In this way, the automatic power generation wireless remote control can be easily carried without power supply. The frequency band of the used radio frequency signal is RF433 MHz, the frequency is low, the wavelength is long, the range is over 50 meters, and the power consumption is small.

Description

Modular kinetic situation panel control device for intelligent integrated control system

The present invention relates to a remote control device, and more particularly to a modular kinetic situation panel control device for a smart integrated control system.

Electrical appliances are usually plugged into the socket with a plug of the power cord to obtain power from the mains supply. Therefore, indoor spaces of today's buildings, such as houses or offices, are provided with a plurality of outlets.

Furthermore, the indoor space usually has a plurality of switches that are respectively connected to different load elements to switch the power state of each load element to be turned on or off.

However, for the user, when the number of sockets, switches, and electrical appliances is large, it is often forgotten to remove the plug of the unused electrical appliance from the socket, or forget to turn off the switch of the unused load component or electronic product. It is difficult to effectively control the power state of all the sockets and all the switches, thus causing waste of electric energy.

In addition, due to the development of technology, the daily life is more convenient. Generally, electronic devices such as televisions and air conditioners usually have a remote controller that can control electronic devices. The remote control is provided with a plurality of buttons for the user to select and press. These buttons usually have a considerable amount in order to achieve a variety of control functions. However, when the remote control is actually used, the number of buttons is complicated and complicated, and the user often has to find the position of the button to be pressed, which increases the user's troubles. In addition, since the remote control is often placed at random, it is often troublesome to find the remote control. Therefore, the conventional remote control design is quite inhuman.

Furthermore, with the development of wireless communication/transmission technology, wireless remote control methods between an electronic device and its associated remote control have also been extensively studied. Conventional technology, such as a general remote control, its software and hardware use functions are first set at the manufacturing end, and can not be set separately according to the needs at the use end, for example, a television and its remote control form a one-to-one correspondence state. The TV can only be turned on with this remote control. Since the use end can not be set separately according to the need, the manufacturing cost of the remote controller is increased and the use end is inconvenient. For example, if there are various devices such as a lighting device, an air conditioner or an audio device in the home, the manufacturing end must be made more. A matching remote control, so the production cost is relatively improved.

Also, the conventional remote control utilizes the power supply of the battery to supply its internal components. Once the battery is dead, the battery must be replaced, which is very troublesome.

Moreover, the conventional remote controller emits a signal with a high frequency, a short wavelength, a transmission distance of less than fifty meters, and a large power consumption.

The wired control unit solves the problem of the remote control, but it needs to be routed through the wall and cannot be carried.

The main purpose of this creation is to provide a modular kinetic situation panel control device for intelligent integrated control system, which can be easily carried, can convert mechanical energy into electric energy, achieve self-power generation effect, without battery, and without wall wiring .

Another object of the present invention is to provide a modular kinetic situation panel control device for a smart integrated control system, which has a low frequency, a long wavelength, a transmission distance of more than fifty meters and a low power consumption. Etc.

Another object of the present invention is to provide a modular kinetic situation panel control device for a smart integrated control system, which can remotely switch all power outlets of a certain area, switches, and all electronic components in a specific area at the same time. The mode of operation of the device.

A further object of the present invention is to provide a modular kinetic situation panel control device for a smart integrated control system, which can dynamically edit the interactive function of the electronic device and the original creation, and solve the conventional remote control with absolute control relationship. The flexible change button corresponds to the function of controlling the operation mode of the electronic device.

In order to achieve the foregoing objectives, the present invention will provide a modular kinetic situation panel control device for a smart integrated control system, the intelligent integrated control system including a central gateway processing device, and the central gateway processing device by wireless communication The agreement connects a plurality of electronic devices and controls the mode of operation of the electronic devices. The modular kinetic energy context panel control device includes an automatic power generation wireless remote control and a radio frequency conversion transmitter.

The automatic power generation wireless remote control comprises a casing, a plurality of pressing portions, a plurality of micro-generators and a radio frequency module, wherein the pressing portions are movably disposed on the casing, and each of the micro-generators comprises a coil group and a magnet group. The coil groups are respectively disposed inside the casing, and the magnet groups are respectively disposed at the bottom of the pressing portions and located outside the coil groups, and each pressing portion drives each magnet group to be displaced relative to each coil group. When the position is between a second position, each coil group generates an induced current, and the wireless RF module is disposed inside the casing, and is electrically connected to the coil groups for receiving the induced current generated by each coil group and being energized. And send a wireless RF signal outward.

The RF conversion transmitter includes a casing, a signal receiving unit, a signal conversion unit and a signal transmitting unit. The signal receiving unit is disposed inside the casing, wirelessly connects to the radio frequency module, and is configured to receive the radio frequency signal and the signal conversion unit. Inside the casing, the signal receiving portion is electrically connected to receive the wireless RF signal transmitted from the signal receiving portion, and convert the wireless RF signal into an electronic device control signal, and the signal transmitting portion is disposed inside the casing, and the electrical connection signal is converted. The unit is configured to receive the electronic device control signal transmitted from the signal conversion unit, and transmit the electronic device control signal to the central gateway processing device by using a wireless communication protocol.

Preferably, the modular kinetic scenario panel control device for the intelligent integrated control system further includes a context setting device, wherein the context setting device comprises a body, a processing module, a storage module, and a display a module, an edit setting module and a wireless transmission module, the processing module is disposed inside the body, the storage module is disposed in the body, electrically connected to the processing module, and stores a plurality of context information, the situation information The display module is disposed on the outer surface of the main body, and the display module is electrically connected to the processing module. The editing setting module is disposed inside the main body, electrically connected to the processing module, and outputs a setting interface and a Editing interface to display module, setting interface for displaying the situation information, editing interface providing editing function to edit the situation information, wireless transmission module is disposed inside the body, electrically connected to the processing module, and Transmitting the completed situation information to the central gateway processing device by means of a wireless communication protocol, and the central gateway processing device will complete the edited situation information and the same Into a plurality of signal integrating means for controlling the operating mode signal, the central processing unit is further gateway by such operation mode control signal into the operating mode of such electronic devices.

Preferably, the wireless communication protocol is ZigBee, infrared, Bluetooth, WiFi or ultra-wideband.

Preferably, the automatic power generation wireless remote control further includes a plurality of protective covers respectively disposed inside the casing and opening an opening, the coil sets are respectively located inside the protective covers, and the magnet sets are respectively located in the protection The outside of the opening of the cover.

Preferably, the automatic power generation wireless remote control further comprises a cover plate, the cover plate is disposed inside the casing, and the radio frequency module is disposed under the cover plate.

Preferably, each of the coil sets includes a spring piece, an iron core and a wire. One ends of the elastic pieces are respectively fixed to the casing, and the iron cores are respectively connected to the other ends of the elastic pieces, thereby being suspended. The wires are electrically connected to the radio frequency module and wound around the outer surfaces of the cores to form a plurality of coils.

Preferably, each magnet group is disposed on the outer side of each iron core and includes a set of joints, a permanent magnet, an upper magnetic conductive plate and a lower magnetic conductive plate, wherein the assembly portions of the magnet groups are respectively disposed on the magnet core a bottom portion of the first ends of the pressing portion and located outside the coil groups, the assembly portion of each magnet group enclosing a groove, and opening an opening on a side facing each coil group, each magnet group The upper magnetic plate is disposed on the top of the permanent magnets disposed on the magnet groups, and the lower magnetic plates of each magnet group are disposed at the bottom of the permanent magnets of each magnet group, the permanent magnets, the upper magnetic plates and the lower guides of each magnet group The magnetic plates are simultaneously located in the grooves of the assembly portions of the magnet groups. Under the action of the permanent magnets of the magnet groups, the upper magnetic plates of the magnet groups are different from the magnetic poles of the lower magnetic plates of the respective magnet groups; When the magnet groups are displaced upward to the first position, the iron core of each coil group is aligned with the lower magnetic conductive plates of each magnet group, and a center line of the coils of each coil group and a lower magnetic conductive plate of each magnet group An axis overlap; wherein, when each magnet group is displaced downward to the second position, each line The iron cores of the group are aligned with the upper magnetic plates of the magnet groups, and the center lines of the coils of the coil groups overlap with an axis of the upper magnetic plates of each magnet group; and wherein each pressing portion drives each magnet group relative to each other When the iron core of each coil group is displaced between the first position and the second position, the magnetic field of the iron core of each coil group is changed, so that the wires of the coils of the respective coil groups generate an induced current.

Preferably, the housing is provided with a plurality of sliding rails, and two sliders are respectively protruded on two sides of the assembly portions of the magnet groups, and the sliders of the assembly portions are respectively slidably disposed in the sliding rails; Two hook portions are respectively protruded on two sides of the bottom portion of the first end of each pressing portion, and two blocks are respectively protruded on two sides of the assembly portion of each magnet group, and the two hook portions of each pressing portion are respectively hooked on each The two blocks of the assembly of the magnet group.

Preferably, the frequency band of each radio frequency signal is RF433 MHz.

Preferably, the radio frequency module includes a circuit board, a plurality of diode rectifying members, and a plurality of radio frequency components. The circuit board is disposed inside the casing, and the diode rectifying members are respectively disposed on the circuit board and electrically connected to the coil groups. And receiving the induced current generated by the coil groups, and rectifying the received induced current, thereby maintaining the correct polarity of the induced current, and the RF components are electrically connected to the diode rectifiers respectively for receiving the rectified The induced current is energized, so that the RF components respectively transmit a wireless RF signal.

The effect of this creation is that the automatic power generation wireless remote control can be easily carried, and the mechanical energy can be converted into electric energy to achieve the effect of self-generation, without the need of a battery, and without the need for wall wiring.

Secondly, the wireless radio frequency signal sent by the automatic power generation wireless remote control has the advantages of low frequency, long wavelength, transmission distance exceeding 50 meters and low power consumption.

Furthermore, the author can simultaneously remotely switch all outlets in a particular area, the power state of the switch, and control the mode of operation of all electronic devices within a particular area.

In addition, the situation setting device can dynamically edit the interactive function of the electronic device and the automatic power generation wireless remote control, and solve the problem that the conventional remote controller has an absolute control relationship, and cannot flexibly change the operation mode of the button corresponding to the control electronic device.

The implementation of the present invention will be described in more detail below with reference to the drawings and component symbols, so that those skilled in the art can implement the present specification after studying the present specification.

Please refer to FIG. 1 , which is a perspective view of the creation. The present invention provides a modular kinetic situation panel control device 1 for an intelligent integrated control system, comprising an automatic power generation wireless remote control 10 and a radio frequency conversion transmitter 20 .

As shown in FIG. 1 to FIG. 3, the automatic power generation wireless remote control 10 includes a casing 11, a plurality of pressing portions 121, 122, 123, a plurality of micro-generators 13, 14, 15 and a radio frequency module 16. As shown in FIGS. 1 to 3, the pressing portions 121, 122, 123 are movably provided on the casing 11. As shown in FIG. 2, FIG. 3 and FIG. 6 to FIG. 10, each of the micro-generators 13, 14, 15 includes a coil group 131, 141, 151 and a magnet group 132, 142, 152, and the coil groups 131, 141. The 151s are respectively disposed inside the casing 11, and the magnet groups 132, 142, and 152 are respectively disposed at the bottoms of the pressing portions 121, 122, and 123 and outside the coil groups 131, 141, and 151. As shown in FIG. 2, FIG. 9, and FIG. 10, each of the pressing portions 121, 122, and 123 drives the magnet groups 132, 142, and 152 to be displaced from a first position and a second position with respect to each of the coil groups 131, 141, and 151. In between, each coil group 131, 141, 151 generates an induced current. The radio frequency module 16 is disposed inside the casing 11 and electrically connected to the coil groups 131, 141, and 151 for receiving the induced current generated by each coil group 131, 141, and 151 to be energized, and transmitting a wireless unit. RF signal.

As shown in FIG. 1 and FIG. 2, the RF conversion transmitter 20 includes a housing 21, a signal receiving unit 22, a signal converting unit 23, and a signal transmitting unit 24. The signal receiving unit 22 is disposed inside the casing 21, wirelessly connects to the radio frequency module 16, and is configured to receive the radio frequency signal. The signal conversion unit 23 is disposed inside the casing 21 and electrically connected to the signal receiving unit 22 for receiving the wireless RF signal transmitted from the signal receiving unit 22 and converting the wireless RF signal into an electronic device control signal. The signal transmitting unit 24 is disposed inside the casing 21, and is electrically connected to the signal converting unit 23 for receiving the electronic device control signal transmitted from the signal converting unit 23, and transmitting the electronic device control signal to a central gate by using a wireless communication protocol. Track processing device 2.

As shown in FIG. 1 and FIG. 3, in the preferred embodiment, the housing 11 includes a base 111 and an outer frame 112. One accommodating groove is recessed on one side of the top of the base 111, and one accommodating groove is recessed in the middle of the other side of the top of the pedestal 111. The radio frequency module 16 is disposed in a middle receiving groove on one side of the top of the base 111. The automatic power generation wireless remote control 10 includes three micro-generators 13, 14, 15 , wherein the coil sets 131 and 141 of the two micro-generators 13 and 14 are respectively fixed to the other two receiving slots on one side of the top of the base 111 The coil set 151 of the other micro-generator 15 is fixed in the middle of the accommodating groove on the other side of the top of the susceptor 111. The top of the base 111 has four pivoting portions 1111 and four pivots 1112. The pivoting portions 1111 are sequentially arranged along an axis along the longitudinal direction of the base 111. The pivots 1112 are respectively disposed on the first pivoting portions 1111. The pivoting portion 1111 is on. As shown in FIG. 1 , FIG. 3 and FIG. 4 , the self-generating wireless remote control includes three pressing portions 121 , 122 , and 123 , and two pivoting arms 124 are respectively protruded from the bottom sides of each of the pressing portions 121 , 122 , and 123 . 124 opens a pivot hole 1241. The two pivots 1112 of the adjacent two pivoting portions 1111 pass through the pivot holes 1241 of the two pivots 124 of one of the pressing portions 121, 122, 123, so that the pressing portions 121, 122, 123 can surround the first pivoting portions 121, 122, 123. The pivot 1112 rotates so that each of the pressing portions 121, 122, and 123 becomes a seesaw. As shown in FIG. 5, the magnet groups 132, 142, and 152 are respectively disposed at the bottoms of the first ends 1211, 1221, and 1231 of the pressing portions 121, 122, and 123. As shown in FIG. 1 and FIG. 3, the outer frame 112 is disposed around the top of the base 111, and the pressing portions 121, 122, 123 are restrained on the base 111 to avoid the pressing portions 121, 122, 123 is separated from the base 111.

As shown in FIG. 3, the automatic power generation wireless remote control 10 further includes three protective covers 171, 172, 173 and a cover plate 174. The two protective covers 171 and 173 are respectively disposed in the other two receiving slots on one side of the top of the base 111 and open an opening, and the other protective cover 172 is disposed in the middle of the other side of the top of the base 111. Set in the slot and open an opening. The coil groups 131, 141, and 151 are respectively located inside the protective covers 171, 172, and 173, and the magnet groups 132, 142, and 152 are located outside the openings of the protective covers 171, 172, and 173, respectively. The cover plate 174 is disposed in a middle receiving groove on one side of the top of the base 111, and the radio frequency module 16 is disposed under the cover plate 174. Thereby, the protective covers 171, 172, 173 can protect the coil sets 131, 141, 151 from the external environment, and the cover 174 can protect the radio frequency module 16 from external environment.

As shown in FIG. 3, FIG. 6, FIG. 9 and FIG. 10, each coil group 131, 141, 151 includes a spring piece 1311, 1411, 1511, a core 1312, 1412, 1512 and a wire 1313, 1413, 1513. One ends of the two elastic pieces 1311 and 1411 are respectively fixed in the other two receiving grooves on one side of the top of the base 111, and one end of the other elastic piece 1511 is fixed in the middle of the other side of the top of the base 111. It is accommodated in the slot. The cores 1312, 1412, and 1512 are respectively connected to the other ends of the elastic pieces 1311, 1411, and 1511 so as to be in a state of being suspended. The wires 1313, 1413, and 1513 are electrically connected to the radio frequency module 16 and wound around the outer surfaces of the cores 1312, 1412, and 1512 to form a plurality of coils 1314, 1414, and 1514.

As shown in FIG. 3 to FIG. 10, each magnet group 132, 142, 152 is disposed outside each of the cores 1312, 1412, 1512 and includes a set of joints 1321, 1421, 1521, a permanent magnet 1322, 1422, 1522. An upper magnetic conductive plate 1323, 1423, 1523 and a lower magnetic conductive plate 1324, 1424, 1524. The assembly portions 1321, 1421, and 1521 of the magnet groups 132, 142, and 152 are respectively disposed at the bottoms of the first ends 1211, 1221, and 1231 of the pressing portions 121, 122, and 123, and are located at the bottoms of the first ends 1211, 1221, and 1231 of the pressing portions 121, 122, and 123, respectively. The outer sides of the coil groups 131, 141, and 151. Each of the joint portions 1321, 1421, 1521 surrounds a groove 1325, 2425, 1525, and an opening 1326, 1426, 1526 is opened on a side facing each coil group 131, 141, 151. The upper magnetic conductive plates 1323, 1423, and 1523 of the magnet groups 132, 142, and 152 are disposed at the top of the permanent magnets 1322, 1422, and 1522 of the respective magnet groups 132, 142, and 152, and the lower guides of the magnet groups 132, 142, and 152. The magnetic plates 1324, 1424, and 1524 are disposed at the bottoms of the permanent magnets 1322, 1422, and 1522 of the magnet groups 132, 142, and 152, and the permanent magnets 1322, 1422, and 1522 of the magnet groups 132, 142, and 152, and the upper magnetic plate 1323. The 1423, 1523 and lower magnetic plates 1324, 1424, 1524 are simultaneously located in the grooves 1325, 2425, 1525 of the assembly portions 1321, 1421, 1521 of the respective magnet groups 132, 142, 152. As shown in FIGS. 9 and 10, under the action of the permanent magnets 1322, 1422, and 1522 of the respective magnet groups 132, 142, and 152, the upper magnetic conductive plates 1323, 1423, and 1523 of the respective magnet groups 132, 142, and 152 are respectively The magnetic poles of the lower magnetic plates 1324, 1424, and 1524 of the magnet groups 132, 142, and 152 are different.

As shown in FIG. 3 and FIG. 6 , the other two receiving slots on one side of the top of the base 111 and the middle receiving recesses on the other side of the bottom of the base 111 respectively protrude from the two sliding rails 1113 . As shown in FIG. 5 to FIG. 8 , two sliders 1327 , 1427 , 1527 are respectively protruded on two sides of the assembly portions 1321 , 1421 , 1521 of the magnet groups 132 , 142 , and 152 , and the assembly portions 1321 , 1421 . The sliders 1327, 1427, and 1527 of the 1521 are respectively slidably disposed in the slide rails 1113. As shown in FIGS. 4 and 5, two hook portions 125 are respectively protruded from the two sides of the bottom ends of the first ends 1211, 1221, and 1231 of the pressing portions 121, 122, and 123, respectively. As shown in FIGS. 5, 7, and 8, two blocks 1328, 1428, and 1528 are respectively protruded from the two sides of the joint portions 1321, 1421, and 1521 of the respective magnet groups 132, 142, and 152. As shown in FIG. 5, the two hook portions 125 of the pressing portions 121, 122, and 123 are respectively hooked on the two blocks 1328 and 1428 of the assembling portions 1321, 1421, and 1521 of the magnet groups 132, 142, and 152, 1528.

The cores 1312, 1412, 1512 have two functions, namely magnetic conduction and magnetic field commutation. As shown in FIGS. 9 and 10, it is assumed that the magnetic poles of the lower magnetic conductive plates 1324, 1424, and 1524 are S poles, and the magnetic poles of the upper magnetic conductive plates 1323, 1423, and 1523 are N poles.

As shown in FIG. 11 , after the user presses a second end 1212 , 1222 , 1232 of each of the pressing portions 121 , 122 , 123 , the pressing portions 121 , 122 , 123 can rotate around the pivot 1112 , so that each pressing portion The second ends 1212, 1222, and 1232 of 121, 122, and 123 are downward, and the first ends 1211, 1221, and 1231 of the pressing portions 121, 122, and 123 are upward, and the pressing portions 121, 122, and 123 can pass through the two hooks. The portion 125 drives the magnet groups 132, 142, 152 to be displaced upwardly relative to the respective coil groups 131, 141, 151 to the first position by the blocks 1328, 1428, 1528 sliding upward along the slide rails 1113. As shown in FIG. 9, when the magnet groups 132, 142, 152 are displaced upward to the first position, the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 are aligned with the magnet groups 132, 142, and 152. The lower magnetic plates 1324, 1424, and 1524 are simultaneously overlapped with a center line of the coils of the respective coil groups 131, 141, and 151 and an axis of the lower magnetic plates 1324, 1424, and 1524 of the respective magnet groups 132, 142, and 152. In the present embodiment, the end faces of the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 are brought into contact with the end faces of the lower magnetic plates 1324, 1424, and 1524 of the respective magnet groups 132, 142, and 152. Since the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 have magnetic permeability, the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 are equivalent to extending the lower magnetic plates 1324 and 1424. , the length of 1524. Therefore, the magnetic induction line of the magnetic field passes through the coils 1314, 1414, and 1514, and the direction of the magnetic induction line can be approximated as N-S, that is, the core 1312, 1412 passing through each coil group 131, 141, 151. The direction of the magnetic induction line in 1512 is from A to B.

The attraction between the magnet groups 132, 142, and 152 and the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 attracts the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 upward. The elastic pieces 1311, 1411, and 1511 of the respective coil groups 131, 141, and 151 are deformed upward to store potential energy. When each of the magnet groups 132, 142, and 152 continues to move upward, the attraction between each of the magnet groups 132, 142, and 152 and the cores 1312, 1412, and 1512 of each of the coil groups 131, 141, and 151 and the respective coil groups 131 and 141 When the reaction force of the elastic pieces 1311, 1411, and 1511 of 151 exceeds the critical point, the elastic pieces 1311, 1411, and 1511 of the respective coil groups 131, 141, and 151 drive the cores of the respective coil groups 131, 141, and 151 at an extremely high speed. 1312, 1412, 1512 rebound, and then achieve the effect of rapid switching of magnetic poles and rapid cutting of magnetic lines 1314, 1414, 1514.

As shown in FIG. 11 , after the user presses the first ends 1211 , 1221 , and 1231 of the pressing portions 121 , 122 , and 123 , the pressing portions 121 , 122 , and 123 can rotate around the pivot 1112 such that the pressing portions 121 . The first ends 1211, 1221, and 1231 of the 122, 123 are downward, and the second ends 1212, 1222, and 1232 of the pressing portions 121, 122, and 123 are upward, and the first ends 1211 and 1221 of the pressing portions 121, 122, and 123 are upward. 1231 can drive each of the magnet groups 132, 142, and 152 to be displaced downward to the second position with respect to each of the coil groups 131, 141, and 151. As shown in FIG. 10, when the magnet groups 132, 142, 152 are displaced downward to the second position, the cores 1312, 1412, 1512 of the coil groups 131, 141, 151 are aligned with the magnet groups 132, 142, 152. The upper magnetic conductive plates 1323, 1423, 1523, and the center lines of the coils 1314, 1414, 1514 of the coil groups 131, 141, 151 and the upper magnetic conductive plates 1323, 1423, 1523 of the respective magnet groups 132, 142, 152 One axis overlaps. More specifically, the positions between the magnet groups 132, 142, and 152 and the cores 1312, 1412, and 1512 of the respective coil groups 131, 141, and 151 are relatively changed, and the core 1312 of each of the coil groups 131, 141, and 151. 1412, 1512 jump from one side of the lower magnetic plates 1324, 1424, 1524 of each of the magnet groups 132, 142, 152 to one side of the upper magnetic plates 1323, 1423, 1523 of each of the magnet groups 132, 142, 152, from S pole jumps to the N pole. The cores 1312, 1412, and 1512 of the respective coil groups 131, 141, and 151 are instantaneously attracted to the upper magnetic conductive plates 1323, 1423, and 1523 of the respective magnet groups 132, 142, and 152, and the coil groups 131, 141, and 151 are The end faces of the iron cores 1312, 1412, and 1512 are in contact with the end faces of the upper magnetic conductive plates 1323, 1423, and 1523 of the respective magnet groups 132, 142, and 152. Since the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 have magnetic conduction, the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 are equivalent to extending the magnet groups 132 and 142, The length of the upper magnetic plates 1323, 1423, 1523 of 152. Therefore, the magnetic flux passes through the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 and the N poles, and the magnetic cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 are magnetic. The direction of the line of sight can be approximated as S-N, that is, the direction of the magnetic line in the cores 1312, 1412, 1512 passing through each of the coil groups 131, 141, 151 is from B to A.

The attraction between each of the magnet groups 132, 142, and 152 and the cores 1312, 1412, and 1512 of each of the coil groups 131, 141, and 151 attracts the cores 1312, 1412, and 1512 of each of the coil groups 131, 141, and 151 to move downward. The elastic pieces 1311, 1411, and 1511 of the coil groups 131, 141, and 151 are deformed downward to store potential energy. When the magnet groups 132, 142, and 152 continue to move downward, the attraction between the magnet groups 132, 142, and 152 and the cores 1312, 1412, and 1512 of the coil groups 131, 141, and 151 and the coil groups 131, When the reaction forces of the elastic pieces 1311, 1411, and 1511 of 141 and 151 exceed the critical point, the elastic pieces 1311, 1411, and 1511 of the respective coil groups 131, 141, and 151 drive the iron of each of the coil groups 131, 141, and 151 at an extremely high speed. The cores 1312, 1412, and 1512 rebound, thereby achieving the effect of rapid switching of the magnetic poles and rapid cutting of the magnetic induction lines 1314, 1414, and 1514.

During the displacement of the magnet groups 132, 142, 152 from the first position to the second position, the magnet groups 132, 142, 152 and the cores 1312, 1412, 1512 of the coil groups 131, 141, 151 The relative positional change between the core lines 1312, 1412, and 1512 of each of the coil groups 131, 141, and 151 is reversed, and the cores 1312 and 1412 of the coil groups 131, 141, and 151 are reversed. The direction of the magnetic field in 1512 is suddenly changed from S-N by the previous N-S, and the change of the magnetic line in the cores 1312, 1412, and 1512 of each coil group 131, 141, 151 is wound around each coil group 131, The coils 1314, 1414, and 1514 outside the cores 1312, 1412, and 1512 of 141, 151 generate a first induced current 133, 143, 153. During the displacement of the magnet groups 132, 142, 152 from the second position to the displacement between the first positions, the relative positions between the magnet groups 132, 142, 152 and the cores 1312, 1412, 1512 change, such that The directions of the magnetic lines of the cores 1312, 1412, 1512 are reversed, and the direction of the magnetic field in the cores 1312, 1412, 1512 suddenly changes from the previous S-N to N-S, in the cores 1312, 1412, 1512 The change in the magnetic line of inductance causes a second induced current 134, 144, 154 to be generated by the coils 1314, 1414, 1514 wound around the cores 1312, 1412, 1512.

As shown in FIG. 2 and FIG. 3, the radio frequency module 16 includes a circuit board 161, three diode rectifiers 162, 163, and 164, and three radio frequency components 165, 166, and 167. The circuit board 161 is disposed in a receiving groove in the middle of one side of the top of the base 111. The diode rectifiers 162, 163, and 164 are respectively disposed on the circuit board 161, and are electrically connected to the coil groups 131, 141, and 151 for receiving the induced current generated by the coil groups 131, 141, and 151, and The received induced current is rectified to maintain the correct polarity of the induced current. The RF components 165, 166, and 167 are electrically connected to the diode rectifiers 162, 163, and 164, respectively, for receiving the rectified induced current and being energized, so that the RF components 165, 166, and 167 are respectively sent outward. Wireless RF signal.

Further, as shown in FIGS. 11 and 12, each of the micro-generators 13, 14, 15 can emit the first induced currents 133, 143, 153 and the second induced currents 134, 144, 154 as described above, and thus each The diode rectifiers 162, 163, 164 can rectify the first induced currents 133, 143, 153 and the second induced currents 134, 144, 154 to maintain the first induced currents 133, 143, 153 and the second induced current 134, The correct polarity of 144, 154. Each of the RF components 165, 166, 167 receives the rectified first induced current 133, 143, 153 or the second induced current 134, 144, 154 and is energized, so that each of the RF components 165, 166, 167 sends a first outward Radio frequency signals 1651, 1661, 1671 or a second radio frequency signal 1652, 1662, 1672. In other words, the combination of the three diode rectifiers 162, 163, 164 of the radio frequency module 16 of the present embodiment and the three radio frequency components 165, 166, 167 can emit the first radio frequency signals 1651, 1661, 1671, and Two radio frequency signals, such as the second radio frequency signal 1652, 1662, and 1672. The signal receiving unit 22 of the RF conversion transmitter 20 receives the first radio frequency signals 1651, 1661, 1671 and the second radio frequency signals 1652, 1662, 1672. The signal conversion unit 23 of the RF conversion transmitter 20 converts the first radio frequency signals 1651, 1661, 1671 and the second radio frequency signals 1652, 1662, 1672 into six electronic device control signals 231-236. The signal transmitting unit 24 of the RF conversion transmitter 20 receives the six electronic device control signals 231 to 236 transmitted from the signal conversion unit 23 of the RF conversion transmitter 20, and controls the six electronic device control signals 231 to 236 by the wireless communication protocol. It is transmitted to the central gateway processing device 2. The central gateway processing device 2 connects the six electronic devices 301-306 by a wireless communication protocol, and controls the operation modes of the six electronic devices 301-306 according to the six electronic device control signals 231-236. The modes of operation of the electronic devices 301-306 include all of the outlets within a particular area, the power state of the switches, and the mode of operation of all electronic devices within a particular area. The six electronic devices 301-306 shown in Figures 11 and 12 include a combination of an electric lamp and a wireless socket, a combination of a coffee machine and a wireless socket, a combination of a fan and a wireless socket, a combination of a television and a wireless outlet, an air conditioner, an alarm, etc. However, it is not limited to this.

Preferably, the frequency band of each radio frequency signal is RF433 MHz. The radio frequency signal in the RF433 MHz band has the advantages of low frequency, long wavelength, transferable distance of more than 50 meters and low power consumption. Moreover, the power generation of the micro-generators 13, 14, 15 is only sufficient to provide the radio frequency signal emitted by the radio frequency module 16 in the RF433 MHz band, which is one of the reasons for selecting the RF433 MHz band for the radio frequency signal.

As shown in FIG. 11 to FIG. 15, the modular kinetic situation panel control device 1 of the present invention further includes a context setting device 30. The context setting device 30 includes a body 31, a processing module 32, a storage module 33, a display module 34, an edit setting module 35, and a wireless transmission module 36. The processing module 32 is disposed inside the body 31. The storage module 33 is disposed in the main body 31, electrically connected to the processing module 32, and stores a plurality of context information 331~336; the context information 331~336 respectively correspond to the electronic control signals 231~236. The display module 34 is disposed on the outer surface of the body 31 and electrically connected to the processing module 32. The editing setting module 35 is disposed inside the main body 31, electrically connected to the processing module 32, and outputs a setting interface 351 and an editing interface 352 to the display module 34. The setting interface 351 is used to display the context information 331~336. The editing interface 352 provides an editing function to edit the context information 331~336. More specifically, FIG. 13 shows a setting interface 351 which, when the user clicks on the screen, enters the aspect shown in FIG. FIG. 14 shows another setting interface 351, and another setting interface 351 displays six context information 331~336. After the user clicks on one of the context information 331~336, the editing interface 352 shown in FIG. 15 is entered. As shown in FIG. 15, the user can edit the content of the context information 331~336 on the editing interface 352. As shown in FIG. 12, the wireless transmission module 36 is disposed inside the main body 31, electrically connected to the processing module 32, and transmits the edited situation information 331~336 to the central gateway processing device 2 by using a wireless communication protocol. The central gateway processing device 2 integrates the edited context information 331~336 with the electronic device control signals 231~236 into a plurality of operational mode signals 201-206. The central gateway processing device 2 further controls the operation modes of the electronic devices 301-306 by the operation mode signals 201-206. The context setting device 30 is a smart phone, a tablet computer, a notebook computer or a desktop computer.

The wireless communication protocol is ZigBee, infrared, Bluetooth, WiFi or ultra-wideband.

As can be seen from the above, the modular kinetic scenario panel control device 1 of the present invention can be combined with the central gateway processing device 2 to form a smart integrated control system 100.

This creation can achieve the following effects:

First of all, the automatic power generation wireless remote control 10 is easy to carry, and can convert mechanical energy into electrical energy to achieve self-power generation effect, without battery, and without wall wiring.

Secondly, the wireless radio frequency signal sent by the automatic power generation wireless remote control 10 has the advantages of low frequency, long wavelength, transmission distance exceeding 50 meters and low power consumption.

Moreover, the present invention can remotely switch all sockets in a specific area, the power state of the switch, and control the operation modes of all the electronic devices 301-306 in a specific area.

In addition, the context setting device 30 can dynamically edit the interactive functions of the electronic devices 301-306 and the automatic power generation wireless remote control 10, and solve the problem that the conventional remote controller has an absolute control relationship, and cannot flexibly change the operation mode of the button corresponding to the control electronic device.

The above description is only a preferred embodiment for explaining the present creation, and is not intended to impose any form of restriction on the creation, so that any modification or change related to the creation under the same creative spirit is provided. , should still be included in the scope of this creative intent.

1‧‧‧Modular kinetic energy situation panel control device  10‧‧‧Automatic power generation wireless remote control  11‧‧‧Shell  111‧‧‧Base  1111‧‧‧ pivotal department  1112‧‧‧ pivot  1113‧‧‧rails  112‧‧‧Front frame  121, 122, 123‧‧‧ Pressing Department  1211, 1221, 1231‧‧‧ first end  1212, 1222, 1232‧‧‧ second end  124‧‧‧ 枢 ear  1241‧‧‧Pivot  125‧‧‧ hook  13,14,15‧‧‧Micro-generators  131, 141, 151‧‧‧ coil group  1331, 1411, 1511‧‧ ‧ shrapnel  1312, 1412, 1512‧‧ iron core  1313, 1413, 1513‧‧‧ wires  1314, 1414, 1514‧‧ ‧ coil  132, 142, 152‧‧‧ magnet group  1321, 1421, 1521‧‧ ‧ joints  1322, 1422, 1522‧‧‧ permanent magnets  1323, 1423, 1523‧‧‧ upper magnetic plate  1324, 1424, 1524‧‧‧ under the magnetic plate  1325, 1425, 1525‧‧‧ grooves  1326, 1426, 1526‧‧  1327, 1427, 1527‧‧‧ slider  1328, 1428, 1528‧‧‧ blocks  133, 143, 153‧‧‧ first induced current  134, 144, 154‧‧‧second induced current  16‧‧‧Wireless RF Module  161‧‧‧ circuit board  162, 163, 164‧ ‧ Diode Rectifiers  165, 166, 167‧‧ ‧ RF parts  1651, 1661, 1671‧‧‧ first radio frequency signal  1652, 1662, 1672‧‧‧ second radio frequency signal  171, 172, 173‧‧ ‧ protective cover  174‧‧‧ Cover  20‧‧‧RF converter  21‧‧‧ Shell  22‧‧‧Signal Reception Department  23‧‧‧Signal Conversion Department  231~236‧‧‧Electronic device control signal  24‧‧‧Signal Transmission Department  30‧‧‧Situation setting device  31‧‧‧Ontology  32‧‧‧Processing module  33‧‧‧ storage module  331~336‧‧‧Scenario information  34‧‧‧Display module  35‧‧‧Edit setting module  351‧‧‧Setting interface  352‧‧‧Editing interface  36‧‧‧Wireless Transmission Module  2‧‧‧Central Gateway Treatment Unit  201~206‧‧‧Operating mode signal  301~306‧‧‧Electronic device  100‧‧‧Smart Integrated Control System

Figure 1 is a perspective view of the creation.  Figure 2 is a block diagram of the creation.  Figure 3 is an exploded view of the automatic power generation wireless remote control of the present invention.  Fig. 4 is a perspective view of the pressing portion of the present invention.  Fig. 5 is a schematic view showing the magnet assembly of the present invention provided at the first end of the pressing portion.  Figure 6 is a perspective view of the micro-generator of the present invention.  Fig. 7 is a perspective view of the magnet group of the present invention.  Figure 8 is an exploded view of the magnet set of the present invention.  Fig. 9 is a schematic view showing the magnet group of the present invention moving upward relative to the coil group.  Figure 10 is a schematic view of the magnet group of the present invention moving downward relative to the coil assembly.  FIG. 11 is a perspective view of the six electronic devices jointly controlled by the creation and the central gateway processing device.  FIG. 12 is a block diagram showing the six electronic devices jointly controlled by the creation and the central gateway processing device.  13 and FIG. 14 are schematic diagrams showing the operation setting interface of the context setting device of the present invention.  Figure 15 is a schematic diagram showing the operation editing interface of the context setting device of the present invention.  

Claims (10)

A modular kinetic situation panel control device for a smart integrated control system, the smart integrated control system comprising a central gateway processing device, the central gateway processing device connecting a plurality of electronic devices by a wireless communication protocol and controlling the The mode of operation of an electronic device is characterized by:
The modular kinetic energy situation panel control device comprises:
An automatic power generation wireless remote control includes a casing, a plurality of pressing portions, a plurality of micro-generators, and a radio frequency module, wherein the pressing portions are movably disposed on the casing, and each of the micro-generators includes a coil assembly and a magnet group, the coil groups are respectively disposed inside the casing, and the magnet groups are respectively disposed at the bottom of the pressing portions and located outside the coil groups, and each of the pressing portions drives each of the magnet groups to face each other When the coil assembly is displaced between a first position and a second position, each of the coil sets generates an induced current. The radio frequency module is disposed inside the casing and electrically connected to the coil sets for receiving The inductive current generated by each coil group is energized, and a radio frequency signal is sent out; and a radio frequency conversion transmitter includes a casing, a signal receiving portion, a signal converting portion and a signal transmitting portion, the signal The receiving portion is disposed inside the casing, is wirelessly connected to the radio frequency module, and is configured to receive the radio frequency signal. The signal converting portion is disposed inside the casing and electrically connected to the signal receiving portion. Receiving the wireless RF signal transmitted from the signal receiving unit, and converting the wireless RF signal into an electronic device control signal, the signal transmitting portion is disposed inside the casing, and is electrically connected to the signal converting portion for receiving The electronic device control signal transmitted by the signal conversion unit is transmitted to the central gateway processing device by a wireless communication protocol. The modular kinetic scenario panel control device for the intelligent integrated control system according to claim 1, further comprising a context setting device, the context setting device comprising a body, a processing module, and a storage module The processing module is disposed inside the body, the storage module is electrically connected to the processing module, and is stored. a plurality of contextual information, the contextual information respectively corresponding to the electronic device control signal, the display module being disposed on an outer surface of the body, electrically connected to the processing module, the editing setting module being disposed inside the body Electrically connecting the processing module, and outputting a setting interface and an editing interface to the display module, the setting interface is configured to display the situation information, and the editing interface provides an editing function to edit the situation information. The wireless transmission module is disposed inside the body, electrically connected to the processing module, and transmits the edited context information to the central gateway processing device by using a wireless communication protocol. The central gateway processing device integrates the edited context information with the electronic device control signals into a plurality of operational mode signals, and the central gateway processing device further controls the operation modes of the electronic devices by the operation mode signals. . The modular kinetic situation panel control device for a smart integrated control system according to claim 1 or 2, wherein the wireless communication protocol is ZigBee, infrared, Bluetooth, WiFi or ultra-wideband. The modular kinetic energy situation panel control device for the smart integrated control system according to the first aspect of the invention, wherein the automatic power generation wireless remote control further comprises a plurality of protective covers, wherein the protective covers are respectively disposed in the casing And opening an opening, the coil sets are respectively located inside the protective covers, and the magnet sets are respectively located outside the openings of the protective covers. The modular kinetic energy situation panel control device for the smart integrated control system according to the first aspect of the invention, wherein the automatic power generation wireless remote control further comprises a cover plate disposed inside the casing, The radio frequency module is disposed under the cover. The modular kinetic energy situation panel control device for the intelligent integrated control system according to claim 1, wherein each of the coil sets includes a spring piece, an iron core and a wire, and one end of the elastic piece is respectively The iron cores are respectively connected to the other ends of the elastic sheets to be in a suspended state, and the wires are electrically connected to the wireless radio frequency module and wound around the outer surfaces of the iron cores to form Multiple coils. A modular kinetic situation panel control device for a smart integrated control system according to claim 6, wherein each of the magnets is disposed outside each of the cores and includes a set of joints and a permanent a magnet, an upper magnetic conductive plate and a lower magnetic conductive plate, wherein the assembly portions of the magnet groups are respectively disposed at the bottoms of the first ends of the pressing portions and located outside the coil groups, each of the magnets The set of joints encloses a groove, and an opening is formed on a side facing each coil group, and the upper magnetic conductive plate of each magnet group is disposed on the top of the permanent magnets disposed on each of the magnet groups The lower magnetic conductive plate of each magnet group is disposed at the bottom of the permanent magnet of each magnet group, and the permanent magnet, the upper magnetic conductive plate and the lower magnetic conductive plate of each magnet group are simultaneously located in each magnet group In the groove of the set of joints, under the action of the permanent magnets of the magnet sets, the upper magnetic plates of the magnet groups are different from the magnetic poles of the lower magnetic plates of the magnet groups; Wherein, when each of the magnet groups is displaced upward to the first position, the coil group The iron core is aligned with the lower magnetic conductive plate of each magnet group, and a center line of the coil of each coil group overlaps with an axis of the lower magnetic conductive plate of each magnet group; wherein, each magnet group When the downward displacement to the second position, the iron core of each coil group is aligned with the upper magnetic conductive plate of each magnet group, and the center line of the coil of each coil group and the upper portion of each of the magnet groups An axis of the magnetic conductive plate is overlapped; and wherein, when each of the pressing portions drives each of the magnet groups to be displaced between the first position and the second position with respect to each of the coil groups, the coil group The magnetic field of the iron core changes so that the wire of the coil of each coil group generates an induced current. The modular kinetic energy situation panel control device for the intelligent integrated control system according to claim 7, wherein the housing protrudes a plurality of slide rails, and the two sides of the assembly portion of each magnet group Two sliders are respectively disposed, and the sliders of the assembly portions are respectively slidably disposed in the slide rails; wherein the two sides of the bottom portion of the first end of each of the pressing portions respectively protrude with two hook portions, respectively Two blocks are respectively protruded from the two sides of the set of the magnet groups, and the two hook portions of the pressing portions are respectively hooked on the two blocks of the set of the magnet groups. The modular kinetic situation panel control device for the intelligent integrated control system according to claim 1, wherein the frequency band of each of the radio frequency signals is RF433 MHz. The modular kinetic situation panel control device for the intelligent integrated control system according to the first aspect of the invention, wherein the radio frequency module comprises a circuit board, a plurality of diode rectifiers and a plurality of radio frequency components, the circuit The diodes are disposed on the circuit board, and the diode rectifiers are respectively disposed on the circuit board, and are electrically connected to the coil groups for receiving the induced current generated by the coil groups, and performing the induced currents Rectifying, in order to maintain the correct polarity of the induced current, the RF components are electrically connected to the diode rectifiers for receiving the rectified induced current and being energized, so that the RF components respectively transmit a wireless RF signal.