CN111105608A - Wireless control system and wireless control method for realizing power supply on-off operation of equipment - Google Patents

Abstract

The invention discloses a wireless control system and a wireless control method for realizing power supply on-off operation of equipment. The wireless control system comprises a wireless switch device and a wireless remote control device, wherein the wireless switch device is used for being arranged between a power supply and equipment which is in a passive standby state when not powered and comprises a transceiving antenna, a passive awakening module, a control module and a controlled module, the passive awakening module is connected with the transceiving antenna and converts a received wireless energy signal into a direct current signal so that the control module is powered and outputs a control signal to prompt the controlled module to execute the on-off operation between the equipment and the power supply, and the wireless remote control device is matched with the wireless switch device and comprises the transceiving antenna and the remote control module. The technical scheme of the invention can thoroughly eliminate the standby power consumption of various types of equipment, can very conveniently and quickly realize the on-off operation between the equipment and the power supply, and can bring quite remarkable social and economic benefits.

Description

Wireless control system and wireless control method for realizing power supply on-off operation of equipment

Technical Field

The present invention relates to the field of switch control technologies, and in particular, to a wireless control system and a wireless control method for implementing power supply on/off operation of a device.

Background

With the increasing warming of global climate, energy conservation and emission reduction become important in government work of various countries, especially in electrical appliances, electronic industries and the like closely related to daily life and production, the wave tip of the air inlet is pushed down, for example, in the market of europe and america, high efficiency and low power consumption become one of important factors which must be considered in the research and development process of electronic products, and the electronic products have market competitiveness.

The standby power consumption of various electronic devices becomes one of the important problems to be solved for energy conservation and emission reduction, however, many devices adopting wireless remote control technology, such as televisions, air conditioners, and the like, still have some problems and disadvantages in the use process. For example, as shown in fig. 1, when the apparatus 80 is in a remote controllable state, i.e., when waiting for the command data signal S to be sent from the wireless remote control device 90 at the remote control end, the power switch in the apparatus 80 must be in an open state, for example, the active standby watch circuit 810 therein needs to be powered on all the time, so that the power consumption in the standby state becomes an irrevocable problem. According to the test, if 1 watt standby power consumption is taken as an example, the power consumed by a common electric appliance for 1 year is close to 10 kilowatt hours. In addition, according to statistical data, the average standby energy consumption of urban families in China in 2009 reaches about 10%, which is equivalent to that each family uses 15-30W of Changming lantern. It follows that the amount of energy consumed by the existing large number of appliances for this space can reach an amazing level. Therefore, reducing the ubiquitous standby energy consumption of various electrical appliances becomes a major technical problem for building a social conservation and implementing an energy-saving, emission-reducing and environment-friendly strategy.

Although various zero power standby schemes have been proposed to address the standby power consumption problem, these schemes still suffer from a number of problems and require further improvement and sophistication. For example, since the control signal of the existing wireless switch remote control device needs to cover a certain range to achieve convenience in operation, accurate directional transmission cannot be used, and the loss ratio of the wireless energy transmission, reception and conversion process is large, so that the wireless energy transmission efficiency is not high, the ratio of the energy finally absorbed and utilized by the wireless switch device is very low, and most of the energy is radiated to the air and wasted. For another example, the existing wireless switch remote control device needs to consume large wireless energy, and even if the remote control end is powered by a high-price and large-capacity battery, the working life of the remote control device is greatly limited, and the cost is increased. For another example, if it is considered that a certain range of coverage of the remote control signal of the wireless switching device needs to be ensured, and particularly, accurate directional transmission is desired, higher requirements are put on the wireless switching remote control device (especially, two parts of a power amplifier and a transmitting antenna), while the requirements are difficult to be met by the existing common power amplifier and an onboard patch antenna, so that if the wireless switching device is applied, the volume of the remote control end needs to be increased, which brings many adverse effects on daily application, manufacturing cost and the like.

It should be noted that the foregoing description is provided to facilitate a better understanding of the invention and should not be construed as prior art only by virtue of the inclusion in this section or that all such problems or disadvantages noted therein are readily apparent.

Disclosure of Invention

In view of the above, the present invention provides a wireless control system and a wireless control method for implementing power supply on/off operation of a device, so as to solve or at least alleviate one or more of the above problems and other problems in the prior art.

The present invention also has for its object to provide an alternative solution to the other inventions filed by the same applicant, which applications are filed on the same day as the present application and have the same or similar subject names, which not only overcome the problems of the prior art in their entirety but also in each case in different respects, and which in particular bring about very significant technical advantages and great practical values.

First, according to a first aspect of the present invention, there is provided a wireless control system for implementing a power supply on/off operation of a device, comprising:

a wireless switching apparatus for placement between a power source and a device that is in a passive standby state when not powered, and comprising:

the receiving and transmitting antenna is arranged for receiving wireless signals and transmitting outgoing signals outwards, and the wireless signals comprise wireless energy signals and instruction data signals;

a passive wake-up module connected to the transceiver antenna and configured to convert the wireless energy signal received by the transceiver antenna to provide a direct current signal;

a control module connected to the transmitting and receiving antenna, configured to demodulate the command data signal received by the transmitting and receiving antenna and output a control signal after being electrically connected to the power supply by the dc signal, and generate a feedback signal according to an execution result of at least a part of the control signal, wherein the output signal includes the feedback signal; and

a controlled module connected to the control module, the power supply and the device and configured to receive and execute an on-off operation between the device and the power supply according to the control signal; and

a wireless remote control device, comprising:

a transmitting and receiving antenna configured to at least transmit the wireless signal and receive the outgoing signal;

and the remote control module is connected with the transmitting and receiving antenna, is used for receiving and processing input operation of a user to transmit a corresponding wireless signal through the transmitting and receiving antenna, and processes the received external signal.

In the wireless control system according to the present invention, optionally, the passive wake-up module at least includes:

a wireless energy receiving and converting unit connected to the transceiving antenna and configured to convert a wireless energy signal received from the transceiving antenna into the direct current signal; and

the switch component is connected with the wireless energy receiving and converting unit to receive the direct current signal, and is also connected with the power supply and the control module to enter a closed state after receiving the direct current signal, so that the control module and the power supply form an electric connection to be powered by the power supply; and/or

The control module at least comprises:

the signal demodulation unit is connected with the transceiving antenna and is arranged to demodulate and convert the instruction data signal received from the transceiving antenna into a digital signal after the control module is powered by the power supply; and

the decoding and control unit is connected with the signal demodulation unit and the controlled module and is used for decoding the digital signal to generate and output the control signal; and/or

The controlled module is a controlled switch that causes the device to be powered by the power source upon entering a closed state, the controlled switch including a monostable switch and a bistable switch; and/or

The power source comprises a battery, an alternating current power source and a direct current power source, and/or the feedback signal comprises a signal output from the control module to the passive wake-up module to break the electrical connection.

In the wireless control system according to the present invention, optionally, the switch component is a monostable switch, and the passive wake-up module further includes a first switch driving unit, which is connected to the output terminal of the wireless energy receiving and converting unit and the control terminal of the switch component, and is configured to output a driving signal matching with the switch component, and is powered by the dc signal output by the wireless energy receiving and converting unit before and after the switch component is closed; and/or

The control module further comprises a second switch driving unit, the second switch driving unit is connected with the output end of the decoding and control unit and the control end of the controlled switch, the input end of the second switch driving unit is connected with the equipment, the second switch driving unit is arranged to output a driving signal matched with the second switch driving unit to the controlled switch, the second switch driving unit receives uniform power supply of the whole control module from the power supply before the controlled switch enters a closed state, and receives specific power supply of the controlled switch from the power supply after the controlled switch enters the closed state.

In the wireless control system according to the present invention, optionally, when the power supply is an alternating current power supply, the wireless switching device further comprises a first AC/DC unit disposed between the passive wake-up module and the alternating current power supply for converting the alternating current power supply into a power form suitable for use by the control module to supply power to the control module after the switching part enters the closed state.

In the wireless control system according to the present invention, optionally, the wireless switching device further comprises a second AC/DC unit connected to the controlled switch, the device and the second switch driving unit and configured to convert the power supply into a form of power supply suitable for use by the second switch driving unit to supply power to the second switch driving unit after the controlled switch enters a closed state.

In the wireless control system according to the present invention, optionally, the wireless energy receiving and converting unit is configured to provide the dc signal at least before the control module outputs the control signal, so as to maintain an electrical connection state between the control module and the power supply; and/or

The decoding and control unit is arranged to perform the following operations: decoding the digital signal to generate a corresponding instruction data signal, carrying out data transmission correctness verification on the instruction data signal, and judging whether the instruction data signal is sent to the wireless switch device: if yes, outputting a corresponding control signal according to the instruction data signal.

In the wireless control system according to the present invention, optionally, the remote control module includes:

the human-computer interaction unit is arranged for receiving input operation of a user;

a signal modulation and demodulation unit connected to the transmitting and receiving antenna and configured to perform wireless modulation processing on the command data signal waiting to be transmitted from the transmitting and receiving antenna and convert the outgoing signal received by the transmitting and receiving antenna into a digital signal; and

and the coding, decoding and control unit is connected with the human-computer interaction unit and the signal modulation and demodulation unit, is arranged for processing the received input operation of the user into a corresponding instruction data signal and providing the instruction data signal to the signal modulation and demodulation unit, and decodes the digital signal converted by the signal modulation and demodulation unit into specific information.

In the wireless control system according to the present invention, optionally, the human-computer interaction unit is configured to receive an input operation by the user through a key, a display device and/or a network input operation mode, and/or the information includes an operation feedback result corresponding to the instruction data signal transmitted from the wireless switching device.

Furthermore, according to the second aspect of the present invention, there is also provided a wireless control method for implementing power supply on/off operation of a device, comprising the steps of:

A. providing a wireless control system for realizing power supply on-off operation of equipment according to any one of the above items, and arranging a wireless switch device between the equipment and a power supply;

B. enabling a transmitting and receiving antenna in the wireless switch device to receive wireless signals transmitted from a transmitting and receiving antenna of the wireless remote control device, wherein the wireless signals comprise wireless energy signals and instruction data signals;

C. enabling a passive wake-up module in the wireless switching device to generate a direct current signal based on the received wireless energy signal, and enabling a control module in the wireless switching device to be electrically connected with the power supply through the direct current signal so as to be powered by the power supply; and

D. and enabling the control module to demodulate and generate a control signal based on the received instruction data signal, and executing on-off operation between the equipment and the power supply according to the control signal.

In the wireless control method for implementing power supply on-off operation of a device according to the present invention, optionally, in step D:

sending a signal from the device to the wireless switching apparatus after the device and the power supply are turned on, so that a controlled module in the wireless switching apparatus keeps performing a turn-on operation between the device and the power supply; and/or

When the equipment needs to be shut down, the command data signal is sent out from the wireless remote control device to the wireless switching device or a signal is sent from the equipment to the wireless switching device, so that the controlled module performs disconnection operation between the equipment and the power supply, and the equipment is in a passive standby state.

The technical scheme of the invention is completely different from the prior art, and the technical scheme is innovatively designed and provided for fully utilizing and distributing wireless energy to control and realize the on-off operation of power supply of equipment. The invention can remarkably promote the realization of the goals of energy conservation, emission reduction, environmental protection and the like, particularly avoid the generation of a large amount of wireless energy waste in the air, obviously prolong the service life of the power supply of the wireless switch remote control device, make the structure of the wireless switch remote control device more compact and improve the practicability of a wireless switch system. The invention is very suitable for large-scale popularization and application, and can bring great social benefit and economic benefit.

Drawings

Fig. 1 is a schematic diagram illustrating the operation principle of an active standby mode commonly used in the prior art.

Fig. 2 is a schematic diagram of the principle of operation in a passive standby mode in an embodiment of a wireless control system according to the present invention.

Fig. 3, 4 and 5 are schematic diagrams of the composition and operation principle of the first, second and third embodiments of the wireless switching device in the wireless control system according to the present invention, respectively.

Fig. 6 is a schematic composition diagram of an embodiment of a wireless remote control device in a wireless control system according to the present invention.

Fig. 7 is a flowchart illustrating an embodiment of a wireless control method for implementing power on/off operation of a device according to the present invention.

Detailed Description

First, it should be noted that the structures, compositions, steps, features, advantages and the like of the wireless control system and the wireless control method for realizing the power supply on-off operation of the device of the present invention will be specifically described below by way of examples, however, all the descriptions are only for illustrative purposes and should not be construed as forming any limitation to the present invention. In this document, the technical terms "first", "second", etc. are used for distinguishing expression purposes only and are not intended to indicate their order, size, relative importance, etc., and the technical term "used" should not be construed as a limiting expression limited thereto, and the technical term "connected" and its derivatives mean that a specific component is directly and/or indirectly connected to another component, and the technical terms "transceiving antenna" and "transceiving antenna" are used for distinguishing expression purposes only, and they also have a function of transmitting and receiving wireless signals.

Furthermore, any single feature described or implicit in an embodiment or any single feature shown or implicit in the drawings or shown or implicit in the drawings, may still allow any combination or permutation to continue between the features (or their equivalents) without any technical barriers and thus further embodiments according to the invention should also be considered within the scope of this disclosure.

First, the wireless control system of the present invention can be used to implement the power on/off operation of the device, and it may include two parts, namely a wireless switch device and a wireless remote control device used in cooperation with the wireless switch device. The general operating principle of the passive standby mode in one example of a wireless control system is shown only schematically in fig. 2. Referring to fig. 2, the controlled standby device 80 is provided with a wireless switch device a according to the system of the present invention, for example, the wireless switch device a may be embedded in the device 80, meanwhile, a wireless remote controller 90, which can be used as a wireless remote controller in the present invention, is embedded with a wireless switch remote controller B, which is generally small in size and low in power consumption, the wireless switching remote control B, which is matched to the above-mentioned wireless switching device a, can send out, for example, a wireless switching signal S' (or called wireless energy signal) which is usually of low power to remotely control the wireless switching device a, for switching on and off the power supply 70 (which may take the form of a battery, ac power source, dc power source, etc.) to one, some or all of the device functional modules in the device 80, one such device functional module has been exemplarily labeled in fig. 2 with reference numeral 820.

Specifically, when the device 80 is required to start operating, for example, the wireless remote controller 90 is operated to send out a wireless switch signal S 'required to turn on the power supply 70 through the wireless switch remote control device B, and the wireless switch device a is operated to turn on the power supply of the device 80 after receiving the wireless switch signal S', and the composition, operation mode, and the like of the wireless switch device a will be described in more detail below. After the controlled device 80 and the controlled power supply 70 are powered on by the wireless switch device a, the wireless remote controller 90 can be used to continuously send various command data signals S to the device 80 to remotely control the device 80 to perform various possible operations, and such command data signals S may be the same or different under different application environments (such as facing different types of devices). Similarly, in the case that the apparatus 80 needs to stop operating (e.g. has been operated, needs to be stopped or suspended suddenly, etc.), the wireless remote controller 90 may be operated to make the wireless switch remote control device B send out a corresponding wireless switch signal S' to instruct the wireless switch device a to operate to cut off the current power supply of the power supply 70 to the apparatus 80, so as to completely implement the zero-power standby of the apparatus 80.

With continued reference to fig. 3 to 5, the wireless switch device in the wireless control system according to the present invention will be described in detail by the embodiments shown in the drawings.

First, in fig. 3, a schematic block diagram of an embodiment of a wireless switching apparatus is shown, in which the wireless switching apparatus 100 may include a transceiver antenna 10, a passive wake-up module 20, a control module 30, and a controlled module 40, wherein a power source 70 may be, for example, a battery or a dc power source for supplying power to a device 80.

Specifically, the transceiving antenna 10 is configured to receive and transmit wireless signals, i.e. it can not only receive wireless signals such as wireless energy signals, command data signals, etc., which are typically transmitted by a user operating a wireless remote control 90 located at a remote control end as shown in fig. 2, but also transmit signals (such as operation feedback signals, etc.) to be transmitted to the outside, which are received by the wireless remote control 90.

For the passive wake-up module 20, it is connected to the transceiving antenna 10 for recovering a dc signal from the wireless energy signal received by the transceiving antenna 10, and the power supply 70 is connected to supply power to the control module 30 according to the dc signal. The invention adopts the direct current signal mode, thereby having the advantages of relative easy realization, convenient processing, stable and reliable signal, and the like. In practical applications, the dc signal may be continuously supplied or supplied only within a preset time range according to requirements, and specific parameters (such as amplitude, duration, etc.) of the dc signal may also be flexibly set according to specific application requirements.

Merely as an exemplary case, the passive wake-up module 20 may be provided with a wireless energy receiving and converting unit 210, a first switch driving unit 220 and a switching part 230. The first switch driving unit 220 is an optional configuration, and in practical applications, whether the first switch driving unit 220 needs to be used or not can be selectively determined according to specific operating conditions of the switch component 230. If the first switch driving unit 220 is used, one end thereof may be connected to the wireless energy receiving and converting unit 210 as shown in fig. 3, and the other end thereof may be connected to a control end of the switch unit 230 (e.g., using a monostable switch, etc.) for outputting a driving signal matched to the switch unit.

As shown in fig. 3, one end of the wireless energy receiving and converting unit 210 is connected to the transmitting and receiving antenna 10, and the other end is connected to the switch component 230 or the first switch driving unit 220 (if selected), and the wireless energy receiving and converting unit 210 is used to receive wireless energy and convert it into a dc signal. The first switch driving unit 220 can be powered by the direct current signal generated by the wireless energy receiving and converting unit 210 before and after the switch component 230 enters the closed state, which is schematically indicated by using a reference symbol a in fig. 3. In some embodiments, the wireless energy receiving and converting unit 210 may be optionally configured such that the provided dc signal can ensure that the control module 30 maintains an electrical connection with the power source before outputting the control signal. Of course, in other embodiments, the wireless energy receiving and converting unit 210 may also continuously provide the above-mentioned dc signal during the operation of the device 80.

The switching component 230 may be implemented by using any suitable device, such as a monostable switch, and its control terminal may be connected to the wireless energy receiving and converting unit 210, or alternatively, the first switch driving unit 220, and the other two terminals of the switching component 230 are connected to the power supply 70 and the control module 30, respectively. When the control terminal of the switching member 230 receives the dc signal generated by the conversion process of the wireless energy receiving and converting unit 210, it enters a closed state to allow the power supply 70 to supply power to the control module 30 via the connection line b schematically shown in fig. 3.

For the control module 30, it is configured to perform demodulation processing according to the instruction data signal received by the transceiving antenna 10 so as to generate and output a control signal matched with the controlled module 40, and it may also be configured to generate a feedback signal (for example, a signal for outputting to the passive wake-up module 20 to disconnect the current power supply to the control module 30) according to the execution result of some or all of the control signals, etc., for example, and may transmit such a feedback signal outwards through the transceiving antenna 10 when required by an application, so that the wireless remote control 90 may receive and obtain corresponding information therefrom.

As an exemplary case only, the control module 30 may be provided with a signal demodulation unit 310, a decoding and control unit 320, and a second switch driving unit 330. The second switch driving unit 330 is an optional configuration, and in practical applications, whether the second switch driving unit 330 needs to be used or not can be selectively determined according to specific configuration conditions of the controlled module 40. If a second switch driving unit 330 is used, it may be connected at one end to the decoding and control unit 320 and at the other end to the controlled module 40 as shown in fig. 3, for outputting a driving signal matched to the controlled module 40. The second switch driving unit 330 receives a unified power supply from the power supply 70 to the whole control module 30 before the controlled module 40 enters the closed state, and receives an exclusive power supply from the power supply 70 to the second switch driving unit 330 after the controlled module 40 enters the closed state, which is schematically indicated by reference sign c in fig. 3.

The signal demodulation unit 310 is configured to receive the modulated command data signal and convert it into a digital signal after the switch component 230 of the passive wake-up module 20 enters the closed state. The decoding and control unit 320 has one end connected to the signal demodulation unit 310 and the other end connected to the controlled module 40 or connected to the second switch driving unit 330 that has been selectively configured, and after the switch component 230 has been closed and the signal demodulation unit 310 converts the digital signal, the decoding and control unit 320 will decode to generate a specific command data signal according to the digital signal. In an alternative scenario, the decoding and control unit 320 may be arranged to perform the following operations on the resulting digital signal: firstly, decoding the digital signal to generate a corresponding instruction data signal (for example, usually demodulating an identification code, a control code and a check code carried in the digital signal), and then, performing data transmission correctness check on the obtained instruction data signal so as to confirm that no error exists in the transmission process; secondly, it is determined whether the obtained command data signal is sent to the wireless switching device, and if yes, a corresponding control signal is output according to the command data signal, and such control signal can be used for being transmitted to the controlled module 40 to complete a corresponding control operation.

Referring next to fig. 3, the controlled module 40 may be implemented by using any suitable components or units, such as a monostable switch, a bistable switch, etc. For the monostable switch, various types of NPN transistors, MOS transistors and the like can be adopted, and for the bistable switch, for example, DS1E-ML-DC1.5V and DS1E-ML2-DC1.5V and the like of the DS series of Panasonic can be adopted. When the controlled module 40 employs a monostable switch, the device 80 usually needs to output a signal to the monostable switch or a second switch driving unit (if selected) in the control module after being powered to maintain the on state of its own power supply line, and when the controlled module 40 employs a bistable switch, the device 80 usually does not need to output any control signal to the bi-monostable switch or the second switch driving unit described above after being powered, because the bistable switch can maintain a high-impedance output state at this time, and the power supply line will automatically maintain the on state. It should be noted, of course, that the various types of switching components or modules, etc., referred to throughout this document are permissible to be various other types of monostable switches, bistable switches, etc., such as magnetic switches, micromechanical (MEMS) switches, MOS switches, etc.

As shown in fig. 3, the controlled module 40 has an input terminal connected to the control module 30 for receiving the control signal, and other output terminals connected to the power source 70 and the device 80, respectively, so that the power line between the device 80 and the power source 70 can be switched on or off according to the control signal. Wherein, the device 80 can be connected to the input end of the controlled module 40 or the second switch driving unit 330 (if selected), when the controlled module 40 is, for example, in the form of a controlled switch (such as a monostable switch, a bistable switch, etc.) and is closed, the device 80 is powered by turning on the power supply 70, and then the control module 30 can output a control signal to the controlled module 40 or the second switch driving unit 330 (if selected) to control the power supply on-off operation as required.

Having described the general composition of the wireless switching device 100 shown in fig. 3, the following description will proceed to exemplarily describe the basic operation thereof. First, the transmitting/receiving antenna 10 waits for the reception of wireless signals including wireless energy signals. If the transceiver antenna 10 receives a wireless energy signal sent from, for example, the wireless remote controller 90 (which may be provided with the wireless switch remote control device B) shown in fig. 2, the wireless energy receiving and converting unit 210 in the passive wake-up module 20 converts the wireless energy signal into a dc signal, and the dc signal can directly (or after performing, for example, signal amplification processing via the optional first switch driving unit 220) drive the switch component 230 to close. When the switch component 230 in the passive wake-up module 20 enters the closed state, the power supply 70 may start to supply power to the control module 30 through the connection line b via the switch component 230, the signal demodulation unit 310 in the control module 30 starts to convert the command data signal received from the transceiving antenna 10 into a digital signal, the decoding and control unit 320 receives the digital signal and decodes a specific command data signal therefrom, and may output a corresponding control signal according to the command data signal, and the control signal may directly (or after performing, for example, signal amplification processing via the optional second switch driving unit 330) drive the controlled module 40 to be closed. Thereby, the power supply 70 may supply power (if selected) to the second switch driving unit 330 through the controlled module 40 via the connection line c. If controlled module 40 employs a monostable switch, device 80 may output a valid signal to maintain controlled module 40 in a closed state, and if controlled module 40 employs a bistable switch, device 80 may output a high impedance state. To this end, the wireless remote controller 90 may stop sending the wireless energy signal, so that the switch part 230 in the passive wake-up module 20 may be turned off, and the power supply 70 stops supplying power to the control module 30; when the device 80 needs to be shut down, such as when it is done, a disconnect command may be sent from the wireless remote control 90 to disconnect the power supply 70, thereby causing the device 80 to return to a zero power consumption standby state (i.e., a passive standby state). Of course, in some applications, it is also possible to actively output a signal from the device 80 to the controlled module 40 or the second switch driving unit 330 (if selected) to disconnect the power supply, thereby returning itself to the zero power consumption standby state. In the above process, the transceiving antenna 10 may transmit wireless signals according to the application requirement, and any suitable information, such as control execution condition, control result feedback, etc., may be included in the wireless signals, which may be received by the wireless remote control device in the system of the present invention.

By way of further illustration, two other different wireless control device embodiments, namely a wireless switching device 200 and a wireless switching device 300, are further schematically illustrated in fig. 4 and 5. To avoid repetition, the following descriptions of the two different embodiments, which are the same as or similar to the embodiment of fig. 3 discussed above, may be directly referred to the detailed description of the corresponding parts, and will not be repeated herein, unless otherwise specified.

First, in the wireless switching apparatus 200 shown in fig. 4, in which the power supply 70 may adopt an alternating current power supply, the wireless switching apparatus 200 includes a first AC/DC unit 50 and a second AC/DC unit 60 additionally provided therein in addition to the transceiving antenna 10, the passive wake-up module 20, the control module 30, and the controlled module 40.

In the wireless switch device 200, the first AC/DC unit 50 is optionally configured to be connected to the power source 70 at one end and to be connected to the switch part 230 of the passive wake-up module 20 at the other end, and is used to convert the power source 70 into a power form (e.g., performing a transformation rectification process, etc.) suitable for the requirement of the control module 30, so as to supply power to the control module 30 after the switch part 230 of the passive wake-up module 20 enters a closed state. That is, in using the wireless switching device 200, after the passive wake-up module 20 converts the wireless energy signal received by the transceiving antenna 10 into a direct current signal and drives the switching component 230 directly (or via the optional first switch driving unit 220) through it into a closed state, the power supply 70 may be voltage-transformed and rectified via the first AC/DC unit 50 to supply power to the control module 30, which has been schematically indicated in fig. 4 using reference sign b for the connection line between them.

It is also an optional configuration for the second AC/DC unit 60, which may be used simultaneously with the second switch driving unit 330 in the control module 30, for example. The second AC/DC unit 60 is connected to the controlled module 40 and the device 80 at one end, and connected to the second switch driving unit 330 in the control module 30 at the other end, and is used to convert the power source 70 (e.g., performing transformation rectification processing, etc.) into a power source form suitable for the second switch driving unit 330 in the control module 30, so that power can be supplied to the second switch driving unit 330 in the control module 30 through the second AC/DC unit 60 after the controlled module 40 enters the closed state.

Next, the wireless switching device 300 shown in fig. 5 will be described, which may include the transceiving antenna 10, the passive wake-up module 20, the control module 30, the controlled module 40, the first AC/DC unit 50, and the second AC/DC unit 60, and at this time, the power supply 70 may employ an alternating current power supply.

In the wireless switch device 300, the first AC/DC unit 50 is optionally configured to be connected at one end thereof to the switch unit 230 of the passive wake-up module 20 and at the other end thereof to the control module 30, so as to convert (e.g., perform a transformation rectification process or the like) the power source 70 into a power source form suitable for the control module 30 when the switch unit 230 is closed, i.e., the power source 70 can supply power to the control module 30 through the connection line d after performing, e.g., the transformation rectification process via the first AC/DC unit 50.

The second AC/DC unit 60 in the present embodiment is also an optional configuration, which can be used simultaneously with the second switch driving unit 330 in the control module 30, it can adopt the same arrangement as the second AC/DC unit 60 in the above-discussed embodiment of fig. 4, and has the same or similar functions and actions in the entire wireless switching device, and thus, the description will not be repeated.

Referring to fig. 2 and fig. 6, a wireless remote control device is further disposed in the wireless control system of the present invention for cooperating with the wireless switch device. In practical applications, the wireless remote control device may be implemented by using any suitable components, units, modules or devices, such as an electronic chip, a processor, etc., for example, fig. 6 shows an example of a wireless remote control device.

As shown in fig. 6, the wireless remote control device (or referred to as a wireless remote control) 90 may include a transmitting and receiving antenna 91, a remote control module 92, and a remote control module 92. The transmitting and receiving antenna 91 is used for transmitting and receiving wireless signals, which may include, but are not limited to, wireless energy signals, command data signals, and the like, for example, the transmitting and receiving antenna 91 may receive an outward transmission signal from the transmitting and receiving antenna 10. The remote control module 92 is connected to the transceiver antenna 91, and is used to receive user input operations, for example, the user can operate keys, a display device and/or network input to communicate his/her manipulation intention to the remote control module 92, which can perform corresponding processing according to the user input operations, so as to transmit corresponding wireless signals through the transceiver antenna 91. The remote control module 92 may also process a wireless signal received by the transmitting/receiving antenna 91 (e.g., an operation feedback result signal corresponding to a command data signal from the wireless remote control device 90 transmitted by the transmitting/receiving antenna 10).

By way of further illustration, the remote control module 92 may optionally be configured to have a signal modulation and demodulation unit 921, a codec and control unit 922, and a human-machine interaction unit 923, which may receive input operation information of a user (e.g., various possible control commands to switch on between the device 80 and the power supply 70, switch off between the device 80 and the power supply 70, etc.) in any one or more of a key, a display device, a network interaction, etc.

The signal modem 921 is disposed between the transmitting and receiving antenna 91 and the codec and control unit 922, and is configured to perform wireless modulation processing on the command data signal to be transmitted to the outside, and also to convert the wireless signal received from the transmitting and receiving antenna 91 into a digital signal and then supply the digital signal to the codec and control unit 922 for processing.

The codec and control unit 922 is disposed between the signal modem unit 921 and the human-computer interaction unit 923, and is configured to process the user input operation information received from the human-computer interaction unit 923 into a corresponding instruction data signal, and then provide the instruction data signal to the signal modem unit 921, and may also decode the digital signal generated by the signal modem unit 921 through conversion to obtain specific information, where such information may be displayed through the human-computer interaction unit 923 in any suitable manner (such as screen text, sound, light, and the like), so as to facilitate practical application, for example, enable a user to know a feedback result corresponding to a previous input operation thereof.

The wireless switching device and the wireless remote control device in the system according to the invention have been described above by way of example in connection with the different embodiments shown in fig. 3, 4, 5 and 6. It will be appreciated that when the device 80 is in the standby remote controlled state, the physical connection between its interior and the power supply 70 for supplying electrical energy is broken, and the device 80 is now in a completely power-free state, thus ensuring that the current standby power consumption of the overall system, including the wireless switching device, is zero. According to statistics, the generated energy of the whole three gorges can be offset only by the energy consumed by various national household appliances in standby mode every year, so that the popularization and the application of the scheme of the invention can save considerable energy consumption, and great social and economic benefits can be generated.

Furthermore, as mentioned above, when the device 80 is in the passive standby state, the wireless energy signal received by the wireless switching device 100, 200 or 300 from the wireless remote control device 90 is only used to control the on/off of the switch component 230 in the passive wake-up module 20 (i.e. to control when the power supply 70 supplies power to the control module 30), for example, a monostable switch built by an NPN tube is used as the switch component 230, only a voltage of 0.7 volts and a current in the order of microamperes are required to drive the NPN tube closed, if conventional germanium transistors are used, only 0.3 volts and microampere levels of current are required, although many types of switches with lower power consumption are available for use with the present invention, the wireless switching device can work only with low radio frequency energy consumption, and can use accurate directional transmission, therefore, a large amount of wireless energy is saved, and the waste caused by the radiation of a large amount of wireless energy to the air is avoided. It will be appreciated that even if a conventional size 5 battery is used in a wireless switch remote control unit which cooperates with the wireless switch unit, the battery will achieve a desired operating life, thereby not only facilitating the application, but also being capable of considerable savings in use costs in the case of large-scale applications. Meanwhile, the radio frequency energy consumption of the wireless switch remote control device can be effectively reduced, so that parts of a transmitting power amplifier, a transmitting antenna and the like of the wireless switch remote control device can obtain larger design space, and the miniaturization, integration and low cost can be realized more conveniently, so that the practicability of the whole system is obviously enhanced.

It should be noted that, in contrast to the present invention, common features of the wireless switching devices in the various existing wireless control systems are: all the energy consumption required for implementing decoding and control, including before the power supply line between the controlled power supply and the controlled standby device is switched on, needs to be provided by the wireless energy transmitted by the existing wireless remote control. Because the control signal of the wireless remote control device covers a certain range to realize the convenience in operation, the loss of the wireless energy transmission, reception and conversion process is larger, and finally, the proportion of the wireless energy which can be effectively absorbed and utilized to the total transmitted wireless energy is very low. Assuming that a certain wireless switch device needs 10 milliwatts of power for each decoding and control operation, if all the wireless energy transmitted by the wireless remote control device is provided, because the transmission efficiency of the wireless energy is not high, the wireless remote control device may need to use 10 to 100 times of transmission power, i.e. 0.1 to 1 watt of wireless transmission power, so a high-price and large-capacity battery is usually needed, however, most of the transmitted wireless energy is still radiated to the air and wasted. The above situations cause the defects and shortcomings of the existing wireless remote control device in aspects such as battery service life, use cost, space volume optimization, component improvement, realization of accurate directional transmission and the like.

It should also be noted that in many areas, such as home homes, office buildings, factory buildings, etc., the wireless switching devices in the system of the present invention will not, or substantially will not, accidentally turn on power and equipment due to external interference. This is because the dc signal amplitude recovered by the wireless energy receiving and converting unit in the wireless switch device usually reaches a certain level (for example, above 0.1 volt), it is only possible to wake up the power supply to supply power to the control module in the wireless switch device, which is completely difficult to reach by the common remote control signal. After a lot of practical tests, even if the mobile phone in the call state (or the networking state) is 0.1 meter away from the wireless switch device, the wireless switch device cannot recover the direct current of more than 0.1 volt at this time. In practical application, the wireless energy receiving and converting unit in the wireless switch device can be set to only absorb and process wireless energy signals within a certain frequency range according to different application requirements. In addition, since different appliances are often placed in different rooms, directions and heights, for example, the probability of placing two or more televisions (or refrigerators, air conditioners, etc.) in the same room, in the same direction and at the same height is very small, and therefore if the probability is slightly noticed, the probability of waking up multiple devices to decode at the same time in practical application is not only quite low, but can also be completely avoided.

According to the design idea of the invention, the invention also provides a wireless control method for realizing the power supply on-off operation of the equipment. By way of illustration, such as shown in fig. 7, the wireless control method may include the steps of:

first, in step S11, a wireless control system designed according to the present invention for performing power on/off operation of a device may be provided, and a wireless switch device may be disposed between the device and a power source, for example, the wireless switch device may be directly integrated into the device, or may be used as an external device to connect to both the device and the power source.

In step S12, the transceiver antenna of the wireless switch device may be used to receive a wireless signal from the wireless remote control device in the wireless control system, such wireless signal may include, but is not limited to, a wireless energy signal, a command data signal, etc., so that in the following step S13, the wireless energy signal may be used to generate a dc signal as described above, and the dc signal may be used to power the passive wake-up module in the wireless switch device, which, once powered, will cause the power supply to be connected to the control module in the wireless switch device.

Next, in step S14, the wireless switch device may be used to demodulate the command data signal received from its transmitting/receiving antenna to generate a specific control signal, and then the corresponding on or off operation between the power supply and the device may be performed according to such control signal. The above is only an exemplary illustration of the radio control method of the invention, it being understood that it is entirely feasible to apply the method of the invention flexibly according to the actual situation, without departing from the gist of the invention, in order to be able to better satisfy the various requirements which may be different.

For example, in step S12, the wireless switching device/wireless remote controller not used may be constituted by only the wireless switching remote control device as described above and only needs to transmit a wireless energy signal to generate the dc signal in the wireless switching device, but may also have a function of transmitting a plurality of signals such as a wireless energy signal and a command data signal.

As another example, in the above step S14, a signal may be sent from the device to the wireless switch device after the device and the power supply are turned on, so that the controlled module in the wireless switch device may keep performing the turn-on operation between the device and the power supply. Further, in an optional case, in the above step S14, in a case where the device needs to stop operating, for example, an instruction data signal may be sent towards the wireless switching apparatus, for example, through a wireless remote controller or the like, so as to cause a controlled module in the wireless switching apparatus to perform an operation of disconnecting the device from the power supply, thereby causing the device to be in the passive standby state, or the above process may also implement the device to return to the passive standby state by sending a signal from the device to the wireless switching apparatus. With regard to the above alternative specific control modes, the method of the invention allows flexible setting selection according to different application occasions so as to better meet various actual requirements.

It should be understood that devices referred to throughout this document may include, but are not limited to, various types of electronic devices, devices in which such electronic devices are integrated, and the like, such as numerous types of electromechanical devices and the like that may be used in a home, office, business, or manufacturing, and the like. The technical scheme of the invention can effectively control the power supply on-off connection of the devices, and particularly can save a large amount of standby electric energy which is still generally consumed at present.

The wireless control system and the wireless control method for implementing power supply on/off operation of the device according to the present invention have been explained in detail by way of examples only, and these examples are only for illustrating the principles of the present invention and the embodiments thereof, and are not to be construed as limiting the present invention, and various modifications and improvements can be made by those skilled in the art without departing from the spirit and scope of the present invention. Accordingly, all equivalents are intended to be included within the scope of this invention and defined in the claims which follow.

Claims (10)

1. A wireless control system for enabling power on/off operation of a device, comprising:

a wireless switching apparatus for placement between a power source and a device that is in a passive standby state when not powered, and comprising:

the receiving and transmitting antenna is arranged for receiving wireless signals and transmitting outgoing signals outwards, and the wireless signals comprise wireless energy signals and instruction data signals;

a passive wake-up module connected to the transceiver antenna and configured to convert the wireless energy signal received by the transceiver antenna to provide a direct current signal;

a control module connected to the transmitting and receiving antenna, configured to demodulate the command data signal received by the transmitting and receiving antenna and output a control signal after being electrically connected to the power supply by the dc signal, and generate a feedback signal according to an execution result of at least a part of the control signal, wherein the output signal includes the feedback signal; and

a controlled module connected to the control module, the power supply and the device and configured to receive and execute an on-off operation between the device and the power supply according to the control signal; and

a wireless remote control device, comprising:

a transmitting and receiving antenna configured to at least transmit the wireless signal and receive the outgoing signal;

and the remote control module is connected with the transmitting and receiving antenna, is used for receiving and processing input operation of a user to transmit a corresponding wireless signal through the transmitting and receiving antenna, and processes the received external signal.

2. The wireless control system of claim 1, wherein the passive wake-up module comprises at least:

a wireless energy receiving and converting unit connected to the transceiving antenna and configured to convert a wireless energy signal received from the transceiving antenna into the direct current signal; and

the switch component is connected with the wireless energy receiving and converting unit to receive the direct current signal, and is also connected with the power supply and the control module to enter a closed state after receiving the direct current signal, so that the control module and the power supply form an electric connection to be powered by the power supply; and/or

The control module at least comprises:

the signal demodulation unit is connected with the transceiving antenna and is arranged to demodulate and convert the instruction data signal received from the transceiving antenna into a digital signal after the control module is powered by the power supply; and

the decoding and control unit is connected with the signal demodulation unit and the controlled module and is used for decoding the digital signal to generate and output the control signal; and/or

The controlled module is a controlled switch that causes the device to be powered by the power source upon entering a closed state, the controlled switch including a monostable switch and a bistable switch; and/or

The power source comprises a battery, an alternating current power source and a direct current power source, and/or the feedback signal comprises a signal output from the control module to the passive wake-up module to break the electrical connection.

3. The wireless control system according to claim 2, wherein the switch component is a monostable switch, and the passive wake-up module further comprises a first switch driving unit which is connected to the output terminal of the wireless energy receiving and converting unit and the control terminal of the switch component, is arranged to output a driving signal matched with the switch component, and is powered by the direct current signal output by the wireless energy receiving and converting unit before and after the switch component is closed; and/or

The control module further comprises a second switch driving unit, the second switch driving unit is connected with the output end of the decoding and control unit and the control end of the controlled switch, the input end of the second switch driving unit is connected with the equipment, the second switch driving unit is arranged to output a driving signal matched with the second switch driving unit to the controlled switch, the second switch driving unit receives uniform power supply of the whole control module from the power supply before the controlled switch enters a closed state, and receives specific power supply of the controlled switch from the power supply after the controlled switch enters the closed state.

4. The wireless control system of claim 3, wherein when the power source is an alternating current power source, the wireless switching device further comprises a first AC/DC unit disposed between the passive wake-up module and the alternating current power source for converting the alternating current power source into a form of power suitable for use by the control module to supply power to the control module upon the switching component entering the closed state.

5. A wireless control system according to claim 3 or 4, wherein the wireless switching device further comprises a second AC/DC unit connected to the controlled switch, the appliance and the second switch driving unit and arranged to convert the power supply into a form suitable for use by the second switch driving unit to supply power to the second switch driving unit after the controlled switch has been brought into a closed state.

6. The wireless control system according to claim 2, 3 or 4, wherein the wireless energy receiving and converting unit is configured to provide the DC signal to maintain an electrical connection between the control module and the power source at least before the control module outputs the control signal; and/or

The decoding and control unit is arranged to perform the following operations: decoding the digital signal to generate a corresponding instruction data signal, carrying out data transmission correctness verification on the instruction data signal, and judging whether the instruction data signal is sent to the wireless switch device: if yes, outputting a corresponding control signal according to the instruction data signal.

7. The wireless control system of any one of claims 1-4, wherein the remote control module comprises:

the human-computer interaction unit is arranged for receiving input operation of a user;

a signal modulation and demodulation unit connected to the transmitting and receiving antenna and configured to perform wireless modulation processing on the command data signal waiting to be transmitted from the transmitting and receiving antenna and convert the outgoing signal received by the transmitting and receiving antenna into a digital signal; and

and the coding, decoding and control unit is connected with the human-computer interaction unit and the signal modulation and demodulation unit, is arranged for processing the received input operation of the user into a corresponding instruction data signal and providing the instruction data signal to the signal modulation and demodulation unit, and decodes the digital signal converted by the signal modulation and demodulation unit into specific information.

8. The wireless control system according to claim 7, wherein the human-computer interaction unit is configured to receive an input operation of the user through a key, a display device and/or a network input operation mode, and/or the information comprises an operation feedback result corresponding to the instruction data signal sent from the wireless switch device.

9. A wireless control method for realizing power supply on-off operation of equipment is characterized by comprising the following steps:

A. providing a wireless control system for enabling power on/off operation of a device according to any one of claims 1-8, and arranging a wireless switching device therein between the device and a power source;

B. enabling a transmitting and receiving antenna in the wireless switch device to receive wireless signals transmitted from a transmitting and receiving antenna of the wireless remote control device, wherein the wireless signals comprise wireless energy signals and instruction data signals;

C. enabling a passive wake-up module in the wireless switching device to generate a direct current signal based on the received wireless energy signal, and enabling a control module in the wireless switching device to be electrically connected with the power supply through the direct current signal so as to be powered by the power supply; and

D. and enabling the control module to demodulate and generate a control signal based on the received instruction data signal, and executing on-off operation between the equipment and the power supply according to the control signal.

10. The wireless control method for realizing power supply on-off operation of equipment according to claim 9, wherein in step D:

sending a signal from the device to the wireless switching apparatus after the device and the power supply are turned on, so that a controlled module in the wireless switching apparatus keeps performing a turn-on operation between the device and the power supply; and/or

When the equipment needs to be shut down, the command data signal is sent out from the wireless remote control device to the wireless switching device or a signal is sent from the equipment to the wireless switching device, so that the controlled module performs disconnection operation between the equipment and the power supply, and the equipment is in a passive standby state.

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