WO2020224173A1

WO2020224173A1 - Internet of things home system

Info

Publication number: WO2020224173A1
Application number: PCT/CN2019/109123
Authority: WO
Inventors: 张少林; 梁勤飞; 丘春辉
Original assignee: 深圳威富智慧家居科技有限公司
Priority date: 2019-05-07
Filing date: 2019-09-29
Publication date: 2020-11-12
Also published as: CN110095991A

Abstract

An Internet of Things home system (10), comprising a main control assembly (110), a central control assembly (120) and a power supply assembly (130), a direct-current power supplying device (132) of the power supply assembly (130) outputting a direct current. After the main control assembly (110) transmits a control signal, the central control assembly (120) can control the turn-on and turn-off of a first switching device (134) of the power supply assembly (130) according to the control signal, so as to control the output of the direct-current power supplying device (132). The Internet of Things home system (10) can control the home power supply, thereby improving the convenience and safety of the Internet of Things home system (10).

Description

Internet of Things Home System

Related application

This application claims the priority of the Chinese patent application filed on May 07, 2019, the application number is 201910376053.6, and the title is "Internet of Things Home System", the full text of which is hereby incorporated by reference.

Technical field

This application relates to smart home technology, especially to the Internet of Things home system.

Background technique

At present, with the advancement of technology, people's living standards have gradually improved, and the use of household appliances has become more common. As a result, people have put forward higher requirements for the intelligence, safety and convenience of modern home systems.

In traditional smart home systems, household appliances are usually connected to the Internet of Things to control the household appliances.

In the process of implementing the traditional technology, the applicant discovered that the traditional Internet of Things home system cannot realize the control of the home power supply.

Summary of the invention

In view of this, this application discloses an IoT home system capable of controlling home power supply.

An Internet of Things home system, including:

The main control component includes a first communicator to transmit control signals;

The central control component includes a second communicator and a first processor, the second communicator is communicatively connected to the first communicator, and the second communicator is electrically connected to the first processor to obtain The control signal is transmitted to the first processor, and the first processor processes the control signal to obtain a wireless communication signal, and the wireless communication signal includes a first communication signal;

The power supply component includes a DC power supply, a first switch, a second processor, and a third communicator. The DC power supply can be electrically connected to the power grid to obtain AC power in the power grid and convert it to DC power for output; The first switch is electrically connected to the DC power supply to control the on/off of the circuit between the DC power supply and the power grid; the second processor is electrically connected to the first switch, the The third communicator is electrically connected with the second processor, and the third communicator is communicatively connected with the second communicator, so that the third communicator acquires the first communication signal and transmits it to all The second processor controls the on-off of the first switch according to the first communication signal to control the on-off of the circuit between the DC power supply and the power grid.

It can be seen from the above technical solutions that this application discloses an IoT home power supply system, which includes a main control component, a central control component and a power supply component, and outputs DC power through a DC power supply of the power supply component. In the Internet of Things home system, after the control signal is transmitted by the main control component, the central control component can control the on and off of the first switch of the power supply component according to the control signal, thereby controlling the output of the DC power supply. The Internet of Things home system can control home power supply, thereby improving the convenience and safety of the Internet of Things home system.

Description of the drawings

In order to more clearly describe the technical solutions in the embodiments of the present application or the prior art, the following will briefly introduce the drawings that need to be used in the description of the embodiments or the prior art. Obviously, the drawings in the following description are only These are the embodiments of the present application. For those of ordinary skill in the art, other drawings may be obtained from the disclosed drawings without creative work.

FIG. 1 is a schematic diagram of the device structure of the Internet of Things home system in an embodiment of the application.

2 is a schematic diagram of the device structure of the Internet of Things home system in another embodiment of the application.

FIG. 3 is a schematic diagram of the device structure of the Internet of Things home system in another embodiment of the application.

FIG. 4 is a schematic diagram of the device structure of the Internet of Things home system in another embodiment of the application.

FIG. 5 is a schematic diagram of the device structure of the Internet of Things home system in another embodiment of the application.

FIG. 6 is a schematic diagram of the device structure of the Internet of Things home system in another embodiment of the application.

FIG. 7 is a schematic diagram of the device structure of the Internet of Things home system in another embodiment of the application.

Detailed ways

The technical solutions in the embodiments of the present application will be clearly and completely described below in conjunction with the drawings in the embodiments of the present application. Obviously, the described embodiments are only a part of the embodiments of the present application, rather than all of the embodiments. Based on the embodiments in this application, all other embodiments obtained by those of ordinary skill in the art without creative work shall fall within the protection scope of this application.

The present application provides an IoT home system 10, as shown in FIG. 1, including a main control component 110, a central control component 120, and a power supply component 130.

Specifically, the main control component 110 is provided with a first communicator 112 so that control signals can be sent out through the first communicator 112. The main control component 110 may be a remote control or other control device that can send out wireless communication signals.

The central control component 120 includes a second communicator 122 and a first processor 124. Wherein, the second communicator 122 is in communication connection with the first communicator 112 to perform information transmission, so that the second communicator 122 can receive the control signal sent by the first communicator 112. The second communicator 122 is also electrically connected to the first processor 124. When the second communicator 122 works, it obtains a control signal from the first communicator 112 and transmits it to the first processor 124. After the first processor 124 obtains the control signal, it processes the control signal to obtain a wireless communication signal. The wireless communication signal may include a first communication signal for controlling the power supply component 130. After the first processor 124 obtains the wireless communication signal, it transmits the wireless communication signal to the second communicator 122 for transmission through the second communicator 122. The central control component 120 may be a central controller.

The power supply component 130 includes a DC power supply 132, a first switch 134, a second processor 136 and a third communicator 138. Wherein, the DC power supply 132 may be provided with an AC/DC conversion circuit, which is electrically connected to the power grid 20 during operation, so as to obtain the AC power in the power grid 20 and convert it into DC power for output. The first switch 134 is electrically connected between the DC power supply 132 and the power grid 20 during operation, and is used to control the on/off of the circuit between the power grid 20 and the DC power supply 132. The first switch 134 is also electrically connected to the second processor 136 to be controlled by the second processor 136. The third communicator 138 is communicatively connected to the second communicator 122, and is electrically connected to the second processor 136 to obtain the first communication signal from the second communicator 122 and transmit it to all Mentioned second processor 136. The second processor 136 can control the on-off of the first switch 134 according to the first communication signal.

More specifically, when the IoT household system 10 of the present application is working, the user can send a control signal through the first communicator 112 of the main control component 110. The control signal is received by the second communicator 122 of the central control component 120. The second communicator 122 transmits the control signal to the first processor 124 after receiving the control signal. The first processor 124 processes the control signal to obtain control commands corresponding to different controlled components, and names the control commands corresponding to different controlled components as wireless communication signals. Wherein, the part of the wireless communication signal corresponding to the power supply component 130 is named the first communication signal. The wireless communication signal may be transmitted through the second communicator 122. The third communicator 138 of the power supply component 130 can identify and receive the first communication signal in the wireless communication signal. After the third communicator 138 obtains the first communication signal, it transmits it to the second processor 136. The second processor 136 can control the first switch 134 to close or open according to the first communication signal. When the first switch 134 is closed, the DC power supply 132 can output DC power. When the first switch 134 is turned off, the DC power supply 132 stops outputting DC power. The Internet of Things home system 10 can control home power supply, thereby improving the convenience and safety of the Internet of Things home system 10.

In one embodiment, as shown in FIG. 2, in the IoT household system 10, the power supply component 130 further includes a DC voltage regulator 133.

Specifically, the DC voltage regulator 133 is electrically connected between the DC power supply 132 and the first switch 134, and is used to adjust the DC power output voltage of the DC power supply 132. The DC voltage regulator 133 may also be electrically connected to the second processor 136 so as to be controlled by the second processor 136. At this time, the first communication signal may include a signal that controls the first switch 134 to close or open, or may further include a signal that controls the operation of the DC voltage regulator 133 to increase or decrease the voltage. . When the Internet of Things home system 10 is working, the power supply component 130 can output DC power with an adjustable voltage or stop outputting DC power according to the control signal, which improves its convenience. Wherein, the DC voltage regulator 133 may be a DC voltage regulator.

In an embodiment, the DC power supply 132 includes at least one of a DC socket and a serial wire interface.

Specifically, the DC power supply 132 may be a DC socket, so that when the DC power supply 132 is working, it supplies power to the household appliances plugged into the DC socket. The DC power supply 132 may also be a Universal Serial Bus (USB), so that when the DC power supply 132 is working, it can supply power to devices such as mobile phones or tablet computers that are charged through the USB.

In an embodiment, as shown in FIG. 2, the power supply assembly 130 further includes an AC power supply 131 and a second switch 137.

Specifically, the AC power supply 131 is electrically connected to the power grid 20 during operation, so as to obtain and output AC power in the power grid 20. The second switch 137 is electrically connected between the AC power supply 131 and the power grid 20, and is used to control the on and off of the circuit between the power grid 20 and the AC power supply 131. The second switch 137 is also electrically connected to the second processor 136 to be controlled by the second processor 136.

Further, when a control signal is sent to the central control component 120 through the main control component 110, the hollow component analyzes the control signal and sends a first communication signal to the power supply component 130. At this time, the first communication signal may not only include the closing or opening of the first switch 134, but also the closing or opening of the second switch 137. The IoT home system 10 can control the output of AC power by controlling the second switch 137, thereby further controlling the home power supply, and improving the convenience and safety of the IoT home system 10.

In an embodiment, as still shown in FIG. 2, in the IoT household system 10, the power supply component 130 may further include an AC voltage regulator 135.

Specifically, the AC voltage regulator 135 is electrically connected between the AC power supply 131 and the second switch 137, and is used to adjust the voltage of the AC power output by the AC power supply 131. The AC voltage regulator 135 may also be electrically connected to the second processor 136 so as to be controlled by the second processor 136. At this time, the first communication signal may include a signal for controlling the closing or opening of the second switch 137, or may further include a signal for controlling the operation of the AC voltage regulator 135 to increase or decrease the voltage. . When the Internet of Things home system 10 is working, the power supply component 130 can output AC power with an adjustable voltage or stop outputting AC power according to the control signal, which improves its convenience. Wherein, the AC voltage regulator 135 may be an AC voltage regulator.

In an embodiment, as shown in FIG. 3, the IoT home system 10 may further include a home appliance component 140 controlled by the central control component 120.

Specifically, the home appliance component 140 includes a worker 142, a third processor 144, and a fourth communicator 146. Among them, the worker 142 is used for power-on work. For example, when the household appliance component 140 is an air conditioner, the worker 142 can be a cooling and heating device to cool or heat when it is energized. When the household appliance component 140 is a refrigerator, the worker 142 may be a refrigerator to cool when it is energized. The third processor 144 is electrically connected to the worker 142 to control whether the worker 142 works. The fourth communicator 146 is electrically connected to the third processor 144 to transmit electrical signals to the third processor 144.

More specifically, when the IoT household system 10 further includes the home appliance component 140, the wireless communication signal may include the second communication signal corresponding to the home appliance component 140. At this time, the user can send a control signal through the main control component 110. The control signal is received by the second communicator 122 of the central control component 120. The second communicator 122 transmits the control signal to the first processor 124 after receiving the control signal. The first processor 124 processes the control signal to obtain control commands corresponding to different controlled components, and names the control commands corresponding to different controlled components as wireless communication signals. Wherein, the part corresponding to the household appliance component 140 in the wireless communication signal is named the second communication signal. When the second communicator 122 transmits the wireless communication signal, the second communication signal can be acquired by the fourth communicator 146. At this time, the third processor 144 can control the work of the worker 142 according to the second communication signal.

Optionally, the aforementioned home appliance component 140 may include at least one of air conditioners, washing machines, refrigerators, sweepers, televisions, electric curtains, electric water heaters, electronic safety locks, stereos, and electric lights. It should be understood that the present application provides an Internet of Things home system 10, the purpose of which is to improve the convenience of using home appliances. Therefore, the home appliance component 140 here is not limited to the several examples in this application. All home appliances that can realize information transmission through the wireless signal transceiving device and the central control component 120 should be understood as falling within the protection scope of this application.

The aforementioned Internet of Things home system 10 can not only control the power supply of the home, but also control whether the home appliance component 140 is working or not, thereby improving the convenience of the Internet of Things home system 10.

In one embodiment, as shown in FIG. 4, the IoT home system 10 may further include a weak electrical signal component 150 controlled by the central control component 120.

Specifically, the weak current signal component 150 includes a weak current signal line 151, a third switch 152, a fourth processor 154, and a fifth communicator 156. Among them, weak electrical signals refer to direct current signals or audio signals, video signals, network signals, telephone signals, etc. The weak current signal line 151 refers to a line used to provide a weak current signal. When a path is formed in the weak current signal line 151, a weak current signal is provided. The third switch 152 is electrically connected to the weak current signal line 151 to control the on/off of the signal in the weak current signal line 151. The fourth processor 154 is electrically connected to the third switch 152 so as to control the on and off of the third switch 152. The fifth communicator 156 is electrically connected with the fourth processor 154 to transmit electrical signals to the fourth processor 154.

More specifically, when the IoT household system 10 further includes the weak electrical signal component 150, the wireless communication signal may include the third communication signal corresponding to the weak electrical signal component 150. At this time, the user can send a control signal through the main control component 110. The control signal is received by the second communicator 122 of the central control component 120. The second communicator 122 transmits the control signal to the first processor 124 after receiving the control signal. The first processor 124 processes the control signal to obtain control commands corresponding to different controlled components, and names the control commands corresponding to different controlled components as wireless communication signals. Wherein, the part of the wireless communication signal corresponding to the weak electric signal component 150 is named the third communication signal. When the second communicator 122 transmits the wireless communication signal, the third communication signal can be acquired by the fifth communicator 156. At this time, the fourth processor 154 can control the third switch 152 to work according to the third communication signal, thereby controlling the on/off of the signal in the weak current signal line 151.

Optionally, the aforementioned weak current signal line 151 may include at least one of a network signal line, a TV signal line, and a telephone signal line. It should be understood that the present application provides an Internet of Things home system 10, the purpose of which is to improve the convenience of home. Therefore, the weak current signal line 151 here is not limited to the several examples in this application, and other weak current signal lines 151 used to provide electrical signals should also be understood as falling within the protection scope of this application.

The aforementioned IoT home system 10 can also control whether the weak current signal line 151 is output or not, thereby improving the scope of application of the IoT home system 10 and improving the convenience of the IoT home system 10.

In an embodiment, the second communicator 122 includes at least one of a mobile communicator, an optical fiber communicator, a Bluetooth communicator, a wireless fidelity communicator, a Zigbee communicator, and a cellular network communicator.

Specifically, in the foregoing embodiments, the second communicator 122 is configured to receive the control signal sent by the first communicator 112, and send the control signal to the third communicator 138, the fourth communicator 146, and At least one of the fifth communicators 156 sends out wireless communication signals. In other words, the second communicator 122 is used to exchange information with the first communicator 112, the third communicator 138, the fourth communicator 146, and the fifth communicator 156. Among them, the way of information interaction should be mobile communication, optical fiber communication, Bluetooth communication, wireless fidelity (WIFI, Wireless-Fidelity), ZigBee (ZigBee) communication, cellular network (NB-IoT, Narrow Band Internet of Things) communication , At least one of Lora communication and Z-wave communication. That is, any one of the first communicator 112, the second communicator 122, the third communicator 138, the fourth communicator 146, and the fifth communicator 156 may include a mobile communicator , Fiber optic communicator, Bluetooth communicator, Wi-Fi communicator, Zigbee communicator, cellular network communicator, Lora communicator and Z-wave communicator.

In one embodiment, as shown in FIG. 5, in the IoT household system 10, the central control component 120 further has a gateway interface 126.

Specifically, the gateway interface 126 is electrically connected to the second processor 136. The gateway interface 126 can be used to electrically connect with other Internet of Things or other networks that can transmit control signals, so as to enhance the compatibility of the Internet of Things household system 10 of the present application.

In one embodiment, as shown in FIG. 6, the IoT household system 10 may further include a detection control component 160 for sending control signals.

Specifically, the detection control component 160 includes an environmental signal detector 162, a fifth processor 164, and a sixth communicator 166. The environmental signal detector 162 is used to detect environmental signals. The environmental signals may include not only environmental humidity, environmental temperature, air quality, etc., but also infrared signals and sound signals brought by the human body. The fifth processor 164 is electrically connected to the environmental signal detector 162 to obtain the environmental signal detected by the environmental signal detector 162. When the fifth processor 164 is working, it processes the environmental signal to obtain a control signal. The sixth communicator 166 is electrically connected to the fifth processor 164 to obtain and transmit the control signal. The sixth communicator 166 is also communicatively connected with the second communicator 122 to transmit wireless signals to the second communicator 122.

More specifically, when the IoT home system 10 is working, the environmental signal detector 162 can detect environmental signals and transmit the environmental signals to the fifth processor 164. The fifth processor 164 may obtain a corresponding control signal according to the environmental signal, and transmit it to the second communicator 122 through the sixth communicator 166. For example, when the environmental signal detector 162 detects the environmental humidity and air quality, it may transmit the environmental humidity and air quality to the fifth processor 164. After the fifth processor 164 processes the environmental humidity and air quality, it can send a control signal to control the operation of the home appliance components 140 such as air conditioners, electric curtains, and humidifiers according to the environmental humidity and air quality at this time. The environmental signals may also include infrared signals and sound signals brought by the human body. For example, when the environmental signal detector 162 detects a human infrared signal, the human infrared signal may be transmitted to the fifth processor 164. The fifth processor 164 can combine the position and time of the infrared signal of the human body to control whether the electric light works or not.

Further, the environmental signal detector 162 of the IoT home system 10 may include face recognition equipment, fingerprint recognition equipment, iris recognition equipment, finger vein recognition equipment, video monitoring equipment, infrared detection equipment, sound detection equipment, and physical signs. At least one of detection equipment, air quality detection equipment, temperature monitoring equipment, humidity detection equipment, and smoke alarm equipment.

Specifically, face recognition equipment, fingerprint recognition equipment, iris recognition equipment, and finger vein recognition equipment can be used for door locks. When at least one of the face recognition device, fingerprint recognition device, iris recognition device, and finger vein recognition device is working and unlocked, the fifth processor 164 can send control signals according to the environmental signal, such as controlling electric lights, air conditioners, and sweeping The machine waits open. Video surveillance equipment can be used for indoor security. For example, after the video surveillance equipment obtains face information and transmits it to the fifth processor 164, the fifth processor 164 may compare the face information with an information database, if the face information If it is not in the information database, a control signal is sent to control the work of the safety alarm.

It should be understood that, here are only a few examples of possible detection and control components 160. Other detection control components 160 not listed in this application should also be understood as falling within the protection scope of this application.

Furthermore, in the aforementioned IoT household system 10, the sixth communicator 166 can also obtain the wireless communication signal transmitted by the second communicator 122. The fifth processor 164 may control the operation of the environmental signal detector 162 according to the wireless communication signal. For example, when the head of the household needs to turn off the detection control component 160, the main control component 110 may send a control signal to the central control component 120. At this time, the central control component 120 processes the control signal and sends out wireless communication signals. The wireless communication signal includes the fourth communication signal of the detection control component 160. After the sixth communicator 166 obtains the fourth communication signal, it is transmitted to the fifth processor 164. The fifth processor 164 may control the environmental signal detector 162 to turn off according to the fourth communication signal.

The aforementioned IoT home system 10 further includes the detection control component 160. The detection control component 160 can detect environmental information, so that the IoT household system 10 can control household power supply and household appliances according to the environmental information. The Internet of Things home system 10 can control home power supply and household appliances according to environmental signals, which improves its intelligence. At the same time, the user can also control the operation of the environmental signal detector 162 by transmitting control signals, which improves the convenience of the IoT home system 10.

In an embodiment, as shown in FIG. 7, the IoT home system 10 may further include a mobile device 170.

Specifically, the mobile device 170 may be a mobile electronic device such as a mobile phone, a tablet computer, or a personal computer that can send communication signals. The mobile device 170 has a seventh communicator 172. The seventh communicator 172 is communicatively connected with the second communicator 122 to send a control signal to the second communicator 122.

More specifically, in the IoT household system 10 of the present application, the user can not only send control signals through the main control component 110, but also send control signals by the mobile device 170. The seventh communication signal can realize information transmission with the second communication signal through at least one of mobile communication or optical communication. The Internet of Things home system 10 can send control signals to the central control component 120 through the mobile device 170 to control home power supply and household appliances, thereby improving the convenience of the Internet of Things home system 10.

In an embodiment, the IoT home system 10 also has a remote monitoring function.

Specifically, in the IoT home system 10, the central control component 120 may also obtain the status of each component connected to the IoT and send it to the mobile device 170. In this way, the working status of each component connected to the Internet of Things home system 10 can be monitored on the mobile device 170.

Further, the central control component 120 of the Internet of Things home furnishing system 10 may also include a memory 128. The memory 128 is in communication connection with the first processor 124. After the first processor 124 obtains the working state through the second communicator 122, it may also be transferred to the memory 128 for storage.

For example, for the power supply component 130, the second processor 136 may obtain the on-off state of the first switch 134, and generate a first monitoring signal according to the on-off state of the first switch 134. The second processor 136 may also transmit the first monitoring signal to the second communicator 122 through the third communicator 138. After the first processor 124 obtains the first monitoring signal through the second communicator 122, it may send the first monitoring signal to the mobile device 170 through the second communicator 122 again. At the same time, the first processor 124 may also transmit the first monitoring signal to the memory 128 for storage.

Similarly, the second processor 136 may also obtain the working status of the DC voltage regulator 133, generate a second monitoring signal, and send it to the central control component 120 through the third communicator 138. The central control component 120 may send the second monitoring signal to the mobile device 170. At the same time, the first processor 124 may also transfer the second monitoring signal to the memory 128 for storage.

For the detection control component 160, when the environmental signal detector 162 includes a monitor, the fifth processor 164 in the detection control component 160 can also obtain the monitoring information of the monitor in real time, and transmit it to the monitor. The central control component 120 is stored by the memory 128. The signal stored in the memory 128 may be a digital signal, so as to facilitate the output of the monitoring screen when being read.

Furthermore, the second communicator 122 may also be connected to a cloud server, so as to store the monitoring signal in the cloud server.

In other embodiments, the mobile device 170 can monitor the working status of the worker 142, the weak current signal line 151, and the environmental signal detector 162. No longer.

The following describes the IoT home system 10 of the present application in detail in conjunction with a specific embodiment.

The IoT home system 10 may include a main control component 110, a mobile device 170, a detection control component 160, a central control component 120, a power supply component 130, a household appliance component 140, and a weak current signal component 150. Wherein, the main control component 110, the mobile device 170, and the detection control component 160 can be used to send control signals. The central control component 120 is used to obtain a control signal and control the corresponding controlled component according to the control signal. The power supply component 130, the home appliance component 140, and the weak electrical signal component 150 are controlled components.

Wherein, the home appliance component 140 includes at least one of an air conditioner, a washing machine, a refrigerator, a sweeper, a TV, an electric curtain, and an electric lamp. The weak electrical signal line 151 in the weak electrical signal component 150 includes at least one of a network signal line, a television signal line, and a telephone signal line. The detection control component 160 includes a camera, an infrared human body sensor, a microphone, a smoke alarm, an air quality detector, a temperature detector, a humidity detector, a physical sign detector, a face recognition door lock, a finger vein recognition door lock, At least one of fingerprint recognition door locks, Bluetooth gateway door locks, Lora smart locks, wifi smart locks, zigbee smart locks, Z-wave smart locks, and NB-IOT smart locks.

The main control component 110 can transmit simpler control signals. For example, in the daytime, the user can send a first control signal through the main control component 110. At this time, the central control component 120 can control the electric light in the household appliance component 140 to turn off according to the first control signal. And control the electric curtain in the household appliance component 140 to open. In addition, the central control component 120 can also control the operation of the weak current signal component 150 according to the first control signal. When sleeping at night, the user can send a second control signal through the main control component 110. At this time, the central control component 120 can control the lights in the home appliance component 140 to turn off according to the second control signal, and The electric curtain in the household appliance component 140 is controlled to close. In addition, the central control component 120 can also control the weak current signal component 150 to stop working according to the first control signal. When the user leaves the home, a third control signal can be sent. At this time, the central control component 120 can control the lights in the home appliance component 140 to turn off, the curtains are closed, and the door locks are closed according to the third control signal. .

The mobile device 170 can send more complicated and detailed control signals. For example, the power supply component 130 may include a plurality of DC power supplies 132. The plurality of DC power supplies 132 are numbered 1, 2, 3...N. When the user wants to control the DC power supply 132 with the number 3 to supply power, the mobile device 170 such as a mobile phone can send a control signal to separately control the DC power supply 132 with the number 3 to supply power.

The first processor 124 of the central control component 120 may also be provided with a preset program, so as to send different wireless communication signals for different environmental signals, thereby controlling the operation of the household appliance component 140 and the power supply component 130 jobs. No longer.

Wherein, the second communicator 122 is connected to the first communicator 112, the third communicator 138, the fourth communicator 146, the fifth communicator 156, the sixth communicator 166, and the The seventh communicator 172 can communicate through any one of 5G mobile communication, 4G mobile communication, optical fiber communication, wired network communication, Bluetooth communication, WIFI communication, Zigbee communication, Lora communication, Z-wave communication, and cellular network communication. One or more ways to implement communication.

The power supply component 130 may include a plurality of the AC power supply 131 and a plurality of the DC power supply 132. The plurality of AC power supplies 131 can be controlled individually or collectively; the plurality of DC power supplies 132 can be controlled individually or collectively. The output voltage of any of the power supplies can be customized by the mobile device 170.

The home power supply system may also have energy supply components. The energy supply component may be electrically connected with other components in the household power supply system to supply electrical energy to other components. The power supply component may be a solar power generation device or other power generation devices or electrical energy storage devices.

Finally, it should be noted that in this article, relational terms such as first and second are only used to distinguish one entity or operation from another entity or operation, and do not necessarily require or imply these entities Or there is any such actual relationship or sequence between operations. Moreover, the terms "include", "include" or any other variants thereof are intended to cover non-exclusive inclusion, so that a process, method, article, or device that includes a series of elements includes not only those elements, but also includes Other elements of, or also include elements inherent to this process, method, article or equipment. If there are no more restrictions, the element defined by the sentence "including a..." does not exclude the existence of other same elements in the process, method, article, or equipment including the element.

The various embodiments in this specification are described in a progressive manner. Each embodiment focuses on the differences from other embodiments, and the same or similar parts between the various embodiments can be referred to each other.

The foregoing description of the disclosed embodiments enables those skilled in the art to implement or use this application. Various modifications to these embodiments will be obvious to those skilled in the art, and the general principles defined in this document can be implemented in other embodiments without departing from the spirit or scope of the application. Therefore, this application will not be limited to the embodiments shown in this document, but should conform to the widest scope consistent with the principles and novel features disclosed in this document.

Claims

An Internet of Things home system, characterized in that it includes:

The main control component (110) includes a first communicator (112) to transmit control signals;

The central control component (120) includes a second communicator (122) and a first processor (124), the second communicator (122) is in communication connection with the first communicator (112), and the The second communicator (122) is electrically connected with the first processor (124) to obtain the control signal and transmit it to the first processor (124), and the first processor (124) responds to the Control signal processing to obtain a wireless communication signal, where the wireless communication signal includes a first communication signal;

The power supply component (130) includes a DC power supply (132), a first switch (134), a second processor (136) and a third communicator (138). The DC power supply (132) can be connected to the power grid ( 20) Electrical connection to obtain alternating current in the power grid (20) and convert it into direct current for output; the first switch (134) is electrically connected to the direct current power supply (132) to control the direct current supply The circuit between the electrical appliance (132) and the power grid (20) is on and off; the second processor (136) is electrically connected to the first switch (134), and the third communicator (138) is connected to The second processor (136) is electrically connected, and the third communicator (138) is communicatively connected with the second communicator (122), so that the third communicator (138) obtains the first communication Signal and transmit it to the second processor (136), and the second processor (136) controls the on-off of the first switch (134) according to the first communication signal to control the The circuit between the DC power supply (132) and the grid (20) is on and off.
The IoT home system according to claim 1, wherein the power supply component (130) further comprises:

The DC voltage regulator (133) is electrically connected between the DC power supply (132) and the first switch (134), and the DC voltage regulator (133) is also connected to the second processor ( 136) is electrically connected, and the second processor (136) can control the operation of the DC voltage regulator (133) according to the first communication signal, thereby adjusting the output voltage of the DC power supply (132).
The Internet of Things home system according to claim 2, wherein the Internet of Things home system (10) includes a plurality of DC power supplies (132), and the plurality of DC power supplies (132) are electrically connected in parallel.
The IoT household system according to claim 3, wherein the DC power supply (132) comprises a DC socket.
The Internet of Things home system according to claim 3, wherein the DC power supply (132) comprises a serial line interface.
The IoT home system according to claim 1, wherein the power supply component (130) further comprises:

AC power supply (131);

The second switch (137) is electrically connected to the AC power supply (131) and the second processor (136), and the second processor (136) controls the The second switch (137) is on and off, and the AC power supply (131) can be electrically connected to the power grid (20) through the second switch (137) to obtain AC power in the power grid (20) And output.
The Internet of Things household system according to claim 6, wherein the power supply component (130) further comprises:

The AC voltage regulator is electrically connected between the AC power supply (131) and the second switch (137), the AC voltage regulator is also electrically connected with the second processor (136), so The second processor (136) can control the AC voltage regulator according to the first communication signal, thereby adjusting the output voltage of the AC power supply (131).
The Internet of Things home system according to claim 1, wherein the wireless communication signal further comprises a second communication signal, and the Internet of Things home system (10) further comprises a home appliance component (140); the home appliance component ( 140) includes:

Worker (142);

The third processor (144) is electrically connected to the worker (142) to control the worker (142);

The fourth communicator (146) is electrically connected to the third processor (144), and the fourth communicator (146) is communicatively connected to the second communicator (122), so that the fourth The communicator (146) obtains the second communication signal and transmits it to the third processor (144), and the third processor (144) controls the worker (142) according to the second communication signal.
The Internet of Things household system according to claim 8, wherein the home appliance component (140) includes at least one of an air conditioner, a washing machine, a refrigerator, a sweeper, a TV, an electric curtain, a stereo and an electric light.
The Internet of Things household system according to claim 8, wherein the worker (142) comprises at least one of a heater and a refrigerator.
The Internet of Things home system according to claim 1, wherein the wireless communication signal further comprises a third communication signal, and the Internet of Things home system (10) further comprises a weak electrical signal component (150); the weak electrical signal The components (150) include:

Weak current signal line (151);

A third switch (152), the third switch (152) is electrically connected to the weak current signal line (151) to control the on/off of the signal in the weak current signal line (151);

The fourth processor (154) is electrically connected to the third switch (152) to control the on and off of the third switch (152);

The fifth communicator (156) is electrically connected to the fourth processor (154), and the fifth communicator (156) is electrically connected to the second communicator (122), so that the fifth The communicator (156) obtains the third communication signal and transmits it to the fourth processor (154), and the fourth processor (154) controls the third switch (152) according to the third communication signal. ) On and off.
The Internet of Things home system according to claim 11, wherein the weak current signal line (151) comprises at least one of an audio signal line, a video signal line, a network signal line, and a telephone signal line.
The Internet of Things home system according to claim 1, wherein the second communicator (122) comprises a mobile communicator, an optical fiber communicator, a Bluetooth communicator, a wireless fidelity communicator, a Zigbee communicator and a cellular At least one of network communicators.
The Internet of Things home system according to claim 1, wherein the central control component (120) further comprises a gateway interface (126), and the gateway interface (126) is electrically connected to the second processor (136). Connected to transmit control signals to the second processor (136).
The IoT household system according to claim 1, characterized in that it further comprises a detection control component (160), comprising:

Environmental signal detector (162) for detecting environmental signals;

The fifth processor (164) is electrically connected to the environmental signal detector (162) to obtain the environmental signal and process the environmental signal to obtain a control signal. The fifth processor (164) also uses To control the operation of the detection control component (160);

The sixth communicator (166) is electrically connected to the fifth processor (164) and is communicatively connected to the second communicator (122) to obtain the control signal and send it to the second communicator (122).
The Internet of Things home system according to claim 15, characterized in that, the environmental signal detector (162) includes face recognition equipment, fingerprint recognition equipment, iris recognition equipment, finger vein recognition equipment, video surveillance equipment, infrared detection equipment At least one of equipment, sound detection equipment, and physical sign detection equipment.
The IoT household system according to claim 15, wherein the environmental signal detector (162) comprises at least one of air quality detection equipment, temperature monitoring equipment, humidity detection equipment and smoke alarm equipment.
The Internet of Things household system according to claim 1, further comprising:

The mobile device (170) includes a seventh communicator (172), which is communicatively connected with the second communicator (122) to transmit control to the second communicator (122) signal.
The Internet of Things home system according to claim 18, wherein the second processor (136) also generates a first monitoring signal according to the on-off state of the first switch (134), and passes the The third communicator (138) is launched;

The central control component (120) further includes: a memory (128), which is communicatively connected with the first processor (124); the first processor (124) obtains all the information through the second communicator (122) The first monitoring signal is transferred to the memory (128) for storage, and sent to the seventh communicator (172) through the second communicator (122).
The Internet of Things home system according to claim 1, characterized in that it further comprises an energy supply component that is electrically connected to the main control component (110), central control component (120) and power supply component (130). Connected to provide power to the main control component (110), the central control component (120) and the power supply component (130).