CN217467654U - Thing networking lagging and thing networking device - Google Patents

Abstract

The application discloses thing networking lagging and thing networking device, wherein, thing networking lagging includes: the mother board is used for being detachably connected with the main control board and the at least one first functional board; the system comprises one or more first function boards, wherein at least one of a sensor circuit, a man-machine interaction assembly and an equipment access end is arranged on each first function board; the main control circuit is used for acquiring sensor data from the first function board through the motherboard and sending a control instruction to target equipment connected with the equipment access end of the first function board according to the acquired sensor data so as to enable the target equipment to execute a preset function; the main control circuit is further used for sending a human-computer interaction signal to the human-computer interaction assembly on the first function board through the motherboard according to the acquired sensor data and/or the state of executing the preset function of the target device, so that the human-computer interaction assembly can execute the human-computer interaction function according to the human-computer interaction signal, and the use flexibility of the internet of things sleeve board in multiple fields and multiple scenes is improved.

Description

Thing networking lagging and thing networking device

Technical Field

The application relates to the technical field of the Internet of things, in particular to an Internet of things sleeve plate and an Internet of things device.

Background

With the prevalence of the internet of things, more and more various solution suppliers are produced, but the solution suppliers are basically carried out according to the pertinence and small-range requirements of customers, and cannot solve the requirements of popularization and large range at one time. In order to meet the requirements of popularization and large range, an internet of things suite board which can be used in multiple fields and multiple scenes is urgently needed.

SUMMERY OF THE UTILITY MODEL

The main purpose of this application is to provide an thing networking lagging and thing networking device, aims at improving the use flexibility of thing networking lagging in many fields, many scenes to improve the use flexibility of thing networking device in many fields, many scenes.

In a first aspect, the present application provides an internet of things socket, the internet of things socket includes:

the mother board is detachably connected with the main control board and the at least one first function board;

the system comprises one or more first function boards, wherein at least one of a sensor circuit, a man-machine interaction assembly and an equipment access end is arranged on each first function board, the sensor circuit is used for collecting sensor data, and the equipment access end is used for connecting target equipment;

the main control circuit is used for acquiring sensor data from the first function board through the motherboard and sending a control instruction to target equipment connected with the equipment access end of the first function board according to the acquired sensor data so as to enable the target equipment to execute a preset function; the main control circuit is further used for sending human-computer interaction information to the human-computer interaction assembly on the first function board through the motherboard according to the acquired sensor data and/or the state of the target device executing the preset function, so that the human-computer interaction assembly executes the human-computer interaction function according to the human-computer interaction signal.

In a second aspect, the present application further provides an internet of things device, including:

the internet of things sleeve board; and

and the target equipment is connected with the equipment access end on the first function board of the Internet of things sleeve board.

The application provides thing networking lagging and thing networking device, thing networking lagging includes: the mother board is detachably connected with the main control board and the at least one first function board; the system comprises one or more first function boards, wherein at least one of a sensor circuit, a man-machine interaction assembly and an equipment access end is arranged on each first function board, the sensor circuit is used for collecting sensor data, and the equipment access end is used for connecting target equipment; the main control circuit is used for acquiring sensor data from the first function board through the motherboard and sending a control instruction to target equipment connected with the equipment access end of the first function board according to the acquired sensor data so as to enable the target equipment to execute a preset function; the master control circuit is further used for sending human-computer interaction information to the human-computer interaction assembly on the first function board through the mother board according to the acquired sensor data and/or the state of executing a preset function by the target device, so that the human-computer interaction assembly executes a human-computer interaction function according to a human-computer interaction signal, the use flexibility of the internet of things sleeve board in multiple fields and multiple scenes is improved, and the use flexibility of the internet of things device in multiple fields and multiple scenes is improved.

Drawings

Fig. 1 is a schematic block diagram of an internet of things socket provided in an embodiment of the present application;

FIG. 2 is a block diagram of a motherboard according to an embodiment of the present application;

fig. 3 is a schematic block diagram of a main control board according to an embodiment of the present application;

fig. 4 is a schematic block diagram of an internet of things socket according to an embodiment of the present application;

fig. 5 is a schematic block diagram of an internet of things socket according to another embodiment of the present application;

fig. 6 is a schematic block diagram of an internet of things deck according to yet another embodiment of the present application;

fig. 7 is a schematic block diagram of an internet of things device provided in an embodiment of the present application.

Description of reference numerals: 10. an Internet of things device; 11. an Internet of things sleeve board; 12. a main control board; 121. a master control circuit; 122. a USB interface; 123. a USB-to-serial port circuit; 124. a plug-in assembly; 13. a motherboard; 131. a main control board plug end; 132. expanding the splicing end; 14. a first function board; 141. a sensor circuit; 1411. a soil detection circuit; 142. a human-computer interaction component; 1421. an LCD display screen; 143. an equipment access end; 1431. a water pump access end; 144. a soil humidity sensing plate; 145. an LCD display panel; 15. a second function board; 151. a Bluetooth circuit; 16. a third function board; 161. an NFC circuit; 21. a target device.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some, but not all, embodiments of the present application. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application without making any creative effort belong to the protection scope of the present application.

In the description of the present application, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

Some embodiments of the present application will be described in detail below with reference to the accompanying drawings. The embodiments described below and the features of the embodiments can be combined with each other without conflict.

Referring to fig. 1, fig. 1 is a schematic block diagram of an internet of things suite board 11 according to an embodiment of the present disclosure.

As shown in fig. 1, the internet of things deck 11 includes: the motherboard 13, the motherboard 13 is used for connecting with the main control board 12 and at least one first function board 14 detachably; the system comprises one or more first function boards 14, wherein at least one of a sensor circuit 141, a man-machine interaction assembly 142 and an equipment access terminal 143 is arranged on each first function board 14, the sensor circuit 141 is used for collecting sensor data, and the equipment access terminal 143 is used for connecting a target device 21; the main control board 12 is provided with a main control circuit 121, the main control circuit 121 is configured to acquire sensor data from the first function board 14 through the motherboard 13, and send a control instruction to the target device 21 connected to the device access terminal 143 of the first function board 14 according to the acquired sensor data, so that the target device 21 executes a preset function; the main control circuit 121 is further configured to send a human-computer interaction signal to the human-computer interaction component 142 on the first function board 14 through the motherboard 13 according to the acquired sensor data and/or the state of the target device 21 executing the preset function, so that the human-computer interaction component 142 executes the human-computer interaction function according to the human-computer interaction signal.

Optionally, a main control board plug terminal 131 and an extension plug terminal 132 are disposed on the motherboard 13, the main control board plug terminal 131 is electrically connected to the extension plug terminal 132, wherein the main control board plug terminal 131 is used for being plugged into the main control board 12, and the extension plug terminal 132 is used for being plugged into the first function board 14.

Referring to fig. 2, fig. 2 is a schematic block diagram of a motherboard 13 according to an embodiment of the present application.

Illustratively, as shown in fig. 2, the main control board plugging end 131 includes a plurality of plugging slots, wherein the plurality of plugging slots can be used for plugging with the main control board 12.

Illustratively, as shown in FIG. 2, the extended mating end 132 includes a plurality of mating slots and/or a plurality of mating connectors. For example, the first performance board 14 can be plugged with a plurality of slots or a plurality of connectors, and the first performance board 14 can also be plugged with a plurality of slots and/or a plurality of connectors through a flat cable.

Optionally, a power interface is further disposed on the motherboard 13, and the power interface is electrically connected to the main control board plug terminal 131 and the extension plug terminal 132, where the power interface is used to connect a power supply, for example, the power interface may be used to connect a power supply device, and the power supply device supplies power to the internet of things socket board 11 through the power interface.

Optionally, the main control board 12 is further provided with a USB interface 122, a USB to serial port circuit 123, and a plug assembly 124, the main control circuit 121 is electrically connected to the USB interface 122, the USB to serial port circuit 123, and the plug assembly 124, wherein the plug assembly 124 is used for being plugged with the motherboard 13, so as to electrically connect the main control board 12 and the motherboard 13; the USB interface 122 is used for connecting a power supply, and the main control circuit 121 is used for communicating with an upper computer through the USB to serial port circuit 123 to perform serial port burning and/or system debugging.

For example, the USB interface 122 may be used to connect to a power source, and the USB interface 122 may be directly connected to a power source device, or the USB interface 122 may be indirectly connected to the power source through an upper computer.

Illustratively, the upper computer includes at least one of: computer, cell-phone, panel computer.

In some embodiments, when the USB interface 122 of the main control board 12 is connected to a computer through a data line, the main control circuit 121 communicates with the computer through the USB to serial port circuit 123 to perform serial port burning and/or system debugging.

In some embodiments, the main control board 12 is further provided with a WiFi circuit, and the main control circuit 121 is electrically connected to the WiFi circuit, wherein the main control circuit 121 is configured to connect to the internet through the WiFi circuit, so as to realize wireless connection between the internet of things suite board 11 and the internet and access to the internet.

Referring to fig. 3, fig. 3 is a schematic block diagram of the main control board 12 according to an embodiment of the present application.

For example, as shown in fig. 3, the main control board 12 includes a first side and a second side opposite to each other, the first side of the main control board 12 is provided with a main control circuit 121, a USB interface 122 and/or a USB-to-serial port circuit 123, and the second side of the main control board 12 is provided with a plug-in component 124.

In some embodiments, when the plug assembly 124 on the main control board 12 is plugged into the main control board plug terminal 131 of the motherboard 13, the main control circuit 121 on the main control board 12 may control one or more first function boards 14 plugged onto the motherboard 13 to implement corresponding functions.

In some embodiments, the main control board plug terminal 131 includes a first power plug terminal and a first communication plug terminal, wherein when the main control board plug terminal 131 is plugged with the main control board 12, the main control board 12 supplies power to the motherboard 13 through the first power plug terminal, and/or the motherboard 13 supplies power to the main control board 12 through the first power plug terminal; and the main control circuit 121 communicates with the first function board 14 connected to the motherboard 13 through the first communication jack.

Accordingly, the plug assembly 124 includes a second power plug terminal and a second communication plug terminal.

For example, when the main control board plug terminal 131 is plugged with the main control board 12, for example, when a first power plug terminal on the motherboard 13 is plugged with a second power plug terminal on the main control board 12, the main control board 12 may supply power to the motherboard 13, and/or the motherboard 13 may supply power to the main control board 12.

For example, when the main control board plug 131 is plugged with the main control board 12, for example, when the first communication plug on the motherboard 13 is plugged with the second communication plug on the main control board 12, the main control circuit 121 can communicate with the first function board 14 connected to the motherboard 13.

In some embodiments, the power supply mode of the internet of things suite board 11 includes at least one of the following: a power supply is connected through a power supply interface on the motherboard 13, and when the main control board plug-in terminal 131 is plugged with the main control board 12, the motherboard 13 supplies power to the main control board 12 through the first power supply plug-in terminal; or, the power supply is connected through the USB interface 122 on the main control board 12, and when the main control board plug terminal 131 is plugged into the main control board 12, the main control board 12 supplies power to the motherboard 13 through the second power plug terminal.

In some embodiments, the expansion jack 132 includes a third power jack and a third communication jack.

Optionally, the first performance board 14 is provided with a first performance board plug assembly, and the first performance board plug assembly is configured to be plugged with the extension plug terminal 132 on the motherboard 13. In some embodiments, the first function board plug assembly includes a fourth power plug terminal and a fourth communication plug terminal. For example, when the expansion plug 132 is plugged with the first function board 14, the third power plug on the motherboard 13 is plugged with the fourth power plug on the first function board 14, and the third communication plug on the motherboard 13 is plugged with the fourth communication plug on the first function board 14.

In some embodiments, in order to meet the requirements of multiple scenes and multiple fields, at least one of the sensor circuit 141, the human-computer interaction component 142, and the device access terminal 143 disposed on the first function board 14 in the internet of things suite board 11 may be designed and combined accordingly.

Optionally, the first function board 14 includes at least one of: an intelligent agricultural series board, an intelligent travel series board, an intelligent medical series board, an intelligent logistics series board and an intelligent home series board; wherein, wisdom agriculture serials board includes following at least one kind sensor circuit 141: a soil detection circuit 1411, a first temperature and humidity detection circuit; and/or, at least one of the following device access ports 143: a water pump inlet 1431, a fan inlet, a humidifier inlet; the smart row series board includes at least one of the following sensor circuits 141: the device comprises a height detection circuit, a Beidou detection circuit, an ethanol detection circuit and a color detection circuit; and/or at least one of the following human-computer interaction components 142: the first buzzer, the light supplement lamp and the display lamp; and/or, at least one of the following device access ports 143: a ceramic antenna access end; the smart medical serials board includes at least one of the following sensor circuits 141: the device comprises a blood oxygen heart rate detection circuit, an infrared temperature measurement circuit, an infrared receiving circuit, an odor detection circuit and a carbon dioxide detection circuit; and/or at least one of the following human-computer interaction components 142: a second buzzer; the smart logistics panel includes at least one of the following sensor circuits 141: the GPS detection circuit and the second temperature and humidity detection circuit; the smart home array board includes at least one of the following sensor circuits 141: the device comprises a thermal infrared human body detection circuit, a brightness detection circuit, a third temperature and humidity detection circuit and a combustible gas detection circuit; and/or at least one of the following human-computer interaction components 142: lamp, third buzzer.

In some embodiments, one of the smart agriculture series board, the smart trip series board, the smart medical series board, the smart logistics series board, and the smart home series board may be used alternatively, or at least two of the smart agriculture series board, the smart trip series board, the smart medical series board, the smart logistics series board, and the smart home series board may be used in combination.

Optionally, the sensor circuit 141 of the smart agriculture train board further comprises an image acquisition circuit.

For example, when the main control board 12 is connected with the smart agriculture series board through the motherboard 13, the internet of things socket board 11 can be applied to the field of agriculture and/or the field of livestock breeding.

In some embodiments, when the main control board 12 is connected to the smart agriculture line board through the motherboard 13, the internet of things suite board 11 may be used to monitor and/or determine at least one of: the growth condition of plants, the growth condition of crops, the health condition of livestock and poultry products, the feeding condition of the livestock and poultry products and the position information of the livestock and poultry products, and further the accurate management of functions such as visual diagnosis and remote control of agriculture is realized.

For example, the smart agriculture series panel may include at least one of: the soil humidity sensing plate 144 and the first temperature and humidity sensing plate are used for monitoring and managing plants or crops in a preset environment range, for example, monitoring and managing plants or crops in a greenhouse. In some embodiments, at least one of the smart agriculture series boards may be used in the alternative or in combination.

Alternatively, the first function board 14 that provides the sensor data to the master control circuit 121 may be the same first function board 14 as the first function board 14 of the connection target device 21.

Illustratively, sensor circuit 141 of soil moisture sensing board 144 includes soil detection circuit 1411, and device access 143 of soil moisture sensing board 144 includes water pump access 1431, wherein soil detection circuit 1411 is used for gathering soil moisture data, and water pump access 1431 is used for connecting the water pump. In some embodiments, soil detection circuitry 1411 may be provided on the soil detection probe board. For example, the soil detection probe plate is inserted into the soil to be detected to contact with the soil, the main control circuit 121 obtains soil humidity data from the soil humidity sensing plate 144 through the motherboard 13, and sends a control instruction to the water pump connected to the water pump inlet 1431 of the soil humidity sensing plate 144 according to the obtained soil humidity data, so that the water pump executes a preset function. For example, the main control circuit 121 sends a watering starting instruction to the water pump connected to the water pump connection end 1431 of the soil humidity sensing board 144 according to that the obtained soil humidity data is less than or equal to the preset soil humidity threshold value, so that the water pump starts watering; the main control circuit 121 sends a watering stopping instruction to the water pump connected to the water pump connection end 1431 of the soil humidity sensing board 144 according to the acquired soil humidity data being greater than the preset soil humidity threshold value, so that the water pump stops watering.

Illustratively, the sensor circuit 141 of the first temperature and humidity sensing board includes a first temperature and humidity detection circuit, and the device access terminal 143 of the first temperature and humidity sensing board includes a fan access terminal, wherein the first temperature and humidity detection circuit is configured to collect temperature data and humidity data within a preset range, and the fan access terminal is configured to connect to a fan. For example, the main control circuit 121 obtains temperature data within a preset range from the first temperature and humidity sensing board through the motherboard 13, and sends a control instruction to the fan connected to the fan access end of the first temperature and humidity sensing board according to the obtained temperature data within the preset range, so that the fan executes a preset function. For example, the main control circuit 121 sends a blowing starting instruction to a fan connected to the fan access end of the first temperature and humidity sensing board according to that the acquired temperature data in the preset range is greater than or equal to a preset temperature threshold value, so that the fan starts blowing; the main control circuit 121 sends a blowing stop instruction to the fan connected to the fan access end of the first temperature and humidity sensing board according to the fact that the acquired temperature data in the preset range is smaller than the preset temperature threshold value, so that the fan stops blowing.

Alternatively, the first function board 14 that supplies the sensor data to the main control circuit 121 may be a different plurality of first function boards 14 from the first function board 14 of the connection target device 21.

Illustratively, wisdom agricultural series board still includes the humidifier access board, and the equipment access 143 of humidifier access board includes the humidifier access, and wherein, the humidifier access is used for connecting the humidifier.

For example, when the main control board 12 is connected to the first temperature and humidity sensing board through the motherboard 13, and the main control board 12 is connected to the humidifier access board through the motherboard 13, the main control circuit 121 acquires humidity data within a preset range from the first temperature and humidity detection circuit of the first temperature and humidity sensing board through the motherboard 13, and sends a control instruction to the humidifier connected to the humidifier access end of the humidifier access board according to the acquired humidity data within the preset range, so that the humidifier performs a preset function. For example, the main control circuit 121 sends a humidification starting instruction to a humidifier connected to a humidifier access end of the humidifier access board according to the acquired humidity data being less than or equal to the preset humidity threshold value, so as to start humidification of the humidifier; the main control circuit 121 sends a humidification stopping instruction to the humidifier connected to the humidifier access end of the humidifier access board according to the acquired humidity data greater than the preset humidity threshold value, so that the humidifier stops humidifying.

Illustratively, when the main control board 12 is connected with the intelligent travel series board through the motherboard 13, the internet of things suite board 11 can be applied to the pedestrian travel field and/or the vehicle travel field.

In some embodiments, when the main control board 12 is connected to the smart travel board through the motherboard 13, the internet of things suite board 11 may be configured to monitor at least one of the following: the system comprises an environment state, a pedestrian behavior state and a vehicle behavior state, and further provides visual management for ensuring the traveling safety of people and vehicles.

For example, the smart travel series board may include at least one of: height and big dipper location tablet, alcohol tablet, colour show board. In some embodiments, at least one of the smart row series boards may be used in alternative or in combination.

Illustratively, the sensor circuit 141 of the height and beidou positioning induction plate includes at least one of a height detection circuit and a beidou detection circuit, and the device access end 143 of the height and beidou positioning induction plate includes a ceramic antenna access end, wherein the height detection circuit is used for collecting height data, the beidou detection circuit is used for collecting longitude and latitude data, and the ceramic antenna access end is used for connecting a ceramic antenna to provide position support for traveling of pedestrians and/or vehicles.

Alternatively, the first function board 14 for providing the sensor data to the main control circuit 121 and the first function board 14 for performing the human-computer interaction function may be the same first function board 14.

Illustratively, the sensor circuit 141 of the alcohol-ethanol sensing board comprises an ethanol detection circuit, and the human-computer interaction component 142 of the alcohol-ethanol sensing board comprises a first buzzer, wherein the ethanol detection circuit is used for collecting ethanol concentration data. For example, a vehicle driver breathes out gas to the internet of things sleeve plate 11, an ethanol detection circuit on the alcohol ethanol sensing plate acquires ethanol concentration data corresponding to the gas breathed out by the vehicle driver, the main control circuit 121 acquires the ethanol concentration data from the ethanol detection circuit of the alcohol ethanol sensing plate through the motherboard 13, and sends a human-computer interaction signal to a first buzzer of the alcohol ethanol sensing plate according to the acquired ethanol concentration data so that the first buzzer executes a human-computer interaction function. For example, the main control circuit 121 sends an alarm signal to a first buzzer of the alcohol-ethanol sensing board according to that the acquired ethanol concentration data is greater than or equal to a preset ethanol concentration threshold value, so that the first buzzer executes an alarm function.

Illustratively, the sensor circuit 141 of the color sensor board includes a color detection circuit, and the human-computer interaction component 142 of the color sensor board includes a light supplement lamp, wherein the color detection circuit is configured to collect color data within a preset range. For example, the main control circuit 121 obtains color data within a preset range from the color detection circuit of the color sensor board through the motherboard 13, and sends a human-computer interaction signal to the light supplement lamp of the color sensor board according to the obtained color data, so that the light supplement lamp executes a human-computer interaction function. In general, the main control circuit 121 may determine the light color and/or the object color within the preset range according to the acquired color data within the preset environment range, and if the main control circuit 121 cannot determine the light color and/or the object color within the preset environment range according to the acquired color data within the preset environment range, the main control circuit 121 sends a light supplement signal to the light supplement lamp of the color sensor board to enable the light supplement lamp to perform a light supplement function.

Illustratively, the human-computer interaction component 142 of the color display board includes a display light and another first buzzer. For example, one or more display lamps may be disposed on the color display board. For example, when one display lamp is arranged on the color display board, the display lamp may include red, green and blue beads, so that the main control circuit 121 may adjust the proportion of the red, green and blue beads according to the acquired color data, so that the display lamp on the color display board displays the corresponding color; when being provided with a plurality of show lights on the colour show board, the show light can include the lamp of red light, yellow light, green light or other colours to master control circuit 121 can send the signal of lighting up so that the lamp of corresponding colour on the colour show board lights up to the lamp of corresponding colour on the colour show board according to the colour data of acquireing.

Alternatively, the first function board 14 that provides the sensor data to the main control circuit 121 may be a different plurality of first function boards 14 from the first function board 14 that performs the human-computer interaction function.

For example, when mother board 13 is connected with main control board 12, colour tablet, colour show board simultaneously, the colour tablet can be used for acquireing the traffic light colour of predetermineeing the within range, and the colour show board can be used for showing the traffic light colour, and the colour show board can also be used for promoting when the traffic light colour changes. For example, the main control circuit 121 sends a display signal to the display lamp on the color display board according to the color of the traffic light obtained by the color detection circuit on the color sensing board, so that the display lamp on the color display board displays the color of the traffic light; when the color of the traffic light acquired by the main control circuit 121 according to the color detection circuit on the color sensing board changes, a prompt signal is sent to the first buzzer on the color display board, so that the first buzzer on the color display board prompts according to the prompt signal.

For example, when the main control board 12 is connected with the smart medical series board through the motherboard 13, the internet of things suite board 11 may be applied to the medical field.

In some embodiments, when the main control board 12 is connected to the smart medical serials board through the motherboard 13, the internet of things suite board 11 may be used to monitor and/or manage at least one of: the physiological state of a person, medical equipment, medical articles and the hospital environment, and further realize the visual management of the person, the medical equipment, the medical articles and the hospital environment.

For example, the smart medical panel may include at least one of: a blood oxygen heart rate sensing plate, an infrared temperature measurement sensing plate, a flame sensing plate and an air quality detection plate. In some embodiments, at least one of the smart medical series boards may be used in the alternative or in combination.

Illustratively, the sensor circuit 141 of the blood oxygen heart rate sensing board includes a blood oxygen heart rate detection circuit for collecting blood oxygen content data and heart rate data of the user. For example, a blood oxygen heart rate sensing pad may be worn on the wrist of a user to collect blood oxygen content data and heart rate data of the user.

Illustratively, the sensor circuit 141 of the infrared temperature measurement sensing board comprises an infrared temperature measurement circuit, and the human-computer interaction component 142 of the infrared temperature measurement sensing board comprises a second buzzer, wherein the infrared temperature measurement circuit is used for collecting body temperature data of a user. For example, the infrared temperature measurement sensing board may be configured to collect body temperature data of the forehead and other parts of the user, the main control circuit 121 obtains the body temperature data of the user from the infrared temperature measurement circuit of the infrared temperature measurement sensing board through the motherboard 13, and sends a human-computer interaction signal to the second buzzer according to the obtained body temperature data of the user, so that the second buzzer executes a human-computer interaction function. For example, when the main control circuit 121 determines that the body temperature data collection of the user is finished, the main control circuit 121 sends a prompt signal to the second buzzer to prompt that the body temperature collection of the user is finished.

Illustratively, the sensor circuit 141 of the flame sensing board comprises an infrared receiving circuit, and the human-computer interaction component 142 of the flame sensing board comprises another second buzzer, wherein the infrared receiving circuit is used for collecting open fire data and open fire distance data. For example, the main control circuit 121 obtains the open fire data and the open fire distance data from the infrared receiving circuit of the flame sensing board through the motherboard 13, and sends the human-computer interaction signal to the second buzzer on the flame sensing board according to the obtained open fire data and the open fire distance data, so that the second buzzer executes the human-computer interaction function. For example, the main control circuit 121 sends an alarm signal to the second buzzer on the flame sensing plate according to the acquired open fire data and the acquired open fire distance data is less than or equal to the preset open fire distance threshold value so as to enable the second buzzer to execute an alarm function.

Illustratively, the sensor circuit 141 of the air quality detection panel includes at least one of an odor detection circuit for collecting odor data and a carbon dioxide detection circuit for collecting carbon dioxide concentration data. In some embodiments, the odor detection circuit may include a TVOC value detection circuit, which may be configured to collect a TVOC value in the air.

For example, when the main control board 12 is connected with the intelligent logistics series board through the motherboard 13, the internet of things suite board 11 can be applied to the field of logistics transportation.

In some embodiments, when the main control board 12 is connected to the intelligent logistics series board through the motherboard 13, the internet of things suite board 11 may be configured to monitor at least one of the following: the position of goods, goods humiture, haulage vehicle position, haulage vehicle state, haulage vehicle oil consumption, haulage vehicle speed for goods and haulage vehicle in the commodity circulation transportation provide visual management, promote the intelligent level of whole commodity circulation trade.

For example, the smart logistics panel may include a cargo sensing panel.

Illustratively, the sensor circuit 141 of the cargo sensing board includes at least one of a GPS detection circuit and a second temperature and humidity detection circuit, wherein the GPS detection circuit is used to collect position data of the cargo, and the second temperature and humidity detection circuit is used to collect temperature data and humidity data of the cargo within a range.

Illustratively, when the main control board 12 is connected with the smart home series board through the motherboard 13, the internet of things sheathing board 11 may be applied to the home field.

In some embodiments, when the main control board 12 is connected to the smart home series board through the motherboard 13, the internet of things suite board 11 may be configured to monitor at least one of: the position of the household product, the state of the household product and the change of the household product. In some embodiments, the main control circuit 121 may also be configured to perform analysis feedback according to the position of the home product, the state of the home product, and the change of the home product, so as to bring a safe and comfortable home experience to the user.

For example, the smart home array panel may include at least one of: a human body induction plate and a combustible gas induction plate. In some embodiments, at least one of the smart home series boards may be used alternatively or in combination.

Illustratively, the sensor circuit 141 of the human body sensing panel includes at least one of a thermal infrared human body detection circuit for collecting thermal infrared data and thus human body data, and a light brightness detection circuit for collecting light brightness data.

Illustratively, the sensor circuit 141 of the combustible gas sensor board includes at least one of a third temperature and humidity detection circuit and a combustible gas detection circuit, and the human-computer interaction component 142 of the combustible gas sensor board includes a third buzzer, wherein the third temperature and humidity detection circuit is configured to collect temperature data and humidity data within a preset environment range, and the combustible gas detection circuit is configured to collect smoke concentration data within the preset environment range. In some embodiments, the main control circuit 121 sends an alarm instruction to the third buzzer of the combustible gas sensing board to alarm the third buzzer according to that the acquired smoke concentration data in the preset environment range is greater than or equal to the preset smoke concentration threshold.

Optionally, the first function board 14 includes an LCD display panel 145, and the human-computer interaction component 142 of the LCD display panel 145 includes an LCD display screen 1421. For example, when the main control board 12 is connected to the LCD panel 145 through the motherboard 13, the main control circuit 121 sends a display signal to the LCD display 1421 on the LCD panel 145 through the motherboard 13 according to the acquired sensor data and/or the state of the target device 21 executing the preset function, so that the LCD display 1421 executes the display function according to the display signal.

Illustratively, at least one of a smart agriculture series board, a smart trip series board, a smart medical series board, a smart logistics series board, and a smart home series board may be used in combination with the LCD display panel 145.

Alternatively, the motherboard 13 may be connected with the main control board 12 and the plurality of first function boards 14. In some embodiments, the sensor circuit 141 and the human interaction component 142, the device access 143 may be located on different first performance boards 14.

Referring to fig. 4, fig. 4 is a schematic block diagram of an internet of things suite board 11 according to an embodiment of the present disclosure.

As shown in fig. 4, when the main control board 12 is connected to the LCD display board 145 through the motherboard 13, and the main control board 12 is connected to the soil humidity sensing board 144 through the motherboard 13, the main control circuit 121 may send a control instruction to the water pump connected to the water pump connection terminal 1431 on the soil humidity sensing board 144 according to the soil humidity data acquired by the soil humidity sensing board 144, so as to enable the water pump to perform a preset function, and the main control circuit 121 may also send a display signal to the LCD display screen 1421 on the LCD display board 145 through the motherboard 13 according to the soil humidity data acquired by the soil humidity sensing board 144 and the state of the water pump connected to the water pump connection terminal 1431 on the soil humidity sensing board 144 to enable the LCD display screen 1421 to perform a display function according to the display signal.

It is understood that when the LCD display panel 145 is used in combination with at least one of a smart agriculture series panel, a smart trip series panel, a smart medical series panel, a smart logistics series panel, and a smart home series panel, the LCD display panel 145 may be used to display corresponding sensor data and/or a state where the corresponding target device 21 performs a preset function.

Referring to fig. 5, fig. 5 is a schematic block diagram of an internet of things sleeve board 11 according to another embodiment of the present application.

Optionally, as shown in fig. 5, the internet of things sleeve board 11 further includes a second function board 15, where the second function board 15 is used for being detachably connected with the motherboard 13; the second function board 15 is provided with a bluetooth circuit 151, and the main control circuit 121 is further configured to control the bluetooth circuit 151 on the second function board 15 to perform bluetooth communication with the terminal device through the motherboard 13.

For example, the extension plug terminals 132 on the motherboard 13 can also be used for plugging with the second function board 15. For example, the second function board 15 is provided with a second function board plug assembly, and the second function board 15 is plugged with the extension plug terminal 132 on the motherboard 13 through the second function board plug assembly. In some embodiments, the second function board plug assembly includes a fifth power plug terminal and a fifth communication plug terminal. For example, when the expansion plug 132 is plugged with the second function board 15, the third power plug on the motherboard 13 is plugged with the fifth power plug on the second function board 15, and the third communication plug on the motherboard 13 is plugged with the fifth communication plug on the second function board 15.

In some embodiments, when the main control board 12 is connected to the second function board 15 through the motherboard 13, the main control circuit 121 is further configured to control the bluetooth circuit 151 on the second function board 15 through the motherboard 13 to perform bluetooth communication with the terminal device, for example, transmit the sensor data acquired by the main control circuit 121 and/or the state of the target device 21 executing the preset function to the terminal device, so that a user may enter a corresponding APP in the terminal device to view the sensor data and/or the state of the target device 21 executing the preset function.

Referring to fig. 6, fig. 6 is a schematic block diagram of an internet of things socket 11 according to still another embodiment of the present application.

Optionally, as shown in fig. 6, the internet of things socket board 11 further includes a third function board 16, where the third function board 16 is used for being detachably connected with the motherboard 13; the third function board 16 is provided with an NFC circuit 161, and the main control circuit 121 is further configured to control the NFC circuit 161 on the third function board 16 to perform NFC communication with a terminal device through the motherboard 13.

Illustratively, the extension plug terminals 132 on the motherboard 13 may also be used for plugging with the third function board 16. For example, the third function board 16 is provided with a third function board plugging component, the third function board 16 is plugged with the extension plugging terminal 132 on the motherboard 13 through the third function board plugging component, and the third function board 16 can also be plugged with the extension plugging terminal 132 on the motherboard 13 through a flat cable. In some embodiments, the third function board patch assembly includes a sixth power patch terminal and a sixth communication patch terminal. For example, when the expansion plug 132 is plugged with the third function board 16, the third power plug on the motherboard 13 is plugged with the sixth power plug on the third function board 16, and the third communication plug on the motherboard 13 is plugged with the sixth communication plug on the third function board 16.

In some embodiments, when the main control board 12 is connected to the third function board 16 through the motherboard 13, the main control circuit 121 is further configured to control the NFC circuit 161 on the third function board 16 to perform NFC communication with the terminal device through the motherboard 13, for example, to call a WeChat in the terminal device or an APP corresponding to the Internet of things suite board 11.

The thing networking lagging 11 that this application embodiment provided includes: the motherboard 13, the motherboard 13 is used for connecting with the main control board 12 and at least one first function board 14 detachably; the system comprises one or more first function boards 14, wherein at least one of a sensor circuit 141, a man-machine interaction assembly 142 and an equipment access terminal 143 is arranged on each first function board 14, the sensor circuit 141 is used for collecting sensor data, and the equipment access terminal 143 is used for connecting a target device 21; the main control circuit 121 is arranged on the main control board 12, and the main control circuit 121 is configured to acquire sensor data from the first function board 14 through the motherboard 13, and send a control instruction to the target device 21 connected to the device access terminal 143 of the first function board 14 according to the acquired sensor data, so that the target device 21 executes a preset function; the main control circuit 121 is further configured to send a human-computer interaction signal to the human-computer interaction component 142 on the first function board 14 through the motherboard 13 according to the acquired sensor data and/or the state of executing a preset function by the target device 21, so that the human-computer interaction component 142 executes a human-computer interaction function according to the human-computer interaction signal, and thus the flexibility of the use of the internet of things suite board 11 in multiple fields and multiple scenes is improved.

Referring to fig. 7, fig. 7 is a schematic block diagram of an internet of things device 10 according to an embodiment of the present disclosure.

As shown in fig. 7, the internet of things device 10 includes: the internet of things sleeve board 11; the target device 21, the target device 21 is connected with the device access terminal 143 on the first function board 14 of the internet of things suite board 11.

Illustratively, the target device 21 may include at least one of: water pump, fan, humidifier, ceramic antenna.

In some embodiments, the main control circuit 121 on the main control board 12 of the internet of things suite board 11 sends a control instruction to the target device 21 connected to the device access terminal 143 of the first function board 14 according to the acquired sensor data, so that the target device 21 executes a preset function. For example, the main control circuit 121 sends a watering start instruction to the water pump connected to the water pump connection end 1431 on the first function board 14 according to the acquired soil humidity data being less than or equal to the preset soil humidity threshold value, so that the water pump starts watering. For another example, the main control circuit 121 sends a blowing starting instruction to the fan connected to the fan access terminal on the first function board 14 according to that the acquired temperature data in the preset environment range is greater than or equal to the preset temperature threshold value, so as to start blowing by the fan.

The specific principle and implementation manner of the internet of things device 10 provided by the embodiment of the present application are similar to those of the internet of things sleeve board 11 of the foregoing embodiment, and are not described herein again.

It is to be understood that the terminology used in the description of the present application herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in the specification of the present application and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should also be understood that the term "and/or" as used in this specification and the appended claims refers to and includes any and all possible combinations of one or more of the associated listed items.

Claims (14)

1. The utility model provides a thing networking lagging which characterized in that, thing networking lagging includes:

the motherboard is detachably connected with the main control board and the at least one first function board;

the system comprises one or more first function boards, wherein at least one of a sensor circuit, a man-machine interaction assembly and an equipment access end is arranged on each first function board, the sensor circuit is used for collecting sensor data, and the equipment access end is used for connecting target equipment;

the main control circuit is used for acquiring sensor data from the first function board through the motherboard and sending a control instruction to target equipment connected with the equipment access end of the first function board according to the acquired sensor data so as to enable the target equipment to execute a preset function; the main control circuit is further used for sending a human-computer interaction signal to the human-computer interaction assembly on the first function board through the motherboard according to the acquired sensor data and/or the state of the target device executing the preset function, so that the human-computer interaction assembly executes the human-computer interaction function according to the human-computer interaction signal.

2. The internet of things sleeve board of claim 1, wherein a main control board plug end and an extension plug end are arranged on the motherboard, the main control board plug end is electrically connected with the extension plug end, the main control board plug end is used for being plugged with the main control board, and the extension plug end is used for being plugged with the first function board.

3. The internet of things nest plate of claim 2, wherein the main control board plug end includes a first power plug end and a first communication plug end;

when the main control board plug end is plugged with the main control board, the main control board supplies power to the motherboard through the first power supply plug end, and/or the motherboard supplies power to the main control board through the first power supply plug end; and the number of the first and second groups,

the main control circuit is communicated with a first function board connected with the motherboard through the first communication plug terminal.

4. The internet of things sleeve board of claim 2, wherein a power interface is further arranged on the motherboard, the power interface is electrically connected with the main control board plug-in terminal and the expansion plug-in terminal, and the power interface is used for connecting a power supply.

5. The internet of things sleeve board according to claim 1, wherein a USB interface, a USB-to-serial port circuit and a plug-in component are further arranged on the main control board, the main control circuit is electrically connected with the USB interface, the USB-to-serial port circuit and the plug-in component, the plug-in component is used for being plugged with the motherboard, the USB interface is used for being connected with a power supply, and the main control circuit is used for communicating with an upper computer through the USB-to-serial port circuit so as to perform serial port burning and/or system debugging.

6. The internet of things nest plate of any one of claims 1-5, wherein the first function plate comprises a smart agriculture series plate;

wherein, wisdom agriculture train board includes following at least one kind sensor circuit: a soil detection circuit and a first temperature and humidity detection circuit; and/or, at least one of: water pump incoming end, fan incoming end, humidifier incoming end.

7. The internet of things nest board of any one of claims 1-5, wherein the first function board comprises a smart travel series board;

wherein, wisdom trip series board includes following at least one kind of sensor circuit: the device comprises a height detection circuit, a Beidou detection circuit, an ethanol detection circuit and a color detection circuit; and/or at least one of the following human-computer interaction components: the first buzzer, the light supplement lamp and the display lamp; and/or, at least one of: ceramic antenna access end.

8. The internet of things nest board of any one of claims 1-5, wherein the first function board comprises a smart medical series board;

wherein, wisdom medical treatment serials board includes following at least one kind sensor circuit: the device comprises a blood oxygen heart rate detection circuit, an infrared temperature measurement circuit, an infrared receiving circuit, an odor detection circuit and a carbon dioxide detection circuit; and/or at least one of the following human-computer interaction components: and a second buzzer.

9. The internet of things nest board of any one of claims 1-5, wherein the first function board comprises a smart logistics series board;

wherein, wisdom commodity circulation serials board includes following at least one kind sensor circuit: GPS detection circuitry, second temperature and humidity detection circuitry.

10. The Internet of things nest plate of any one of claims 1-5, wherein the first function plate comprises a smart home series plate;

wherein, intelligence house serials board includes following at least one kind sensor circuit: the device comprises a thermal infrared human body detection circuit, a light brightness detection circuit, a third temperature and humidity detection circuit and a combustible gas detection circuit; and/or at least one of the following human-computer interaction components: and a third buzzer.

11. The Internet of things suite board of any one of claims 1 to 5, wherein the first function board comprises an LCD display panel, and the human-computer interaction component of the LCD display panel comprises an LCD display screen.

12. The Internet of things sleeve board of any one of claims 1 to 5, further comprising a second function board, wherein the second function board is detachably connected with the motherboard;

the second function board is provided with a Bluetooth circuit, and the master control circuit is also used for controlling the Bluetooth circuit on the second function board to perform Bluetooth communication with the terminal equipment through the motherboard.

13. The Internet of things sleeve board according to any one of claims 1 to 5, further comprising a third function board, wherein the third function board is detachably connected with the mother board;

the third function board is provided with an NFC circuit, and the master control circuit is further used for controlling the NFC circuit on the third function board to carry out NFC communication with the terminal equipment through the motherboard.

14. An internet of things device, comprising:

the internet of things nest plate of any one of claims 1-13; and

and the target equipment is connected with the equipment access end on the first function board of the Internet of things sleeve board.

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