CN219019039U - Terminal management device - Google Patents

Abstract

The utility model discloses a terminal management device which is applied to a wireless sensor network of a plurality of sensor nodes and is in communication connection with different sensor nodes. The terminal management equipment comprises a signal transmission module and an intelligent interaction module; the signal transmission module is in communication connection with the sensor node and a server of the external equipment; the intelligent interaction module is in communication connection with the signal transmission module. According to the technical scheme, the signal transmission module is adopted, and the environment condition of the monitoring area can be conveniently known in real time by a user in a wireless transmission mode. On the basis of the scheme, the intelligent interaction module is further arranged for user interaction to rapidly deploy the sensor nodes, so that the deployment efficiency of the Internet of things is improved.

Description

Terminal management device

Technical Field

The utility model relates to the technical field of gateway equipment, in particular to terminal management equipment.

Background

With the development and mutual integration of technologies such as sensors, communication and computers, wireless sensor networks are generated. The wireless sensor network is a full-distribution system without a central node, and tens of sensor nodes, even hundreds of sensor nodes, are densely deployed in a monitoring area in a random throwing mode.

Further, in the process of setting up the deployment internet of things, after the wireless sensor network is to be formed, workers need to perform node adding operation on a server of external equipment, so that data of the sensor nodes are identified and displayed by the server. When the node needs to be transferred to another area, a worker needs to perform an operation of deleting the node at the server and update the position information of the node. Thus, the data on the server can be correctly in one-to-one correspondence with the real environment.

However, the existing ways of setting up and deploying the internet of things mainly include two ways: firstly, the serial numbers and the position information of the sensor nodes are manually recorded on a notebook computer, and are input on a computer room or a computer of an operation room one by one after deployment is finished, so that the deployment efficiency is often low; secondly, the mobile phone APP is used for installing the sensor node and recording, but the situation that no mobile phone signal exists or the mobile phone is strictly limited to be carried can exist on site.

Disclosure of Invention

The utility model mainly aims to provide terminal management equipment, which aims to improve the deployment efficiency of the Internet of things.

In order to achieve the above object, the present utility model provides a terminal management device, which is used in a wireless sensor network including a plurality of sensor nodes, and is in communication connection with different sensor nodes, the terminal management device includes:

the signal transmission module is in communication connection with the sensor node and a server of external equipment, and is used for receiving an environment monitoring signal acquired by the sensor node and sending the environment monitoring signal to the server;

the intelligent interaction module is in communication connection with the signal transmission module, and is used for providing user interaction to generate node signals corresponding to the sensor nodes and outputting the node signals to the signal transmission module.

Preferably, the signal transmission module further comprises:

the transmission gateway comprises a gateway shell and a gateway controller, and the gateway controller is arranged on the gateway shell;

the receiving antenna is arranged on the gateway shell, is in communication connection with the sensor node and is electrically connected with the gateway controller, and is used for receiving the environment monitoring signals collected by the sensor node and outputting the environment monitoring signals to the gateway controller;

the transmission antenna is arranged on the gateway shell, is electrically connected with the gateway controller and is in communication connection with the server, and is used for receiving the environment monitoring signals sent by the gateway controller and outputting the environment monitoring signals to the server.

Preferably, the signal transmission module further comprises:

the Ethernet interface is arranged on the gateway shell and is electrically connected with the gateway controller, and the Ethernet is used for connecting the server.

Preferably, the intelligent interaction module further comprises:

an operation screen including a screen housing, a screen controller, a touch display screen, and a transmitting antenna; wherein, the liquid crystal display device comprises a liquid crystal display device,

the screen controller is arranged on the screen shell;

the touch display screen is arranged on the screen shell, is electrically connected with the screen controller, and is used for providing user interaction to generate node signals corresponding to the sensor nodes and outputting the node signals to the screen controller;

the transmitting antenna is arranged on the screen shell, is electrically connected with the screen controller and is in communication connection with the receiving antenna, and is used for receiving the node signals sent by the screen controller and outputting the node signals to the receiving antenna.

Preferably, the intelligent interaction module further comprises:

the scanning piece is arranged on the other side of the screen shell relative to the touch display screen, is electrically connected with the screen controller and is used for scanning the two-dimensional code on the sensor node so as to acquire the information of the sensor node.

Preferably, the terminal management device further includes:

the first installation part is arranged on the gateway shell and is electrically connected with the gateway controller;

the second installation part is arranged on the other side of the screen shell relative to the touch display screen and is electrically connected with the screen controller;

the first mounting part is assembled and matched with the second mounting part so as to trigger the transmission gateway to be electrically connected with the operation screen.

Preferably, the first installation part comprises a first contact seat, the first contact seat is arranged on the gateway shell, the first contact seat is electrically connected with the gateway controller, and a positioning hole is formed in the gateway shell;

the second installation part comprises a second contact seat and a positioning piece, the second contact seat and the positioning piece are both arranged on the other side of the screen shell relative to the touch display screen, and the second contact seat is electrically connected with the screen controller;

the positioning hole is matched with the positioning piece in an assembling way so as to drive the first contact seat to be contacted with the second contact seat.

Preferably, the first mounting part further comprises a first magnet, and the first magnet is arranged on the gateway housing;

the second installation part further comprises a second magnet, and the second magnet is arranged on the screen shell;

the first magnet and the second magnet are attracted to each other to maintain a contact state between the first contact seat and the second contact seat.

Preferably, the intelligent interaction module further comprises:

the USB interface is arranged on the screen shell and is electrically connected with the screen controller, and the USB interface is used for externally connecting movable equipment.

Preferably, the intelligent interaction module further comprises:

the HDMI output interface is arranged on the screen shell and is electrically connected with the screen controller, and the HDMI output interface is used for being connected with electronic equipment with an HDMI input interface.

The utility model provides a terminal management device which is applied to a wireless sensor network of a plurality of sensor nodes and is in communication connection with different sensor nodes. The terminal management equipment comprises a signal transmission module and an intelligent interaction module; the signal transmission module is in communication connection with the sensor node and a server of the external equipment; the intelligent interaction module is in communication connection with the signal transmission module. According to the technical scheme, the signal transmission module is adopted, and the environment condition of the monitoring area can be conveniently known in real time by a user in a wireless transmission mode. On the basis of the scheme, the intelligent interaction module is further arranged for user interaction to rapidly deploy the sensor nodes, so that the deployment efficiency of the Internet of things is improved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a signal transmission module in a terminal management device according to the present utility model;

fig. 2 is a schematic diagram of a front structure of a smart interactive module in the terminal management device of the present utility model;

FIG. 3 is a schematic diagram of the back structure of the intelligent interaction module in the terminal management device of the present utility model;

FIG. 4 is a schematic side view of a smart interactive module in the terminal management device of the present utility model;

fig. 5 is a schematic structural diagram of the terminal management device of the present utility model in an unassembled state of the signal transmission module and the intelligent interaction module;

fig. 6 is a schematic structural diagram of the signal transmission module and the intelligent interaction module in the terminal management device in the assembled state.

Reference numerals illustrate:

reference numerals	Name of the name	Reference numerals	Name of the name
				10	Signal transmission module	11	Transmission gateway
111	Gateway shell	12	Receiving antenna
				13	Transmission antenna	14	Ethernet interface
15	A first mounting part	151	First contact base
				152	Positioning hole	20	Intelligent interaction module
21	Operation screen	211	Screen shell
				212	Touch display screen	213	Transmitting antenna
22	Scanning piece	23	A second mounting part
				231	Second contact base	232	Positioning piece
24	USB interface	25	HDMI output interface

The achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that, if a directional indication (such as up, down, left, right, front, and rear … …) is involved in the embodiment of the present utility model, the directional indication is merely used to explain the relative positional relationship, movement condition, etc. between the components in a specific posture, and if the specific posture is changed, the directional indication is correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present utility model, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, if "and/or" and/or "are used throughout, the meaning includes three parallel schemes, for example," a and/or B "including a scheme, or B scheme, or a scheme where a and B are satisfied simultaneously. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

It is appreciated that wireless sensor networks have evolved with the development and convergence of sensor, communication, and computer technologies. The wireless sensor network is a full-distribution system without a central node, and tens of sensor nodes, even hundreds of sensor nodes, are densely deployed in a monitoring area in a random throwing mode.

Further, in the process of setting up the deployment internet of things, after the wireless sensor network is to be formed, workers need to perform node adding operation on a server of external equipment, so that data of the sensor nodes are identified and displayed by the server. When the node needs to be transferred to another area, a worker needs to perform an operation of deleting the node at the server and update the position information of the node. Thus, the data on the server can be correctly in one-to-one correspondence with the real environment.

However, the existing ways of setting up and deploying the internet of things mainly include two ways: firstly, the serial numbers and the position information of the sensor nodes are manually recorded on a notebook computer, and are input on a computer room or a computer of an operation room one by one after deployment is finished, so that the deployment efficiency is often low; secondly, the mobile phone APP is used for installing the sensor node and recording, but the situation that no mobile phone signal exists or the mobile phone is strictly limited to be carried can exist on site.

Therefore, the utility model provides terminal management equipment, which aims to improve the deployment efficiency of the Internet of things.

Referring to fig. 1 to 6, in an embodiment, the terminal management device is used in a wireless sensor network including a plurality of sensor nodes, and communication connection is performed between different sensor nodes, the terminal management device includes:

the signal transmission module 10 is in communication connection with the sensor node and a server of external equipment, and the signal transmission module 10 is used for receiving an environment monitoring signal acquired by the sensor node and sending the environment monitoring signal to the server;

the intelligent interaction module 20 is in communication connection with the signal transmission module 10, and the intelligent interaction module 20 is used for providing user interaction to generate node signals corresponding to the sensor nodes and outputting the node signals to the signal transmission module 10.

The sensor node is integrated with an environment monitoring module, a data processing module, a node communication module and an energy supply module, which are connected through a wireless channel to form a network system in an self-organization manner. Specifically, the environment monitoring module comprises a plurality of sensors, a data processing module and a control module, wherein the sensors are used for acquiring environment monitoring signals such as temperature, humidity, pressure, sound and the like in a monitoring area and outputting the signals to the data processing module; the data processing module is used for processing the environment monitoring signals acquired by the sensor node into related data and storing the related data together with data transmitted by other nodes; the node communication module is responsible for carrying out wireless communication with other sensor nodes, exchanging control information, receiving and transmitting acquired data; the energy supply module provides the sensor nodes with the energy required for operation.

In this embodiment, the signal transmission module 10 includes a transmission gateway 11, where the transmission gateway 11 is also called an intersubnetwork connector and a protocol converter, and is used for connecting a wireless sensor network formed by the plurality of sensor nodes with a server of an external device. In practical application of the terminal management device, each sensor node in the monitoring area monitors environmental parameters such as temperature, humidity, pressure, sound and the like in the surrounding environment in real time by means of a plurality of built-in sensors, and outputs a plurality of environmental monitoring signals to the signal transmission module 10, so that the signal transmission module 10 further sends the signals to the server. After receiving the signal, the server reverts the signal to environment monitoring data for the user to check so that the user can know the environment condition in the monitoring area.

Alternatively, the intelligent interaction module 20 may be implemented by using an operation panel, or may be implemented by using an operation screen 21. In this embodiment, the intelligent interaction module 20 is implemented using an operation screen 21. Specifically, in the process of setting up the internet of things, the user controls the intelligent interaction module 20 to generate a node signal of the sensor node and outputs the node signal to the signal transmission module 10, so that the signal transmission module 10 further transmits the node signal to a server of an external device through wireless transmission, and the operation of on-line or off-line of the node can be completed during on-site deployment. After the sensor nodes are deployed to form the wireless sensor network, a user does not need to enter the serial numbers and the position information of each sensor node one by one on a computer in a machine room or an operation room, and the deployment efficiency of the Internet of things is improved.

The utility model provides a terminal management device which is applied to a wireless sensor network of a plurality of sensor nodes and is in communication connection with different sensor nodes. The terminal management equipment comprises a signal transmission module 10 and an intelligent interaction module 20; the signal transmission module 10 is in communication connection with the sensor node and with a server of an external device; the intelligent interaction module 20 is in communication with the signal transmission module 10. The technical scheme of the utility model is that the signal transmission module 10 is adopted, so that a user can conveniently know the environment condition of a monitoring area in real time in a wireless transmission mode. On the basis of the scheme, the intelligent interaction module 20 is further arranged for user interaction to rapidly deploy the sensor nodes, so that the deployment efficiency of the Internet of things is improved.

Referring to fig. 2, in an embodiment, the signal transmission module 10 further includes:

a transmission gateway 11, wherein the transmission gateway 11 comprises a gateway housing 111 and a gateway controller, and the gateway controller is arranged on the gateway housing 111;

a receiving antenna 12, provided in the gateway housing 111, where the receiving antenna 12 is in communication connection with the sensor node, and the gateway controller is electrically connected, and the receiving antenna 12 is configured to receive an environmental monitoring signal collected by the sensor node, and output the environmental monitoring signal to the gateway controller;

and a transmission antenna 13, provided in the gateway housing 111, where the transmission antenna 13 is electrically connected to the gateway controller and is in communication connection with the server, and the transmission antenna 13 is configured to receive the environmental monitoring signal sent by the gateway controller and output the environmental monitoring signal to the server.

Alternatively, the signal transmission module 10 may be implemented by using wireless data transmission and wired data transmission. The signal transmission module 10 in this embodiment is implemented by microwave transmission in wireless data transmission. The signal transmission module 10 includes a transmission gateway 11, a reception antenna 12, and a transmission antenna 13; wherein the transmission gateway 11 is composed of a gateway housing 111, a gateway controller, and the like. The gateway housing 111 is used for mounting a gateway controller and other components, and may be made of a metal material or a plastic material, which is not limited herein. The model of the gateway controller is not limited in general, and can be set as required.

Specifically, in practical application of the device, the receiving antenna 12 receives the environmental monitoring signals collected by all the sensor nodes in the monitoring area based on the control of the gateway controller. The gateway controller receives the plurality of environmental monitoring signals and transmits them to the transmission antenna 13, so that the transmission antenna 13 further outputs the signals to a server connected to the server in wireless communication. After the server receives the signal and restores the signal to the environment monitoring data, the user can know the environment condition in the monitoring area by looking up the data.

Referring to fig. 2, in an embodiment, the signal transmission module 10 further includes:

an ethernet interface 14 is provided in the gateway housing 111 and is electrically connected to the gateway controller, and the ethernet is used for connecting to the server.

Alternatively, the ethernet interface 14 may employ an RJ-45 interface, an RJ-11 interface, an SC fiber interface, an FDDI interface, an AUI interface, a BNC interface, and a cone interface, which are not limited herein. Specifically, by providing the ethernet interface 14, the signal transmission module 10 in the present embodiment may be implemented by using wired data transmission. In this way, when it is required to improve the stability of acquiring the environmental information in the monitoring area, the user can access the server of the external device through the ethernet interface 14, so that the transmission antenna 13 in the signal transmission module 10 more quickly and more stably transmits the received environmental monitoring signal to the server.

Referring to fig. 2 to 4, in an embodiment, the intelligent interaction module 20 further includes:

an operation screen 21, the operation screen 21 including a screen housing 211, a screen controller, a touch display screen 212, and a transmitting antenna 213; wherein, the liquid crystal display device comprises a liquid crystal display device,

the screen controller is arranged on the screen shell 211;

the touch display screen 212 is disposed on the screen housing 211, the touch display screen 212 is electrically connected to the screen controller, and the touch display screen 212 is used for providing user interaction to generate a node signal corresponding to the sensor node and outputting the node signal to the screen controller;

the transmitting antenna 213 is disposed in the screen housing 211, the transmitting antenna 213 is electrically connected to the screen controller and is communicatively connected to the receiving antenna 12, and the transmitting antenna 213 is configured to receive the node signal sent by the screen controller and output the node signal to the receiving antenna 12.

In this embodiment, the intelligent interaction module 20 is implemented using an operation screen 21, and the operation screen 21 is composed of a screen housing 211, a screen controller, a touch display screen 212, a transmitting antenna 213, and the like.

Specifically, the screen housing 211 is used for mounting a screen controller, a touch display screen 212 and a transmitting antenna 213, and its cross-sectional shape is generally rectangular, so that it is convenient for a user to install and use. The screen housing 211 may be made of a metal material or a plastic material, which is not limited herein. The type of touch screen 212 is generally not limited and may be set as desired.

It should be noted that, the bottom of the touch display screen 212 and the peripheral wall of the screen housing 211 form a mounting cavity, and the screen controller and the transmitting antenna 213 are both mounted in the mounting cavity. In this way, the operation screen 21 formed by the screen housing 211, the screen controller, the touch display screen 212 and the transmitting antenna 213 is in an integrated structure, so that the influence of external environmental factors on the screen controller and the transmitting antenna 213 is reduced, and the user can conveniently carry and use the operation screen 21.

Thus, in the process of setting up the internet of things, when a user is deploying a certain sensor node, the user can operate the screen 21 by holding the user's hand so as to further control the touch display screen 212, so as to generate a node signal corresponding to the sensor node, and output the signal to the screen controller. The screen controller receives the signal and sends it to the transmitting antenna 213. The transmitting antenna 213 outputs the above-mentioned signal to the receiving antenna 12 in the signal transmission module 10, so that the receiving antenna 12 further forwards to the server via wireless transmission. The user repeats the operation on the plurality of sensor nodes, so that a wireless sensor network which is finally needed can be formed, and the operation of on-line or off-line of the nodes can be completed during on-site deployment, thereby improving the deployment efficiency of the Internet of things.

Referring to fig. 2 to 4, in an embodiment, the intelligent interaction module 20 further includes:

the scanning piece 22 is arranged on the other side of the screen shell 211, which is opposite to the touch display screen 212, the scanning piece 22 is electrically connected with the screen controller, and the scanning piece 22 is used for scanning the two-dimensional code on the sensor node so as to acquire the information of the sensor node.

Alternatively, the scanner 22 may be implemented using a camera as well as a scanner. In this embodiment, in order to enable the intelligent interaction module 20 to have a function of scanning two-dimensional codes, the scanning piece 22 is implemented by a rear camera. The model of the rear camera is not limited generally, and can be set according to the needs.

Specifically, when a user is deploying a certain sensor node, the user can hold the operation screen 21 by hand, so that the scanning member 22 thereon scans the two-dimensional code on the sensor node, and outputs a corresponding node signal to the screen controller. After receiving the node signal, the screen controller controls the touch display screen 212 to display the relevant information of the sensor node. After the user performs editing operation on the touch display screen 212 according to the information, the screen controller further outputs the node signal to the transmission gateway 11, so that the transmission gateway 11 forwards the node signal to the server after receiving the node signal, and further, the user can conveniently perform online or offline operation on the node.

Referring to fig. 1 to 6, in an embodiment, the terminal management device further includes:

a first mounting portion 15 provided in the gateway housing 111 and electrically connected to the gateway controller;

a second mounting portion 23 provided at the other side of the screen housing 211 with respect to the touch display screen 212 and electrically connected to the screen controller;

the first mounting portion 15 is assembled with the second mounting portion 23 to trigger the transmission gateway 11 to be electrically connected with the operation screen 21.

Alternatively, the first mounting portion 15 may be provided at any position of the gateway housing 111; the second mounting portion 23 may be provided at any position of the other side of the screen housing 211 with respect to the touch display screen 212. In order to improve the stability of installation, in the present embodiment, the first installation portion 15 is provided at a middle position of the front or rear surface of the gateway housing 111; the second mounting portion 23 is disposed at a middle position of the other side of the screen housing 211 with respect to the touch display screen 212, and is disposed corresponding to the position of the first mounting portion 15.

In this way, the user can trigger the operation screen 21 to be electrically connected to the transmission gateway 11 by holding the operation screen 21 so that the second mounting portion 23 thereon is fitted with the first mounting portion 15 of the transmission gateway 11. The receiving antenna 12 continuously receives the environmental monitoring signals collected by all the sensor nodes in the monitoring area, and outputs a plurality of environmental monitoring signals to the gateway controller. After receiving the signal, the gateway controller further sends the signal to the screen controller, so that the screen controller controls the touch display screen 212 to display the environmental monitoring data collected by the sensor nodes, and the environmental monitoring data is checked by a user at any time.

Referring to fig. 1 to 6, in an embodiment, the first mounting portion 15 includes a first contact base 151, the first contact base 151 is disposed on the gateway housing 111, the first contact base 151 is electrically connected to the gateway controller, and a positioning hole 152 is formed in the gateway housing 111;

the second mounting portion 23 includes a second contact seat 231 and a positioning member 232, the second contact seat 231 and the positioning member 232 are both disposed on the other side of the screen housing 211 relative to the touch display screen 212, and the second contact seat 231 is electrically connected to the screen controller;

the positioning hole 152 is assembled and matched with the positioning piece 232 to drive the first contact seat 151 to contact with the second contact seat 231.

Alternatively, the first contact base 151 may be disposed at any position of the gateway housing 111, and the second contact base 231 may be disposed at any position of the screen housing 211. In the present embodiment, the first contact seat 151 is disposed at a middle position of the front or rear surface of the gateway housing 111, and two positioning holes 152 are disposed at two sides of the first contact seat 151. The second contact seat 231 is disposed at a middle position of the other side of the screen housing 211 opposite to the touch display screen 212 and corresponds to the first contact seat 151, and the positioning members 232 are also disposed at two positions corresponding to the two positioning holes 152 one to one and disposed at two sides of the second contact seat 231 respectively.

Specifically, when the user needs to view the environmental monitoring data collected by the sensor node at the deployment site, the user can hold the screen housing 211 by hand, so that the positioning piece 232 on the screen housing is assembled and matched with the positioning hole 152 on the gateway housing 111, and further the first contact seat 151 is driven to contact with the second contact seat 231, so that the first contact seat 151 sends a first control signal to the gateway controller, and the second contact seat 231 also sends a second control signal to the screen controller. Since the first contact base 151 and the second contact base 231 are both made of metal, and have good electrical conductivity, the first control signal and the second control signal trigger the gateway controller to be electrically connected with the screen controller. In this way, the gateway controller receives the environmental monitoring signals collected by the sensor nodes through the receiving antenna 12 and sends the environmental monitoring signals to the shielding controller, so that the screen controller controls the touch display screen 212 to display the environmental monitoring data of the corresponding sensor nodes for a user to view in the deployment site.

Referring to fig. 1 to 6, in an embodiment, the first mounting portion 15 further includes a first magnet, and the first magnet is disposed on the gateway housing 111;

the second mounting portion 23 further includes a second magnet, and the second magnet is disposed on the screen housing 211;

the first magnet and the second magnet are attracted to each other to maintain a contact state between the first contact seat 151 and the second contact seat 231.

Alternatively, the first magnet may be disposed inside and outside the gateway housing 111, and the second magnet may be disposed inside and outside the screen housing 211. In the present embodiment, the first magnet is disposed inside the gateway housing 111 at a position corresponding to the first contact base 151; the second magnet is disposed inside the screen housing 211 at a position corresponding to the second contact seat 231. In this way, on the premise that the positioning piece 232 and the positioning hole 152 are assembled with each other, and the first contact seat 151 and the second contact seat 231 are contacted with each other, the first magnet and the second magnet are attracted with each other, so as to maintain the contact state between the first contact seat 151 and the second contact seat 231, thereby improving the stability of signal transmission between the gateway controller and the screen controller, and ensuring that the touch display screen 212 continuously displays relevant environmental monitoring data.

Referring to fig. 1 to 6, in an embodiment, the intelligent interaction module 20 further includes:

the USB interface 24 is disposed on the screen housing 211 and electrically connected to the screen controller, and the USB interface 24 is used for externally connecting a mobile device.

It will be appreciated that the removable device may be a removable hard disk as well as a USB flash disk, which is not limited herein.

Alternatively, the USB interface 24 may be disposed on any side of the screen housing 211, which is not limited herein. The type of the USB interface 24 is not limited in general, and may be set as needed.

Specifically, the operation screen 21 in this embodiment may be externally connected to the mobile device through the USB interface 24, so that even if the user is in a network-free environment, the environmental monitoring data collected by the sensor node received on the operation screen 21 may be copied to the mobile device for storage, which is convenient for use.

Referring to fig. 1 to 6, in an embodiment, the intelligent interaction module 20 further includes:

the HDMI output interface 25 is disposed on the screen housing 211 and electrically connected to the screen controller, and the HDMI output interface 25 is used for connecting an electronic device having an HDMI input interface.

It is understood that the electronic device with HDMI input interface may be a computer display, a video projector, a digital audio device, etc., without limitation.

Alternatively, the HDMI output interface 25 may be provided on either side of the screen housing 211, which is not limited herein. The type of the HDMI output interface 25 is not limited in general, and may be set as necessary.

Specifically, the operation screen 21 in the present embodiment may be externally connected to an electronic device having an HDMI input interface through the HDMI output interface 25, so that video data or audio data in the environment detection data collected by the sensor node received on the operation screen 21 is transmitted to the electronic device. The user can more intuitively know the environment of the monitoring area by watching the image on the electronic device or listening to the sound emitted by the electronic device.

The foregoing description is only of the preferred embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structural changes made by the description of the present utility model and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the utility model.

Claims (10)

1. A terminal management apparatus for use in a wireless sensor network including a plurality of sensor nodes, and for communication connection between different ones of the sensor nodes, the terminal management apparatus comprising:

the signal transmission module is in communication connection with the sensor node and a server of external equipment, and is used for receiving an environment monitoring signal acquired by the sensor node and sending the environment monitoring signal to the server;

the intelligent interaction module is in communication connection with the signal transmission module, and is used for user interaction to generate node signals corresponding to the sensor nodes and output the node signals to the signal transmission module.

2. The terminal management device according to claim 1, wherein the signal transmission module further includes:

the transmission gateway comprises a gateway shell and a gateway controller, and the gateway controller is arranged on the gateway shell;

the receiving antenna is arranged on the gateway shell, is in communication connection with the sensor node and is electrically connected with the gateway controller, and is used for receiving the environment monitoring signals collected by the sensor node and outputting the environment monitoring signals to the gateway controller;

the transmission antenna is arranged on the gateway shell, is electrically connected with the gateway controller and is in communication connection with the server, and is used for receiving the environment monitoring signals sent by the gateway controller and outputting the environment monitoring signals to the server.

3. The terminal management device according to claim 2, wherein the signal transmission module further includes:

the Ethernet interface is arranged on the gateway shell and is electrically connected with the gateway controller, and the Ethernet is used for connecting the server.

4. The terminal management device of claim 2, wherein the intelligent interaction module further comprises:

an operation screen including a screen housing, a screen controller, a touch display screen, and a transmitting antenna; wherein, the liquid crystal display device comprises a liquid crystal display device,

the screen controller is arranged on the screen shell;

the touch display screen is arranged on the screen shell, is electrically connected with the screen controller, and is used for providing user interaction to generate node signals corresponding to the sensor nodes and outputting the node signals to the screen controller;

the transmitting antenna is arranged on the screen shell, is electrically connected with the screen controller and is in communication connection with the receiving antenna, and is used for receiving the node signals sent by the screen controller and outputting the node signals to the receiving antenna.

5. The terminal management device of claim 4, wherein the intelligent interaction module further comprises:

the scanning piece is arranged on the other side of the screen shell relative to the touch display screen, is electrically connected with the screen controller and is used for scanning the two-dimensional code on the sensor node so as to acquire the information of the sensor node.

6. The terminal management apparatus according to claim 4, wherein the terminal management apparatus further comprises:

the first installation part is arranged on the gateway shell and is electrically connected with the gateway controller;

the second installation part is arranged on the other side of the screen shell relative to the touch display screen and is electrically connected with the screen controller;

the first mounting part is assembled and matched with the second mounting part so as to trigger the transmission gateway to be electrically connected with the operation screen.

7. The terminal management apparatus according to claim 6, wherein the first mounting portion includes a first contact seat provided in a gateway housing, the first contact seat being electrically connected to the gateway controller, the gateway housing being provided with a positioning hole;

the second installation part comprises a second contact seat and a positioning piece, the second contact seat and the positioning piece are both arranged on the other side of the screen shell relative to the touch display screen, and the second contact seat is electrically connected with the screen controller;

the positioning hole is matched with the positioning piece in an assembling way so as to drive the first contact seat to be contacted with the second contact seat.

8. The terminal management apparatus according to claim 7, wherein the first mounting portion further includes a first magnet provided to the gateway housing;

the second installation part further comprises a second magnet, and the second magnet is arranged on the screen shell;

the first magnet and the second magnet are attracted to each other to maintain a contact state between the first contact seat and the second contact seat.

9. The terminal management device of claim 4, wherein the intelligent interaction module further comprises:

the USB interface is arranged on the screen shell and is electrically connected with the screen controller, and the USB interface is used for externally connecting movable equipment.

10. The terminal management device of claim 4, wherein the intelligent interaction module further comprises:

the HDMI output interface is arranged on the screen shell and is electrically connected with the screen controller, and the HDMI output interface is used for being connected with electronic equipment with an HDMI input interface.

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