CN220415464U - Mining fusion information transmission system - Google Patents

Abstract

The application relates to the technical field of communication and provides a mining fusion information transmission system. Mining fusion information transmission system includes: the system comprises an underground device, a fusion information transmission device, an underground broadcasting device, an underground communication device and a wireless communication base station subsystem; the fusion information transmission equipment is in signal connection with the underground broadcasting equipment and the underground communication equipment through a wireless communication base station subsystem; the fusion information transmission device is also in signal connection with the uphole device. Through above-mentioned technical scheme, can help solving the poor problem of system stability, owing to through fusing signal connection between information transmission equipment and the broadcasting equipment and the communication equipment in pit, can realize signal connection between equipment in pit and broadcasting equipment in pit and the communication equipment in pit, so can fuse communication system and emergency broadcasting system to make communication and broadcasting can support each other in the function, and then help improving the stability of system.

Description

Mining fusion information transmission system

Technical Field

The application relates to the technical field of communication, in particular to a mining fusion information transmission system.

Background

In order to enable mineral exploitation to meet the requirement of safe production, a mine needs to deploy two sets of communication systems and emergency broadcasting systems, and in the related art, the communication systems and the emergency broadcasting systems are independently established to meet the requirement of safe production.

However, the communication system and the emergency broadcasting system in the related art are independent from each other in hardware, and it is difficult to realize association control, which results in a problem that the two systems cannot be supported each other functionally, and thus the stability of the systems is poor.

Disclosure of Invention

In order to help solve the problem of poor system stability, the application provides a mining fusion information transmission system.

The application provides a mining fusion information transmission system, which adopts the following technical scheme:

the mining fusion information transmission system comprises an underground device, a fusion information transmission device, an underground broadcasting device, an underground communication device and a wireless communication base station subsystem, wherein the fusion information transmission device, the underground broadcasting device and the underground communication device are arranged underground;

the wireless communication base station subsystem comprises a control unit and an antenna unit connected with the control unit, wherein the antenna unit is arranged underground, and the fusion information transmission equipment is in signal connection with the underground broadcasting equipment and the underground communication equipment through the wireless communication base station subsystem;

the fusion information transmission equipment is also in signal connection with the aboveground equipment, and the aboveground equipment is in signal connection with the underground broadcasting equipment and the underground communication equipment through signal connection between the aboveground equipment and the fusion information transmission equipment and signal connection between the fusion information transmission equipment and the underground broadcasting equipment and the underground communication equipment.

By adopting the technical scheme, the problem of poor system stability can be solved, because the signal connection between the underground equipment and the fusion information transmission equipment and the signal connection between the fusion information transmission equipment and the underground broadcasting equipment and the underground communication equipment can be realized, the signal connection between the underground equipment and the underground broadcasting equipment and the underground communication equipment can be realized, and the communication system and the emergency broadcasting system can be fused, so that the communication and the broadcasting can be controlled in a correlated manner, the communication and the broadcasting can be mutually supported in function, and the stability of the system can be improved.

Optionally, the antenna unit includes more than two active antenna units, and the wireless communication base station subsystem further includes a hub unit;

the control unit is respectively connected with the active antenna units through the hub unit in a signal mode.

In the technical scheme, the active antenna unit is adopted, so that the cost of the feeder line between the remote radio unit and the passive antenna can be saved, and meanwhile, the signal loss caused by feeder line transmission of the traditional communication base station system can be reduced, and the subsystem based on the wireless communication base station can be ensured.

Optionally, the wireless communication base station subsystem includes a 5G base station subsystem.

In the technical scheme, the 5G base station subsystem is adopted to help to improve the information transmission speed of the fusion information transmission equipment, the underground communication equipment and the underground broadcasting equipment, reduce the information transmission delay and further improve the reliability of communication and emergency broadcasting.

Optionally, the control unit includes a centralized unit and a distributed unit, the antenna unit includes an active antenna unit, and the centralized unit is in signal connection with the active antenna unit through the distributed unit.

By adopting the technical scheme, as the control unit comprises the centralized unit and the distribution unit, the flexibility of the deployment of the control unit can be improved, the deployment mode of the distribution unit can be conveniently and reasonably set according to the requirements of actual use scenes, and the requirements of different scenes can be further met.

Optionally, the 5G base station subsystem includes more than two centralized units of each 5G base station subsystem, and the distribution unit of each 5G base station subsystem is disposed at a position close to the active antenna unit of the 5G base station subsystem.

In the above technical scheme, since the centralized control units of the 5G base station subsystems are arranged in a centralized manner, the centralized control units can be maintained conveniently, and meanwhile, since the distribution units are arranged at positions close to the active antenna units, the distribution units can be used for processing the service with strong real-time performance, the response timeliness of the 5G base station subsystems can be ensured, and thus the reliability of the converged communication system can be improved.

Optionally, the centralized unit and the distributed unit are centrally disposed.

Because the centralized units and the distributed units are generally connected through optical fibers, in some use scenes with low aging requirements, the centralized arrangement of the centralized units and the distributed units can reduce the amount of optical fibers required in the system deployment process by adopting the technical scheme, so that the deployment cost of the system can be reduced.

Optionally, the wireless communication base station subsystem is further connected with a core network, and the converged information transmission device is accessed to the core network through the wireless communication base station subsystem.

In the technical scheme, the converged information transmission equipment can be accessed to the core network through the wireless communication base station subsystem, so that the equipment which can be accessed to the core network can realize information interaction with the converged information transmission equipment, and can conveniently carry out remote information transmission with the converged information transmission equipment.

Optionally, the above-mentioned device accesses the core network, and the above-mentioned device is connected with the above-mentioned fusion information transmission device through the above-mentioned core network signal.

In the technical scheme, the above-mentioned equipment is connected with the fusion information transmission equipment through the core network signal, so that a special channel is not required to be established for the above-mentioned equipment and the fusion information transmission equipment, and the deployment cost of the system can be reduced.

Optionally, the above-mentioned well equipment and the above-mentioned fusion information transmission equipment are connected to the same local area network so as to be connected through the above-mentioned local area network signal.

In the technical scheme, the above-mentioned equipment is connected with the fusion information transmission equipment through the local area network signal, so that the cost of information transmission between the above-mentioned equipment and the fusion information transmission equipment can be reduced, and the speed of information transmission between the above-mentioned equipment and the fusion information transmission equipment can be guaranteed.

Optionally, the above-mentioned well equipment is connected with the fusion information transmission equipment through an optical fiber.

In the technical scheme, because the optical fiber connection is adopted, the stability of signal transmission between the on-well equipment and the fusion information transmission equipment can be improved, and the reliability of the system can be improved.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the system stability problem can be solved, and the signal connection between the underground equipment and the underground broadcasting equipment and the underground communication equipment can be realized through the signal connection between the underground equipment and the fusion information transmission equipment and the signal connection between the fusion information transmission equipment and the underground broadcasting equipment and the underground communication equipment, so that the communication system and the emergency broadcasting system can be fused, the associated control of communication and broadcasting can be realized, the communication and the broadcasting can be mutually supported in function, and the stability of the system can be improved.

2. Because the fusion information transmission equipment is connected with the underground broadcasting equipment and the underground communication equipment through the wireless communication base station subsystem, wireless signal transmission between the fusion information transmission equipment and the underground broadcasting equipment and the underground communication equipment can be realized, and therefore deployment of the underground broadcasting equipment and the underground communication equipment can be facilitated.

Drawings

Fig. 1 is a schematic structural diagram of a mining fusion information transmission system provided in an embodiment of the present application;

fig. 2 is a schematic structural diagram of a wireless communication base station subsystem according to an embodiment of the present application;

fig. 3 is a schematic structural diagram of another wireless communication base station subsystem according to an embodiment of the present application.

Reference numerals illustrate: 100. an uphole device; 200. fusion information transmission equipment; 300. downhole broadcasting equipment; 400. downhole communication equipment; 500. a wireless communication base station subsystem; 510. a control unit; 511. a concentration unit; 512. a distribution unit; 520. an antenna unit; 521. an active antenna unit; 530. a hub unit.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application will be further described in detail with reference to fig. 1 to 3 and the embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application.

The embodiment of the application discloses a mining fusion information transmission system, referring to fig. 1, the mining fusion information transmission system comprises an uphole device 100, a fusion information transmission device 200, an downhole broadcasting device 300, a downhole communication device 400 and a wireless communication base station subsystem 500.

Wherein the fusion information transmitting apparatus 200, the downhole broadcasting apparatus 300, and the downhole communication apparatus 400 are disposed downhole.

The wireless communication base station subsystem comprises a control unit 510 and an antenna unit 520 in signal connection with the control unit 510, the antenna unit 520 being arranged downhole.

The uphole device 100 refers to: an apparatus on a well. In one example, the uphole device 100 includes a server, zone controller, computer, etc. located at a surface control center.

The downhole broadcasting apparatus 300 refers to: downhole broadcast enabled devices such as: speakers, sound equipment, etc. Alternatively, the downhole broadcasting device 300 may be disposed at a fixed location downhole, or may be disposed in an operating room of a downhole movable mechanical device, and the manner of disposing the downhole broadcasting device 300 is not limited in this embodiment.

The downhole communication device 400 refers to: downhole devices having communication functions. Alternatively, the downhole communication device 400 may be stationary, such as: a landline telephone, or may be removable, such as: the implementation of the downhole communication device 400 is not limited in this embodiment as long as the communication function can be implemented by the portable mobile terminal used by the downhole operator.

The fusion information transfer apparatus 200 is used to implement signal connection between the uphole apparatus 100 and the downhole broadcasting apparatus 300 and the downhole communication apparatus 400. Specifically, the fusion information transmission device 200 is in signal connection with the uphole device 100, the downhole broadcasting device 300 and the downhole communication device 400, respectively, so that the signal connection between the uphole device 100 and the downhole broadcasting device 300 and the downhole communication device 400 can be realized through the signal connection between the uphole device 100 and the fusion information transmission device 200 and the signal connection between the fusion information transmission device 200 and the downhole broadcasting device 300 and the downhole communication device 400.

Optionally, the converged information delivery device 200 supports at least one information delivery mode. In one example, the converged information delivery device 200 may be implemented as a gateway or router.

The wireless communication base station subsystem 500 is used for establishing a wireless communication network downhole, and the converged information transmission apparatus 200 is in signal connection with the downhole broadcasting apparatus 300 and the downhole communication apparatus 400 through the wireless communication base station subsystem 500.

Specifically, the radio communication base station subsystem 500 includes a control unit 510 and an antenna unit 520 in signal connection with the control unit 510. In the wireless communication process, the wireless communication base station subsystem 500 receives data information transmitted by other devices through the antenna unit 520, processes the data information through the control unit 510, and transmits the processed data information to the corresponding devices through the antenna unit 520, so that communication between the devices can be realized.

In one example, the wireless communication base station subsystem 500 comprises a cellular mobile communication base station subsystem, in which case the wireless communication base station subsystem 500 may comprise a 5G base station subsystem or may also comprise a 4G, 3G base station subsystem.

In actual implementation, the wireless communication base station subsystem 500 may also provide other wireless communication modes, such as: based on WiFi, UWB, zigBee implementation, the present embodiment does not limit the type of wireless communication scheme provided by the wireless communication base station subsystem 500.

Because the signal coverage of the single wireless communication base station subsystem 500 is limited, and the distribution range of the downhole device is wider, in order to realize the coverage of the downhole wireless signals, the number of the wireless communication base station subsystems 500 can be more than two, and meanwhile, the wireless communication base station subsystems can form access networks in different manners, so that the information interaction between the fusion information transmission device 200 and the downhole broadcasting device 300 and the downhole communication device 400 can be facilitated.

The implementation principle of the mining fusion information transmission system provided by the embodiment of the application is as follows: the mining fusion information transmission system comprises an uphole device 100, a fusion information transmission device 200, a downhole broadcasting device 300, a downhole communication device 400 and a wireless communication base station subsystem 500, wherein the fusion information transmission device 200, the downhole broadcasting device 300 and the downhole communication device 400 are arranged underground; the fusion information transmission device 200 is in signal connection with the underground broadcasting device 300 and the underground communication device 400 through the wireless communication base station subsystem 500; the fusion information transfer device 200 is also in signal connection with the uphole device 100. Through the above technical scheme, the problem of poor system stability can be solved, because through the signal connection between the aboveground equipment 100 and the fusion information transmission equipment 200 and the signal connection between the fusion information transmission equipment 200 and the underground broadcasting equipment 300 and the underground communication equipment 400, the signal connection between the aboveground equipment 100 and the underground broadcasting equipment 300 and the underground communication equipment 400 can be realized, so that the communication system and the emergency broadcasting system can be fused, the associated control of communication and broadcasting can be realized, the communication and the broadcasting can be mutually supported in function, and the stability of the system can be improved.

In addition, the communication and emergency broadcasting functions can be realized based on the fusion information transmission system, so that the fusion of the communication system and the emergency broadcasting system on hardware can be realized, the hardware and the construction cost can be saved, and the maintenance difficulty of the system can be reduced.

In addition, since the fusion information transmission device 200 is in signal connection with the downhole broadcasting device 300 and the downhole communication device 400 through the wireless communication base station subsystem 500, wireless signal transmission between the fusion information transmission device 200 and the downhole broadcasting device 300 and the downhole communication device 400 can be realized, and thus deployment of the downhole broadcasting device 300 and the downhole communication device 400 can be facilitated.

In some embodiments, referring to fig. 2, antenna unit 520 includes more than two active antenna units 521, and wireless communication base station subsystem 500 further includes hub unit 530.

The control unit 510 is signal-connected to each of the active antenna units 521 via a hub unit 530.

The active antenna element 521 refers to: and combining the remote radio unit (Remote Radio Unit, RRU) with the passive antenna.

In one example, the control unit 510 is connected to the hub unit 530 by optical fibers.

In one example, the active antenna element 521 may be implemented as a pico-cell (PRRU) that is signally connected to the hub unit 530 via a network cable, such as a Cat6A network cable.

In one example, the control unit 510 may be implemented as a baseband control unit (Building Baseband Unit, BBU).

In the above technical solution, the active antenna unit 521 is adopted, so that the cost of the feeder line between the remote radio unit and the passive antenna can be saved, and meanwhile, the signal loss caused by the feeder line transmission in the conventional communication base station system can be reduced, so that the base station subsystem 500 based on wireless communication can be ensured.

In addition, since the wireless communication base station subsystem 500 further includes the hub unit 530, a plurality of active antennas can be conveniently connected to the same control unit 510 through the hub unit 530, so that the deployment of the wireless communication base station subsystem 500 can be facilitated, and the deployment cost of the system can be reduced.

In some implementations, the wireless communication base station subsystem 500 includes a 5G base station subsystem.

Wherein, the 5G base station subsystem refers to: a communication base station subsystem supporting a 5G communication protocol. In practical implementation, the 5G base station subsystem can also be downward compatible with 4G and 3G communication protocols, so that some traditional devices can conveniently access a wireless network, and the deployment cost of the system is reduced.

Because the 5G has the characteristics of high speed and low delay, in the technical scheme, the adoption of the 5G base station subsystem can be beneficial to improving the information transmission speed of the fusion information transmission equipment 200, the underground communication equipment 400 and the underground broadcasting equipment 300, and reducing the information transmission delay, so that the reliability of communication and emergency broadcasting can be improved.

Optionally, referring to fig. 3, the control Unit 510 includes a Centralized Unit 511 (CU) and a distributed Unit 512 (DU), the antenna Unit 520 includes an active antenna Unit 521 (Active Antenna Unit, AAU), and the Centralized Unit 511 is in signal connection with the active antenna Unit 521 through the distributed Unit 512.

The centralized unit 511 is obtained by dividing the non-real-time part of the conventional baseband control unit, and is responsible for processing non-real-time protocols and services.

The active antenna unit 521 is formed by combining part of the physical layer processing functions of the conventional baseband control unit with the remote radio unit and the passive antenna.

The distribution unit 512 is used for implementing the functions of the conventional baseband control unit except the functions implemented by the concentration unit 511 and the active antenna unit 521, that is, is responsible for processing physical layer protocols and real-time services.

It should be noted that, the specific implementation manners of the centralized control unit 510, the distribution unit 512, and the active antenna unit 521 are all related to the art in the 5G communication field, and the present embodiment does not relate to an improvement of the implementation manners of the control unit 510, the distribution unit 512, and the active communication unit.

In the above technical solution, since the control unit 510 includes the centralized unit 511 and the distributed unit 512, the flexibility of deployment of the control unit 510 can be improved, so that the deployment mode of the distributed unit 512 can be set reasonably according to the requirements of actual usage scenarios, and thus the requirements of different scenarios can be met.

In one example, the 5G base station subsystem includes more than two centralized control units 510 of each 5G base station subsystem, and the distribution unit 512 of each 5G base station subsystem is disposed near the active antenna unit 521 of the 5G base station subsystem.

In one example, the centralized control unit 510 of each 5G base station subsystem is disposed within a downhole control cabinet.

In the above technical solution, since the centralized control units 510 of each 5G base station subsystem are centrally disposed, the centralized control units 510 can be conveniently maintained, and meanwhile, since the distribution units 512 are disposed at positions close to the active antenna units 521, the distribution units 512 can be used for processing the service with strong real-time performance, so that the timeliness of the response of the 5G base station subsystem can be ensured, thereby being beneficial to improving the reliability of the converged communication system.

In another example, the concentration unit 511 and the distribution unit 512 are centrally disposed. Because the centralized unit 511 and the distributed unit 512 are generally connected through optical fibers, in some usage scenarios with less time-consuming requirements, the centralized arrangement of the centralized unit 511 and the distributed unit 512 can reduce the amount of optical fibers required in the deployment process of the system, thereby contributing to the reduction of the deployment cost of the system.

In some embodiments, the wireless communication base station subsystem 500 is further connected to a core network, and the converged information transmission apparatus 200 accesses the core network through the wireless communication base station subsystem 500.

Alternatively, the manner in which the wireless communication base station subsystem 500 accesses the core network may be access to the core network through a packet transport network (Packet Transport Network, PTN), or may also be access to the core network through a broadband passive optical network (GPON) or other broadband access manners, which is not limited by the manner in which the control unit 510 accesses the core network.

In the above technical solution, since the converged information transmission device 200 may access the core network through the wireless communication base station subsystem 500, the device capable of accessing the core network may implement information interaction with the converged information transmission device 200, so that it may be convenient to perform remote information transmission with the converged information transmission device 200.

Further, the above-mentioned device 100 is connected to the core network, and the above-mentioned device 100 is connected to the fusion information transmission device 200 through the core network signal.

Alternatively, the manner in which the above-mentioned device 100 accesses the core network may be accessed through an optical fiber communication interface or may also be accessed through another wireless communication base station, which is not limited by the manner in which the above-mentioned device 100 accesses the core network in this embodiment.

In the above technical solution, since the above-mentioned device 100 and the fusion information transmission device 200 are connected through the core network signal, it is not necessary to establish a dedicated channel for the above-mentioned device 100 and the fusion information transmission device 200, which can help to reduce the deployment cost of the system.

In some embodiments, the uphole device 100 and the fusion information delivery device 200 are connected to the same local area network to enable signal connection between the uphole device 100 and the fusion information delivery device 200 via the local area network.

In one example, the uphole device 100 and the fusion information delivery device 200 are connected by optical fibers, which may help to improve the stability of signal transmission between the uphole device 100 and the fusion information delivery device 200, which may help to improve the reliability of the system.

In practical implementation, the uphole device 100 and the fusion information transmission device 200 may be connected by a twisted pair or a wireless signal, and the information transmission method of the uphole device 100 and the fusion information transmission device 200 is not limited in this embodiment.

In the above technical solution, because the aboveground device 100 and the fusion information transmission device 200 are connected through the lan signal, it is helpful to reduce the cost of information transmission between the aboveground device 100 and the fusion information transmission device 200, and at the same time, it is also helpful to ensure the speed of information transmission between the aboveground device 100 and the fusion information transmission device 200.

The foregoing description of the preferred embodiments of the present application is not intended to limit the scope of the application, in which any feature disclosed in this specification (including abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. That is, each feature is one example only of a generic series of equivalent or similar features, unless expressly stated otherwise.

Claims (9)

1. A mining fusion information transmission system, which is characterized by comprising an uphole device (100), a fusion information transmission device (200), a downhole broadcasting device (300), a downhole communication device (400) and a wireless communication base station subsystem (500), wherein the fusion information transmission device (200), the downhole broadcasting device (300) and the downhole communication device (400) are arranged downhole;

the wireless communication base station subsystem (500) comprises a control unit (510) and an antenna unit (520) connected with the control unit (510), wherein the antenna unit (520) is arranged underground, and the fusion information transmission equipment (200) is in signal connection with the underground broadcasting equipment (300) and the underground communication equipment (400) through the wireless communication base station subsystem (500); the antenna unit (520) comprises more than two active antenna units (521), the wireless communication base station subsystem (500) further comprising a hub unit (530); the control unit (510) is respectively connected with the active antenna units (521) through the hub unit (530) in a signal manner;

the fusion information transmission device (200) is further in signal connection with the aboveground device (100), and the aboveground device (100) is in signal connection with the underground broadcasting device (300) and the underground communication device (400) through signal connection between the aboveground device (100) and the fusion information transmission device (200) and signal connection between the fusion information transmission device (200) and the underground broadcasting device (300) and the underground communication device (400).

2. The system of claim 1, wherein the wireless communication base station subsystem (500) comprises a 5G base station subsystem.

3. The system according to claim 2, characterized in that the control unit (510) comprises a concentration unit (511) and a distribution unit (512), the antenna unit (520) comprising an active antenna unit (521), the concentration unit (511) being in signal connection with the active antenna unit (521) via the distribution unit (512).

4. A system according to claim 3, characterized in that the 5G base station subsystem comprises more than two concentration units (511) of each of the 5G base station subsystems being arranged in a concentration, and the distribution units (512) of each of the 5G base station subsystems being arranged close to the active antenna units (521) of the 5G base station subsystem.

5. A system according to claim 3, characterized in that the concentration unit (511) and the distribution unit (512) are arranged centrally.

6. The system according to claim 1, wherein the radio communication base station subsystem (500) is further connected to a core network, and the converged information transfer device (200) accesses the core network through the radio communication base station subsystem (500).

7. The system according to claim 6, characterized in that the uphole device (100) is connected to a core network, through which the uphole device (100) is signal-connected with the fusion information transfer device (200).

8. The system of claim 1, wherein the uphole device (100) and the fusion information transfer device (200) are connected to the same local area network for signal connection through the local area network.

9. The system of claim 8, wherein the uphole device (100) and the fusion information transfer device (200) are connected by optical fibers.