CN214410260U - Flow pressure integration transmission terminal based on NBIOT communication technology - Google Patents

Abstract

The utility model provides a flow pressure integration transmission terminal based on NBIOT communication technology, it relates to flow pressure transmission technical field, it includes data control module, communication module, terminal module, data acquisition module, mobile client, data control module is connected with communication module, communication module connection terminal module, terminal module is connected with mobile client through data acquisition module, it sets up on terminal module to remove NB communication module, remove NB communication module and connect NB antenna interface and thing networking sim card, infrared configuration mouth and embedded little consumption treater interconnect, the beneficial effects of the utility model are that: the system has the advantages that multiple sampling modes such as the pressure sensor and the flowmeter are realized under the condition of ensuring the communication quality, the equipment can realize remote transmission by reducing the standby power consumption, the acquisition power consumption and the communication power consumption of the equipment, the system has a real-time data internet of things function, and the NB-IOT base stations are numerous in number, so that more places for deployment are realized, and the data transmission is more timely and reliable.

Description

Flow pressure integration transmission terminal based on NBIOT communication technology

Technical Field

The utility model relates to a flow pressure transmission technical field, concretely relates to flow pressure integration transmission terminal based on NBIOT communication technology.

Background

At present, pipe network pressure monitoring and flow equipment in the market generally has the following characteristics that firstly, the pipe network is wide in distribution area, buried underground, difficult in power supply and the like, so that equipment for pipe network pressure monitoring needs to be powered by a battery and has a wireless communication function, the pipe network pressure monitoring in the market generally realizes wireless transmission by LORa (radio over fiber) or GPRS (general packet radio service) communication or 4G communication, and the LORa is applied to a local area network and can realize a data forwarding platform by forwarding through a concentrator; is unique in safety; in the future development trend of GPRS, multi-terminal connection cannot be realized; the data sending quantity is limited until the network is exited; 4G communication is a good choice; however, the power supply power consumption of the lithium battery is large, the NB-IoT wireless pipe network pressure monitoring device has the characteristic of low power consumption and the capability of remote transmission, and the lithium battery which supplies power for a long time.

Various pressure terminals on the market at present are old-fashioned meters which display pressure and flow and have no remote communication function; the conditions of water flow change and pressure cannot be seen in real time, and the user needs to go to the site every time the meter is read; the flow data and the pressure data of the statistical table are not real-time data every day, more manpower is needed, the statistical workload is large, and the change of the water flow and the pressure change data cannot be intuitively sensed; the statistical period is long, the existing pressure sensor adopts various sampling modes such as a voltage type pressure sensor, a current type pressure sensor, an RS-485 communication flowmeter and the like, is applied to different occasions, and is inconvenient because each pressure sensor needs to replace a corresponding mainboard to replace a corresponding related sensor.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to be not enough and the defect among the prior art, a flow pressure integration transmission terminal based on NBIOT communication technology is provided, can realize multiple sampling methods such as pressure sensor, flowmeter under the circumstances of guaranteeing communication quality, and let equipment can realize remote transmission through reducing equipment stand-by power consumption, the collection consumption, communication consumption, and have the real-time data thing allies oneself with the function, and the quantity of NB-IOT basic station is numerous, thereby realize that the place of deployment is more, data transmission is more timely reliable.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a flow and pressure integrated transmission terminal based on an NBIOT communication technology comprises a data control module 1, a communication module 2, a terminal module 3, a data acquisition module 4 and a mobile client 5, wherein the data control module 1 is connected with the communication module 2, the communication module 2 is connected with the terminal module 3, the terminal module 3 is connected with the mobile client 5 through the data acquisition module 4, the terminal module 3 comprises a magnetic control switch tube 31, a storage module 32, an indicator lamp 33, an infrared configuration port 34, an embedded micro-power consumption processor 35, an NB antenna interface 36, a mobile NB communication module 37, an Internet of things sim card 38, a voltage type pressure sampling module interface 39, a communication module interface 310, a first wire outlet 311, a current type pressure sampling module interface 312, a power supply input interface 313 and a second wire outlet 314, the mobile NB communication module 37 is arranged on the terminal module 3, the mobile NB communication module 37 is connected with an NB antenna interface 36 and an Internet of things sim card 38, the infrared configuration port 34 is connected with the embedded micro-power consumption processor 35 and the mobile NB communication module 37, the storage module 32 and the indicator lamp 33 are connected on the embedded micro-power consumption processor 35, the communication module interface 310 is connected with the embedded micro-power consumption processor 35 through the magnetic control switch tube 31, the voltage type pressure sampling module interface 39 is connected with the embedded micro-power consumption processor 35, the power input interface 313 is connected with the current type pressure sampling module interface 312, the current type pressure sampling module interface 312 is connected with the embedded micro-power consumption processor 35 and the mobile NB communication module 37, and the terminal module 3 is provided with a first outlet hole 311 and a second outlet hole 314.

Furthermore, the terminal module 3 is provided with a fixing through hole 315, which facilitates the fixing and installation of the terminal module 3.

Further, the communication module interface 310 is an RS-485 communication interface.

Further, the first wire outlet 311 is a power line and module wire outlet, and the second wire outlet 314 is an NB antenna outlet.

The utility model discloses a theory of operation: when the device is installed and used, a worker can connect a pressure sensor, a flowmeter and the like of the device to the terminal module 3 through the voltage type pressure sampling module interface 39 and the current type pressure sampling module interface 312, install a sim card on the sim card 38 of the internet of things to enable the terminal module 3 to have the function of the internet of things, connect relevant connectors to the NB antenna interface 36, the communication module interface 310 and the power input interface 313 of the terminal module 3 to enable the terminal module 3 to work normally, when the device is used, the worker can drive the communication module 2 through the data control module 1 to enable the communication module 2 to send instructions to the mobile NB communication module 37, and then the mobile NB communication module 37 can process data obtained by the voltage type pressure sampling module interface 39 and the current type pressure sampling module interface 312 through the embedded micro-power consumption processor 35, then the data are sent to the data acquisition module 4 through the mobile NB communication module 37, and the staff can check the data through the mobile client 5.

After the technical scheme is adopted, the utility model discloses beneficial effect does: the system has the advantages that multiple sampling modes such as the pressure sensor and the flowmeter are realized under the condition of ensuring the communication quality, the equipment can realize remote transmission by reducing the standby power consumption, the acquisition power consumption and the communication power consumption of the equipment, the system has a real-time data internet of things function, and the NB-IOT base stations are numerous in number, so that more places for deployment are realized, and the data transmission is more timely and reliable.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a block flow diagram of the present invention.

Fig. 2 is a schematic structural diagram of the middle terminal module 3 of the present invention.

Description of reference numerals: the system comprises a data control module 1, a communication module 2, a terminal module 3, a data acquisition module 4, a mobile client 5, a magnetic control switch tube 31, a storage module 32, an indicator light 33, an infrared configuration port 34, an embedded micro-power consumption processor 35, an NB antenna interface 36, a mobile NB communication module 37, an Internet of things sim card 38, a voltage type pressure sampling module interface 39, a communication module interface 310, a first wire outlet 311, a current type pressure sampling module interface 312, a power input interface 313, a second wire outlet 314 and a fixing through hole 315.

Detailed Description

Referring to fig. 1 to 2, the technical solution adopted by the present embodiment is: the mobile terminal comprises a data control module 1, a communication module 2, a terminal module 3, a data acquisition module 4 and a mobile client 5, wherein the data control module 1 is connected with the communication module 2, the communication module 2 is connected with the terminal module 3, the terminal module 3 is connected with the mobile client 5 through the data acquisition module 4, the terminal module 3 comprises a magnetic control switch tube 31, a storage module 32, an indicator lamp 33, an infrared configuration port 34, an embedded micro-power processor 35, an NB antenna interface 36, a mobile NB communication module 37, an Internet of things sim card 38, a voltage type pressure sampling module interface 39, a communication module interface 310, a first wire outlet 311, a current type pressure sampling module interface 312, a power input interface 313 and a second wire outlet 314, the mobile NB communication module 37 is arranged on the terminal module 3, and the mobile NB communication module 37 is connected with the NB antenna interface 36 and the Internet of things sim card 38, the infrared configuration port 34 is connected with the embedded micro power consumption processor 35, the infrared configuration port 34 is connected with the embedded micro power consumption processor 35 and the mobile NB communication module 37, the storage module 32 and the indicator lamp 33 are connected with the embedded micro power consumption processor 35, the communication module interface 310 is connected with the embedded micro power consumption processor 35 through the magnetic control switch tube 31, the voltage type pressure sampling module interface 39 is connected with the embedded micro power consumption processor 35, the power input interface 313 is connected with the current type pressure sampling module interface 312, the current type pressure sampling module interface 312 is connected with the embedded micro power consumption processor 35 and the mobile NB communication module 37, and the terminal module 3 is provided with a first wire outlet 311 and a second wire outlet 314.

The terminal module 3 is provided with a fixing through hole 315, so that the terminal module 3 can be conveniently and fixedly mounted, the communication module interface 310 is an RS-485 communication interface, the first wire outlet 311 is a power line and module wire outlet, and the second wire outlet 314 is an NB antenna wire outlet.

The utility model discloses a theory of operation: when the device is installed and used, a worker can connect a pressure sensor, a flowmeter and the like of the device to the terminal module 3 through the voltage type pressure sampling module interface 39 and the current type pressure sampling module interface 312, install a sim card on the sim card 38 of the internet of things to enable the terminal module 3 to have the function of the internet of things, connect relevant connectors to the NB antenna interface 36, the communication module interface 310 and the power input interface 313 of the terminal module 3 to enable the terminal module 3 to work normally, when the device is used, the worker can drive the communication module 2 through the data control module 1 to enable the communication module 2 to send instructions to the mobile NB communication module 37, and then the mobile NB communication module 37 can process data obtained by the voltage type pressure sampling module interface 39 and the current type pressure sampling module interface 312 through the embedded micro-power consumption processor 35, then the data are sent to the data acquisition module 4 through the mobile NB communication module 37, and the staff can check the data through the mobile client 5.

The above description is only for the purpose of illustrating the technical solutions of the present invention and not for the purpose of limiting the same, and other modifications or equivalent replacements made by those of ordinary skill in the art to the technical solutions of the present invention should be covered within the scope of the claims of the present invention as long as they do not depart from the spirit and scope of the technical solutions of the present invention.

Claims (4)

1. A flow pressure integration transmission terminal based on NBIOT communication technology is characterized in that: the mobile client comprises a data control module (1), a communication module (2), a terminal module (3), a data acquisition module (4) and a mobile client (5), wherein the data control module (1) is connected with the communication module (2), the communication module (2) is connected with the terminal module (3), and the terminal module (3) is connected with the mobile client (5) through the data acquisition module (4);

the terminal module (3) comprises a magnetic control switch tube (31), a storage module (32), an indicator lamp (33), an infrared configuration port (34), an embedded micro-power consumption processor (35), an NB antenna interface (36), a mobile NB communication module (37), an Internet of things sim card (38), a voltage type pressure sampling module interface (39), a communication module interface (310), a first wire outlet (311), a current type pressure sampling module interface (312), a power input interface (313) and a second wire outlet (314), the mobile NB communication module (37) is arranged on the terminal module (3), the mobile NB communication module (37) is connected with the NB antenna interface (36) and the Internet of things sim card (38), the infrared configuration port (34) is connected with the embedded micro-power consumption processor (35), and the infrared configuration port (34) is connected with the embedded micro-power consumption processor (35) and the mobile NB communication module (37), the storage module (32) and the indicator lamp (33) are connected to the embedded micro power consumption processor (35), the communication module interface (310) is connected with the embedded micro power consumption processor (35) through the magnetic control switch tube (31), the voltage type pressure sampling module interface (39) is connected with the embedded micro power consumption processor (35), the power input interface (313) is connected with the current type pressure sampling module interface (312), the current type pressure sampling module interface (312) is connected with the embedded micro power consumption processor (35) and the mobile NB communication module (37), and the terminal module (3) is provided with a first wire outlet (311) and a second wire outlet (314).

2. The NBIOT communication technology-based flow and pressure integrated transmission terminal of claim 1, wherein: and a fixing through hole (315) is formed in the terminal module (3).

3. The NBIOT communication technology-based flow and pressure integrated transmission terminal of claim 1, wherein: the communication module interface (310) is an RS-485 communication interface.

4. The NBIOT communication technology-based flow and pressure integrated transmission terminal of claim 1, wherein: the first wire outlet hole (311) is a power line and module wire outlet hole, and the second wire outlet hole (314) is an NB antenna wire outlet hole.

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