CN204155435U - A kind of wireless temperature acquisition system - Google Patents

Abstract

The utility model discloses a wireless temperature acquisition system, which comprises a monitoring control system platform and a temperature acquisition subsystem connected to the monitoring control system platform; the monitoring control system platform has a monitoring computer; the temperature acquisition subsystem has at least one The temperature acquisition subsystem includes a wireless receiving terminal and 1 to 32 temperature collectors, and the wireless receiving terminal is connected to the monitoring computer in the monitoring and control system platform with an RS485 interface. The monitoring and control system platform is connected to multiple temperature acquisition subsystems. In one temperature acquisition subsystem, a wireless receiving terminal receives multiple temperature collectors wirelessly to realize remote collection of temperature information of power equipment, and can collect temperature information from different collection points. Temperature information, easy to operate, save time, timely maintenance when problems are found, fixed-point collection, and accurate data collection.

Description

A wireless temperature acquisition system

technical field

The utility model relates to the field of remote data acquisition, in particular to a wireless temperature acquisition system.

Background technique

During the power operation of the power supply system, it is necessary to monitor the temperature of the power equipment, especially the connection points of the high-voltage power equipment, the dynamic and static contacts of each knife switch, and the cable connector, so as to prevent the equipment from being damaged due to the rise of temperature. Faults affect the safe operation of the power grid. The current temperature measurement method is: the operator holds a "temperature measurement gun" to conduct patrol monitoring on the measuring points that need to be measured, and then collects and analyzes statistically on the machine to find possible problems. This monitoring method cannot achieve real-time detection at any time, and cannot detect hidden troubles in time to make warnings and forecasts. Moreover, it consumes a lot of human resources, and each inspection also takes a lot of time.

Utility model content

The purpose of the utility model is to provide a timely and convenient maintenance, accurate data collection and time-saving wireless temperature collection system.

The technical solution of the utility model is a wireless temperature acquisition system, including a monitoring control system platform and a temperature acquisition subsystem connected to the monitoring control system platform; a monitoring computer is provided in the monitoring control system platform; the temperature acquisition subsystem is at least There is 1; the temperature acquisition subsystem includes a wireless receiving terminal and 1 to 32 temperature collectors, and the wireless receiving terminal is connected to the monitoring computer in the monitoring and control system platform with an RS485 interface; the wireless receiving terminal includes a main control unit, a power processor connected to the main control unit, a wireless transceiver device and a communication circuit; the temperature collector includes a controller, a wireless transceiver module connected to the controller, a temperature sensor and a battery, and the temperature collector also includes a power manager, the power manager is connected to the power source.

The temperature sensor sends the collected temperature data information to the controller for processing, and the controller sends the processed temperature data information through the wireless transceiver module. After the wireless transceiver device receives the temperature data information, it is sent by the communication The circuit is transmitted to the monitoring computer in the monitoring and control system platform through the RS485 interface. A temperature acquisition subsystem can be connected or withdrawn from the entire monitoring system as an integral part. The temperature acquisition subsystem can be equipped with up to 32 temperature collectors. The temperature collectors transmit the temperature from the temperature monitoring point to the sub-system through wireless means The wireless receiving terminal of the system. The monitoring and control system adopts a polling method to collect the temperature data of each temperature acquisition subsystem, and the polling time is configurable. When the wireless receiving terminal receives the polling command of the monitoring and control system, it uploads the temperature information of the acquisition subsystem to the Monitor and control the system. The wireless receiving terminal transmits the temperature information of each monitoring point in the whole subsystem to the monitoring and control system platform through the RS485 network. In this technical solution, the temperature information of electric equipment can be collected remotely, and the temperature information of different collection points can be collected, which is convenient to operate, saves time, can be maintained in time when problems are found, and can be collected at fixed points, and the collected data is accurate. the

Further, the temperature collector is a box. The box body can be connected to the measured place, and its temperature sensing element is closely attached to the surface of the measured object.

Further, the operating voltage of the main control unit is 3.3V, which ensures the normal operation of the wireless receiving terminal.

Further, the main control unit adopts MSP430 series single-chip microcomputer.

Further, the power processor is externally connected with a DC12V power supply, steps down the DC12V power supply, and outputs 3.3V power supply to the main control unit.

Further, the communication circuit uses an RS485 chip, and is connected to the monitoring computer in the monitoring and control system platform through an RS485 interface. Two-stage protection is adopted on the RS485 interface. The front stage uses a patch gas discharge tube LT-B3D090L to discharge the surge current, and the latter stage uses a bidirectional transient suppression tube BS0080MS to limit the surge voltage to a relatively short time. low level. The recoverable fuse LP-MSM010 is selected as the decoupling device between the two stages.

Further, the controller adopts MSP430 series single-chip microcomputer, which has low power consumption and power saving. Three groups of DIP switches are arranged in the MSP430 series MCU. The first group of DIP switches configures the sampling time of temperature, and the configurable temperature acquisition time is 1 Minutes to 8 minutes; the second set of DIP switches is configured with wireless communication signals. In the field environment, a set of temperature acquisition subsystems can choose one of 8 wireless communication frequencies to avoid on-site wireless interference; the third set of DIP switches The number of the temperature collector where the configuration is located.

Further, the wireless transceiver module adopts CC1101 chip, and the CC1101 chip is connected with the controller through the SPI interface.

Furthermore, the temperature sensor is attached to the surface of the object to be measured, so as to accurately detect the temperature data of the detection point.

Further, the output voltage of the battery is 3.6V, so that the entire temperature collector can work normally.

Beneficial effects: the monitoring and control system platform is connected to multiple temperature acquisition subsystems. In one temperature acquisition subsystem, one wireless receiving terminal can receive multiple temperature collectors wirelessly, so as to realize remote collection of temperature information of electric equipment, and can collect different The temperature information at the collection point is easy to operate, saves time, and can be maintained in time when problems are found, and the collected data is accurate at fixed points. the

Description of drawings

Fig. 1 is a structural block diagram of an embodiment of the utility model;

Fig. 2 is a structural block diagram of the wireless receiving terminal in the utility model;

Fig. 3 is a structural block diagram of the temperature collector in the utility model.

Marks in the figure: 1- monitoring and control system platform; 2- temperature acquisition subsystem; 3- wireless receiving terminal; 4- temperature collector; 5- main control unit; 6- power processor; 7- wireless transceiver device; 8- Communication circuit; 9-controller; 10-wireless transceiver module; 11-temperature sensor; 12-battery; 13-power manager.

Detailed ways

Below in conjunction with accompanying drawing, preferred embodiment of the present utility model is described in further detail:

Referring to Fig. 1 to 3, a kind of wireless temperature acquisition system, comprises monitoring and control system platform and the temperature acquisition subsystem 2 that connects this monitoring and control system platform; There is monitoring computer in the described monitoring and control system platform; Described temperature acquisition subsystem 2 There are 3; the temperature acquisition subsystem 2 includes a wireless receiving terminal 3 and 3 temperature collectors 4, and the wireless receiving terminal 3 connects the monitoring computer in the monitoring and control system platform 1 with an RS485 interface; the wireless receiving The terminal 3 includes a main control unit 5, a power processor 6 connected to the main control unit 5, a wireless transceiver device 7 and a communication circuit 8; the temperature collector 4 includes a controller 9, a wireless transceiver module 10 connected to the controller 9 , a temperature sensor 11 and a battery 12, the temperature collector 4 also includes a power manager 13, and the power manager 13 is connected to the power source.

The temperature sensor 11 sends the collected temperature data information to the controller 9 for processing, and the controller 9 sends the processed temperature data information through the wireless transceiver module 10, and the wireless transceiver device 7 receives the temperature data information , transmitted by the communication circuit 8 to the monitoring computer in the monitoring and control system platform 1 through the RS485 interface. A temperature acquisition subsystem 2 as an integral part can be connected or withdrawn from the entire monitoring system at will, and the temperature collector 4 transmits the temperature from the temperature monitoring point to the wireless receiving terminal 3 of the subsystem through wireless means. The monitoring and control system adopts a polling method to collect the temperature data of each temperature acquisition subsystem 2, and the polling time is configurable. When the wireless receiving terminal 3 receives the polling command of the monitoring and control system, the temperature data of the temperature acquisition subsystem 2 will be The temperature information is uploaded to the monitoring and control system. The wireless receiving terminal 3 transmits the temperature information of each monitoring point in the entire temperature acquisition subsystem 2 to the monitoring and control system platform through the RS485 network. In this embodiment, the remote collection of temperature information of electric equipment can be realized, and the temperature information of different collection points can be collected, which is convenient to operate, saves time, and can be maintained in time when problems are found, fixed-point collection, and accurate data collection. the

Preferably, there are five temperature collection subsystems 2 and eight temperature collectors 4 .

Preferably, there are 8 temperature collection subsystems 2 and 30 temperature collectors 4 .

Preferably, the temperature collector 4 is a box. The box body can be connected to the measured place, and its temperature sensing element is closely attached to the surface of the measured object.

Preferably, the operating voltage of the main control unit 5 is 3.3V to ensure the normal operation of the wireless receiving terminal 3 .

Preferably, the main control unit 5 adopts MSP430 series single-chip microcomputer.

Preferably, the power processor 6 is externally connected with a DC12V power supply, steps down the DC12V power supply, and outputs 3.3V power supply to the main control unit 5 .

Preferably, the communication circuit 8 adopts an RS485 chip, and is connected to the monitoring computer in the monitoring and control system platform 1 through an RS485 interface. Two-stage protection is adopted on the RS485 interface. The front stage uses a patch gas discharge tube LT-B3D090L to discharge the surge current, and the latter stage uses a bidirectional transient suppression tube BS0080MS to limit the surge voltage to a relatively short time. low level. The recoverable fuse LP-MSM010 is selected as the decoupling device between the two stages.

Preferably, the controller 9 adopts MSP430 series single-chip microcomputer, which has low power consumption and power saving. Three sets of dial switches are arranged in the MSP430 series single-chip microcomputer. The sampling time of the first set of dial switch configuration temperature is 1 minute; the second set The DIP switches are configured with wireless communication signals. In the field environment, each group of temperature acquisition subsystems 2 can choose one of 8 wireless communication frequencies to avoid on-site wireless interference; the third group of DIP switches is configured with the temperature collector 4 number.

Preferably, the sampling time of the configuration temperature of the first set of DIP switches is 5 minutes.

Preferably, the sampling time of the configuration temperature of the first set of DIP switches is 8 minutes.

Preferably, the wireless transceiver module 10 adopts a CC1101 chip, and the CC1101 chip is connected to the controller 9 through an SPI interface.

Furthermore, the temperature sensor 11 is attached to the surface of the measured object, so as to accurately detect the temperature data of the detection point.

Further, the output voltage of the battery 12 is 3.6V, which enables the entire temperature collector 4 to work normally.

The above content is a further detailed description of the utility model in combination with specific preferred embodiments, and it cannot be assumed that the specific implementation of the utility model is only limited to these descriptions. For a person of ordinary skill in the technical field to which the utility model belongs, without departing from the concept of the utility model, some simple deduction or substitutions can also be made, which should be regarded as belonging to the protection scope of the utility model.

Claims (10)

1. a wireless temperature acquisition system, is characterized in that: comprise supervisor control platform and the temperature acquisition subsystem being connected this supervisor control platform; Monitoring computer is had in described supervisor control platform; Described temperature acquisition subsystem has 1 at least; Described temperature acquisition subsystem comprises radio receiving terminal and 1 to 32 Temperature samplers, and described radio receiving terminal RS485 interface connects the monitoring computer in described supervision regulator control system platform; Described radio receiving terminal comprises main control unit, connects the power processor of this main control unit, wireless transmitter and communicating circuit; Described Temperature sampler comprises controller, connects the radio receiving transmitting module of this controller, temperature sensor and battery, and described Temperature sampler also comprises power supervisor, and described power supervisor connects described power supply.

2. wireless temperature acquisition system according to claim 1, is characterized in that: described Temperature sampler is box body.

3. wireless temperature acquisition system according to claim 1 and 2, is characterized in that: the operating voltage of described main control unit is 3.3V.

4. wireless temperature acquisition system according to claim 3, is characterized in that: described main control unit adopts MSP430 series monolithic.

5. wireless temperature acquisition system according to claim 4, is characterized in that: the external DC12V power supply of described power processor.

6. wireless temperature acquisition system according to claim 5, is characterized in that: described communicating circuit adopts RS485 chip, connects the monitoring computer in described supervision regulator control system platform with RS485 interface.

7. wireless temperature acquisition system according to claim 6, it is characterized in that: described controller adopts MSP430 series monolithic, three groups of toggle switchs are provided with in this MSP430 series monolithic, the sampling time of first group of toggle switch configuration temperature, second group of toggle switch configuration communication signal, the numbering of the 3rd group of toggle switch configuration place Temperature sampler.

8. wireless temperature acquisition system according to claim 7, is characterized in that: radio receiving transmitting module adopts CC1101 chip, and this CC1101 chip is connected by SPI Interface and Controler.

9. wireless temperature acquisition system according to claim 8, is characterized in that: temperature sensor is attached to measured object surface.

10. wireless temperature acquisition system according to claim 9, is characterized in that: the output voltage of described battery is 3.6V.