CN104776929A - Low-power-consumption self-organization temperature data acquisition method, system and mounting and debugging method thereof - Google Patents
Low-power-consumption self-organization temperature data acquisition method, system and mounting and debugging method thereof Download PDFInfo
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Abstract
The invention belongs to the technical field of Internet of Things communication equipment, in particular relates to a low-power-consumption self-organization temperature data acquisition method, system and a mounting and debugging method thereof, and solves the problems that conventional heating radiator temperature information cannot be conveniently acquired and the like. The system comprises a plurality of temperature acquisition nodes with heating radiator temperature sensors and ambient temperature sensors, wherein the temperature acquisition nodes are networked through first RF modules, interacted through information, and respectively connected with at least one main computer; each main computer is connected with a debugging maintainer through a second RF module; the main computers are connected with at least one upper computer through GPRS communication modules. The system has the advantages that the structure is simple, the stability is good, the nodes can be networked, one main computer can be simultaneously combined with a plurality of nodes, the cost is low, the system is convenient to mount and maintain, and the temperature information of a plurality groups of heating radiators can be simultaneously acquired.
Description
Technical field
The invention belongs to Internet of Things technical field of communication equipment, especially relate to a kind of low-power consumption self-organization temperature data acquisition method, system and Installation and Debugging method thereof.
Background technology
Along with the idea of energy-conserving and environment-protective is rooted in the hearts of the people, everybody is for energy-conservation more and more attention, such as adopt the mode of central heating in the north in winter of cold more, one family is provided with multiple radiator usually, in order to improve energy-saving effect, need during use detect each radiator and environment temperature in time thus carry out temperature adjustment according to actual conditions to each radiator, but because the warm braw sheet quantity in Dan Donglou is more, it is very inconvenient that this just makes the detection of the environment temperature in the temperature of the radiator in entire building and each family, so just cause user cannot obtain the duty of indoor environment temperature and radiator reality in time, greatly have impact on energy-saving effect when radiator uses, in addition, existing warm braw sheet temperature acquisition system also also exists: I&M difficulty is large, high in cost of production problem.
In order to solve prior art Problems existing, people have carried out long-term exploration, propose solution miscellaneous.Such as, Chinese patent literature discloses a kind of intelligent controlling device [application number: 201210459746.X] for controlling radiator, radiator supervisor arranges solenoid valve, described solenoid valve is connected electrically on single-chip microcomputer, described single-chip microcomputer arranges wireless transport module, described single-chip microcomputer is electrically connected with indoor temperature sensor, the temperature of the indoor of temperature sensor measurement is passed through wireless transport module by described single-chip microcomputer, be transferred to control terminal, described control terminal is according to the temperature of transmission, by Micro Controller Unit (MCU) driving solenoid valve adjustment radiator in enter the water yield.Such scheme to some extent solves the problem that existing warm braw sheet temperature information gathers inconvenience, but the program still fundamentally cannot solve poor stability, cannot gather multiple warm braw sheet temperature information, cost is high, the problem that I&M difficulty is large simultaneously.
Summary of the invention
The object of the invention is for the problems referred to above, provide a kind of simple and reasonable, the low-power consumption self-organization temperature data collecting system of good stability.
Another object of the present invention is for the problems referred to above, provides one to be convenient to install, the Installation and Debugging method of low-power consumption self-organization temperature data collecting system easy to maintenance.
Another object of the present invention is for the problems referred to above, provides a kind of easy to operate, can gather the low-power consumption self-organization temperature data acquisition method of multiple warm braw sheet and environment temperature simultaneously.
For achieving the above object, present invention employs following technical proposal: this low-power consumption self-organization temperature data collecting system, it is characterized in that, native system comprises some temperature acquisition nodes with warm braw sheet temperature sensor and environment temperature sensor, each temperature acquisition node passes through a RF network module and information interaction is also connected with at least one main frame respectively, each main frame is all connected with debugging maintenance device by the 2nd RF module, and described main frame is connected with at least one host computer by GPRS communication module.Obviously, here temperature acquisition node can networking and carry out information interaction and be connected with at least one main frame mutually, make to carry out multiple temperature acquisition node temperature information simultaneously, making like this between temperature acquisition node can route mutually, the requirement to node transmitted power can be reduced, reduce node energy consumption, main frame, by using GPRS mode uploading data, makes whole system good stability.
In above-mentioned low-power consumption self-organization temperature data collecting system, described main frame comprises data acquisition module, described data acquisition module is connected with the data acquisition main control chip be connected with GPRS communication module, described data acquisition main control chip is connected with host supplying power battery, and each temperature acquisition node is connected with data acquisition module or data acquisition main control chip respectively by a RF module; Described data acquisition main control chip is connected with at least one LED display module and some first buttons.Temperature acquisition node can be selected to be connected with data acquisition module or data acquisition main control chip to make good stability according to actual conditions, and LED display module is here preferably red, green, yellow three pilot lamp.
In above-mentioned low-power consumption self-organization temperature data collecting system, described temperature acquisition node comprises the MSP430 single-chip microcomputer be connected with a RF module respectively, described MSP430 single-chip microcomputer is connected with node supplying cell, and described warm braw sheet temperature sensor is connected with MSP430 single-chip microcomputer respectively with environment temperature sensor, described MSP430 single-chip microcomputer is also connected with at least one LCD MODULE and some second buttons.Namely warm braw sheet temperature sensor is here for gathering the temperature information on warm braw sheet, and environment temperature sensor, for gathering indoor environment temperature information, makes duty and the indoor temperature state that can gather warm braw sheet in time like this.
In above-mentioned low-power consumption self-organization temperature data collecting system, described debugging maintenance device comprises the MCU chip be connected with the 2nd RF module, and described MCU chip is connected with control terminal; Described control terminal is any one in panel computer, PC, handheld device and mobile phone; Described MCU chip is also connected with Bluetooth chip or USB chip; A described RF module and the 2nd RF module are CC1100E chip.Namely when control terminal be panel computer and PC time, MCU chip is connected with USB chip, when control terminal be handheld device and mobile phone time, MCU chip is connected with Bluetooth chip, and CC1100E chip to have receiving sensitivity high, advantage low in energy consumption.
The Installation and Debugging method of above-mentioned low-power consumption self-organization temperature data collecting system is as described below: the Installation and Debugging method of low-power consumption self-organization temperature data collecting system, it is characterized in that, this method comprises the steps:
A, paired device: first make temperature acquisition node enter pairing mode, waiting status is matched in now LCD MODULE display accordingly, by temperature acquisition node placement in the scope of distance 5 meters, main frame, then by the first button, main frame started shooting by short and start pairing, after this temperature acquisition node has matched, the LED display module green light flicker of main frame once, repeats above process until need the temperature acquisition node of pairing all to complete;
B, erecting equipment: length makes LED display module red light start flicker for 3 seconds by the first button, main frame enters Installation Modes, opening debugging maintenance device makes it enter Installation Modes, by the temperature acquisition node placement of successful matching to installable diverse location, check the signal condition information that the control terminal of debugging maintenance device shows, select best signal quality position as the installation site of temperature acquisition node, repeat above process, until install;
C, startup optimization: after all temperature acquisition node installations complete, debugging maintenance device is used to connect main frame, check whether all temperature acquisition nodes are all connected to main frame, unnecessary temperature acquisition node is deleted, then length presses the first button 3 seconds, when LED display module flashing yellow lamp, then represents that main frame carries out initial configuration, when LED display module green light can start to glimmer at a slow speed, then represent that main frame enters normal work.
Obviously, this process simplify the installation of temperature acquisition node and main frame, ensure that the accuracy of temperature acquisition node and host matching, make the Installation and Debugging of whole system very easy with maintenance, can installation cost be saved, reduce and install and maintenance difficulties.
In the Installation and Debugging method of above-mentioned low-power consumption self-organization temperature data collecting system, when temperature acquisition node and main frame match in described steps A, in the same time, ensure only have a temperature acquisition node and be in pairing state.Cause confusion when preventing multiple temperature acquisition node from matching with main frame simultaneously.
In the Installation and Debugging method of above-mentioned low-power consumption self-organization temperature data collecting system, unnecessary temperature acquisition knot removal is comprised the following steps in step C: again shortly by the first button, main frame and temperature acquisition node are cancelled to match, and cancel pairing demand fulfillment main frame all there is unpaired message with temperature acquisition node just can be successfully.Can prevent the Information Monitoring of temperature acquisition node from but cannot deliver to main frame by the temperature acquisition node of Delete superfluous, avoid the wasting of resources, also can adjust the quantity of the temperature acquisition node of host matching simultaneously, be conducive to improving main frame stability.
The temperature data acquisition method of above-mentioned low-power consumption self-organization temperature data collecting system is as described below: low-power consumption self-organization temperature data acquisition method, it is characterized in that, this method comprises the steps:
Temperature data information and the ambient temperature data information of warm braw sheet is gathered respectively by the warm braw sheet temperature sensor on temperature acquisition node and environment temperature sensor, each temperature acquisition node is by a RF network module and information interaction the temperature data information of the warm braw sheet of collection and ambient temperature data information are sent to main frame by a RF module, main frame is had by the 2nd RF model calling can the debugging maintenance device of mesh information between displays temperature acquisition node and main frame connection status and temperature acquisition node, the temperature data information of warm braw sheet and ambient temperature data information are uploaded to host computer by GPRS communication module by main frame.
Namely temperature data information and the ambient temperature data information of warm braw sheet is gathered by temperature acquisition node, multiple temperature acquisition node can networking and carry out information interaction and be connected with at least one main frame mutually, make to carry out multiple temperature acquisition node temperature infomation detection simultaneously, making like this between temperature acquisition node can route mutually, the requirement to node transmitted power can be reduced, reduce node energy consumption.
In above-mentioned low-power consumption self-organization temperature data acquisition method, described main frame comprises data acquisition module, described data acquisition module is connected with the data acquisition main control chip be connected with GPRS communication module, described data acquisition main control chip is connected with host supplying power battery, and each temperature acquisition node is connected with data acquisition module or data acquisition main control chip respectively by a RF module; Described temperature acquisition node comprises the MSP430 single-chip microcomputer be connected with a RF module respectively, and described MSP430 single-chip microcomputer is connected with node supplying cell, and described warm braw sheet temperature sensor is connected with MSP430 single-chip microcomputer respectively with environment temperature sensor; Described debugging maintenance device comprises the MCU chip be connected with the 2nd RF module, and described MCU chip is connected with control terminal.
In above-mentioned low-power consumption self-organization temperature data acquisition method, a described RF module and the 2nd RF module are CC1100E chip.It is high that CC1100E chip has receiving sensitivity, advantage low in energy consumption.
Compared with prior art, the advantage of this low-power consumption self-organization temperature data acquisition method, system and Installation and Debugging method thereof is: structure is simple, good stability, networking can be carried out between node, and a main frame can combine with multiple node simultaneously, cost is low, convenient for installation and maintenance, can gather many group warm braw sheet temperature informations simultaneously.
Accompanying drawing explanation
Fig. 1 is the structural representation of the embodiment of the present invention one.
Fig. 2 is the structured flowchart of temperature acquisition node in the embodiment of the present invention one.
Fig. 3 is the structured flowchart of main frame in the embodiment of the present invention one.
Fig. 4 is the structured flowchart of debugging maintenance device in the embodiment of the present invention one.
Fig. 5 is the structured flowchart of debugging maintenance device in the embodiment of the present invention two.
In figure, temperature acquisition node 1, a RF module 11, MSP430 single-chip microcomputer 12, warm braw sheet temperature sensor 13, environment temperature sensor 14, node supplying cell 15, LCD MODULE 16, first button 17, main frame 2, data acquisition module 21, data acquisition main control chip 22, GPRS communication module 23, host supplying power battery 24, LED display module 25, second button 26, debugging maintenance device 3, the 2nd RF module 31, MCU chip 32, control terminal 33, Bluetooth chip 34, USB chip 35, host computer 4.
Embodiment
Below in conjunction with the drawings and specific embodiments, the present invention will be further described in detail.
Embodiment one
As Figure 1-4, this low-power consumption self-organization temperature data collecting system, comprise some temperature acquisition nodes 1 with warm braw sheet temperature sensor 13 and environment temperature sensor 14, each temperature acquisition node 1 passes through RF module 11 networking and information interaction is also connected with at least one main frame 2 respectively, each main frame 2 is all connected with debugging maintenance device 3 by the 2nd RF module 31, and main frame 2 is connected with at least one host computer 4 by GPRS communication module 23, here temperature acquisition node 1 can networking and carry out information interaction and be connected with at least one main frame 2 mutually, make to carry out multiple temperature acquisition node 1 temperature information simultaneously, making like this between temperature acquisition node 1 can route mutually, the requirement to node transmitted power can be reduced, reduce node energy consumption, main frame 2 is by using GPRS mode uploading data, make whole system good stability.
Particularly, main frame 2 in the present embodiment comprises data acquisition module 21, data acquisition module 21 is connected with the data acquisition main control chip 22 be connected with GPRS communication module 23, data acquisition main control chip 22 is connected with host supplying power battery 24, and each temperature acquisition node 1 is connected with data acquisition module 21 or data acquisition main control chip 22 respectively by a RF module 11; Data acquisition main control chip 22 is connected with at least one LED display module 25 and some first buttons 26, namely the temperature acquisition node 1 in the present embodiment can be selected to be connected with data acquisition module 21 or data acquisition main control chip 22 to make good stability according to actual conditions, and LED display module 25 is here preferably red, green, yellow three pilot lamp.
Wherein, temperature acquisition node 1 in the present embodiment comprises the MSP430 single-chip microcomputer 12 be connected with a RF module 11 respectively, MSP430 single-chip microcomputer 12 is connected with node supplying cell 15, and warm braw sheet temperature sensor 13 is connected with MSP430 single-chip microcomputer 12 respectively with environment temperature sensor 14, MSP430 single-chip microcomputer 12 is also connected with at least one LCD MODULE 16 and some second buttons 17, namely warm braw sheet temperature sensor 14 is here for gathering the temperature information on warm braw sheet, environment temperature sensor 15 is for gathering indoor environment temperature information, make duty and the indoor temperature state that can gather warm braw sheet in time like this.
Further, debugging maintenance device 3 here comprises the MCU chip 32 be connected with the 2nd RF module 31, and MCU chip 32 is connected with control terminal 33; Control terminal 33 is any one in panel computer and PC; MCU chip 32 is also connected with USB chip 35; One RF module 11 and the 2nd RF module 31 are CC1100E chip, namely when control terminal 33 be panel computer and PC time, MCU chip 32 is connected with USB chip 35, and CC1100E chip to have receiving sensitivity high, advantage low in energy consumption.
The Installation and Debugging method of low-power consumption self-organization temperature data collecting system in the present embodiment, comprise the steps: A, paired device: first make temperature acquisition node 1 enter pairing mode, now LCD MODULE 16 shows and matches waiting status accordingly, temperature acquisition node 1 is placed in the scope of distance 25 meters, main frame, then by the first button 26, main frame 2 started shooting by short and start pairing, after this temperature acquisition node 1 has matched, the LED display module 25 green light flicker of main frame 2 once, repeat above process until need the temperature acquisition node 1 of pairing all to complete, B, erecting equipment: length makes LED display module 25 red light start flicker for 263 seconds by the first button, main frame 2 enters Installation Modes, opening debugging maintenance device 3 makes it enter Installation Modes, the temperature acquisition node 1 of successful matching is placed into installable diverse location, check the signal condition information that the control terminal 33 of debugging maintenance device 3 shows, select best signal quality position as the installation site of temperature acquisition node 1, repeat above process, until install, C, startup optimization: after all temperature acquisition node 1 installations, debugging maintenance device 3 is used to connect main frame 2, check whether all temperature acquisition nodes 1 are all connected to main frame 2, unnecessary temperature acquisition node 1 is deleted, then length presses the first button 263 seconds, when LED display module 25 flashing yellow lamp, then represent that main frame 2 carries out initial configuration, when LED display module 25 green light can start to glimmer at a slow speed, then represent that main frame 2 enters normal work, this process simplify the installation of temperature acquisition node 2 and main frame 1, ensure that the accuracy that temperature acquisition node 2 mates with main frame 1, make the Installation and Debugging of whole system very easy with maintenance, installation cost can be saved, reduce and install and maintenance difficulties.
Causing confusion when matching with main frame 1 to prevent multiple temperature acquisition node 2 simultaneously, when temperature acquisition node 1 and main frame 2 match in step, in the same time, ensureing only have a temperature acquisition node 1 and be in pairing state.Simultaneously, deleting unnecessary temperature acquisition node 1 in step C comprising the following steps: again shortly by the first button 26, main frame 2 and temperature acquisition node 1 are cancelled to match, and all there is unpaired message just meeting success with temperature acquisition node 1 in cancellation pairing demand fulfillment main frame 2, can prevent temperature acquisition node 2 Information Monitoring from but cannot deliver to main frame 1 by the temperature acquisition node 2 of Delete superfluous like this, avoid the wasting of resources, also can adjust the quantity of the temperature acquisition node that main frame 1 mates simultaneously, be conducive to improving main frame 1 stability.
The temperature data acquisition method of the low-power consumption self-organization temperature data collecting system in the present embodiment, comprise the steps: the temperature data information and the ambient temperature data information that are gathered warm braw sheet by the warm braw sheet temperature sensor 13 on temperature acquisition node 1 and environment temperature sensor 14 respectively, each temperature acquisition node 1 is by RF module 11 networking and information interaction the temperature data information of the warm braw sheet of collection and ambient temperature data information are sent to main frame 2 by a RF module 11, main frame 2 is connected with by the 2nd RF module 31 can the debugging maintenance device 3 of mesh information between displays temperature acquisition node 1 and main frame 2 connection status and temperature acquisition node 1, the temperature data information of warm braw sheet and ambient temperature data information are uploaded to host computer 4 by GPRS communication module 23 by main frame 2, namely temperature data information and the ambient temperature data information of warm braw sheet is gathered by temperature acquisition node 2, multiple temperature acquisition node 2 can networking and carry out information interaction and be connected with at least one main frame 1 mutually, make to carry out the collection of multiple temperature acquisition node 2 temperature information simultaneously, making like this between temperature acquisition node 2 can route mutually, the requirement to node transmitted power can be reduced, reduce node energy consumption.
Wherein, main frame 2 in this method comprises data acquisition module 21, described data acquisition module 21 is connected with the data acquisition main control chip 22 be connected with GPRS communication module 23, described data acquisition main control chip 22 is connected with host supplying power battery 24, and each temperature acquisition node 1 is connected with data acquisition module 21 or data acquisition main control chip 22 respectively by a RF module 11; Described temperature acquisition node 1 comprises the MSP430 single-chip microcomputer 12 be connected with a RF module 11 respectively, described MSP430 single-chip microcomputer 12 is connected with node supplying cell 15, and described warm braw sheet temperature sensor 13 is connected with MSP430 single-chip microcomputer 12 respectively with environment temperature sensor 14; Described debugging maintenance device 3 comprises the MCU chip 32 be connected with the 2nd RF module 31, and described MCU chip 32 is connected with control terminal 33.One RF module 11 and the 2nd RF module 31 are CC1100E chip.
Embodiment two
As shown in Figure 5, the structure & working mechanism of the present embodiment is substantially identical with embodiment one, and difference is, in the present embodiment, when control terminal 33 be handheld device and mobile phone time, MCU chip 32 is connected with Bluetooth chip 34.
Specific embodiment described herein is only to the explanation for example of the present invention's spirit.Those skilled in the art can make various amendment or supplement or adopt similar mode to substitute to described specific embodiment, but can't depart from spirit of the present invention or surmount the scope that appended claims defines.
Although more employ temperature acquisition node 1 herein, one RF module 11, MSP430 single-chip microcomputer 12, warm braw sheet temperature sensor 13, environment temperature sensor 14, node supplying cell 15, LCD MODULE 16, first button 17, main frame 2, data acquisition module 21, data acquisition main control chip 22, GPRS communication module 23, host supplying power battery 24, LED display module 25, second button 26, debugging maintenance device 3, 2nd RF module 31, MCU chip 32, control terminal 33, Bluetooth chip 34, USB chip 35, term such as host computer 4 grade, but do not get rid of the possibility using other term.These terms are used to be only used to describe and explain essence of the present invention more easily; The restriction that they are construed to any one additional is all contrary with spirit of the present invention.
Claims (10)
1. a low-power consumption self-organization temperature data collecting system, it is characterized in that, native system comprises some temperature acquisition nodes (1) with warm braw sheet temperature sensor (13) and environment temperature sensor (14), each temperature acquisition node (1) is by RF module (11) networking and information interaction being connected with at least one main frame (2) respectively, each main frame (2) is all connected with debugging maintenance device (3) by the 2nd RF module (31), and described main frame (2) is connected with at least one host computer (4) by GPRS communication module (23).
2. low-power consumption self-organization temperature data collecting system according to claim 1, it is characterized in that, described main frame (2) comprises data acquisition module (21), described data acquisition module (21) is connected with the data acquisition main control chip (22) be connected with GPRS communication module (23), described data acquisition main control chip (22) is connected with host supplying power battery (24), and each temperature acquisition node (1) is connected with data acquisition module (21) or data acquisition main control chip (22) respectively by a RF module (11), described data acquisition main control chip (22) is connected with at least one LED display module (25) and some first buttons (26).
3. low-power consumption self-organization temperature data collecting system according to claim 2, it is characterized in that, described temperature acquisition node (1) comprises the MSP430 single-chip microcomputer (12) be connected with a RF module (11) respectively, described MSP430 single-chip microcomputer (12) is connected with node supplying cell (15), and described warm braw sheet temperature sensor (13) is connected with MSP430 single-chip microcomputer (12) respectively with environment temperature sensor (14), described MSP430 single-chip microcomputer (12) is also connected with at least one LCD MODULE (16) and some second buttons (17).
4. low-power consumption self-organization temperature data collecting system according to claim 3, it is characterized in that, described debugging maintenance device (3) comprises the MCU chip (32) be connected with the 2nd RF module (31), and described MCU chip (32) is connected with control terminal (33); Described control terminal (33) is panel computer, any one in PC, handheld device and mobile phone; Described MCU chip (32) is also connected with Bluetooth chip (34) or USB chip (35); A described RF module (11) and the 2nd RF module (31) are CC1100E chip.
5. an Installation and Debugging method for the low-power consumption self-organization temperature data collecting system described in claim 4, it is characterized in that, this method comprises the steps:
A, paired device: first make temperature acquisition node (1) enter pairing mode, waiting status is matched in now LCD MODULE (16) display accordingly, temperature acquisition node (1) is placed in the scope of distance (2) 5 meters, main frame, then by the first button (26), main frame (2) started shooting by short and start pairing, after this temperature acquisition node (1) has matched, LED display module (25) the green light flicker of main frame (2) once, repeats above process until need the temperature acquisition node (1) of pairing all to complete;
B, erecting equipment: length makes LED display module (25) red light start flicker for (26) 3 seconds by the first button, main frame (2) enters Installation Modes, opening debugging maintenance device (3) makes it enter Installation Modes, the temperature acquisition node (1) of successful matching is placed into installable diverse location, check the signal condition information of the upper display of the control terminal (33) of debugging maintenance device (3), select best signal quality position as the installation site of temperature acquisition node (1), repeat above process, until install;
C, startup optimization: after all temperature acquisition node (1) installations, debugging maintenance device (3) is used to connect main frame (2), check whether all temperature acquisition nodes (1) are all connected to main frame (2), unnecessary temperature acquisition node (1) is deleted, then length presses the first button (26) 3 seconds, when LED display module (25) flashing yellow lamp, then represent that main frame (2) carries out initial configuration, when LED display module (25) green light can start to glimmer at a slow speed, then represent that main frame (2) enters normal work.
6. the Installation and Debugging method of low-power consumption self-organization temperature data collecting system according to claim 5, it is characterized in that, when temperature acquisition node (1) and main frame (2) match in described steps A, in the same time, ensure only have a temperature acquisition node (1) and be in pairing state.
7. the Installation and Debugging method of low-power consumption self-organization temperature data collecting system according to claim 1, it is characterized in that, the deletion of unnecessary temperature acquisition node (1) is comprised the following steps in step C: again shortly by the first button (26), main frame (2) and temperature acquisition node (1) are cancelled match, and cancel pairing demand fulfillment main frame (2) and all there is unpaired message with temperature acquisition node (1) just meeting is successful.
8. a temperature data acquisition method for the low-power consumption self-organization temperature data collecting system described in claim 1-4 any one, it is characterized in that, this method comprises the steps:
Temperature data information and the ambient temperature data information of warm braw sheet is gathered respectively by the warm braw sheet temperature sensor (13) on temperature acquisition node (1) and environment temperature sensor (14), each temperature acquisition node (1) is by RF module (11) networking and the temperature data information of the warm braw sheet of collection and ambient temperature data information are also sent to main frame (2) by a RF module (11) by information interaction, main frame (2) is connected with by the 2nd RF module (31) can displays temperature acquisition node (1) and the debugging maintenance device (3) of mesh information between main frame (2) connection status and temperature acquisition node (1), the temperature data information of warm braw sheet and ambient temperature data information are uploaded to host computer (4) by GPRS communication module (23) by main frame (2).
9. low-power consumption self-organization temperature data acquisition method according to claim 8, it is characterized in that, described main frame (2) comprises data acquisition module (21), described data acquisition module (21) is connected with the data acquisition main control chip (22) be connected with GPRS communication module (23), described data acquisition main control chip (22) is connected with host supplying power battery (24), and each temperature acquisition node (1) is connected with data acquisition module (21) or data acquisition main control chip (22) respectively by a RF module (11), described temperature acquisition node (1) comprises the MSP430 single-chip microcomputer (12) be connected with a RF module (11) respectively, described MSP430 single-chip microcomputer (12) is connected with node supplying cell (15), and described warm braw sheet temperature sensor (13) is connected with MSP430 single-chip microcomputer (12) respectively with environment temperature sensor (14), described debugging maintenance device (3) comprises the MCU chip (32) be connected with the 2nd RF module (31), and described MCU chip (32) is connected with control terminal (33).
10. low-power consumption self-organization temperature data acquisition method according to claim 9, is characterized in that, a described RF module (11) and the 2nd RF module (31) are CC1100E chip.
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