CN109658661B - Monitoring system and implementation method thereof - Google Patents

Abstract

The invention discloses a supervisory system and a realization method thereof, and the system comprises: the system comprises a granary management information system, each granary information transceiving control terminal, a granary temperature and humidity monitoring unit, an excitation/charging source module and corresponding cooling, dehumidifying and ventilating equipment; the information receiving and transmitting control terminal of each granary is connected with a granary management information system through a communication network, connected with cooling, dehumidifying and ventilating equipment through control signals, connected with a granary temperature and humidity monitoring unit in the same granary in a high-frequency wireless mode, and connected with an excitation/charging source module in the same granary in a wireless or wired mode; the excitation/charging source module is connected with a granary temperature and humidity monitoring unit in the same cabin in a low-frequency wireless mode. The method is characterized in that when the time period is the turning time period, the turning quality is judged according to the proportion of the sum of the quantity of output information sent out from the time period setting to the current of the granary temperature and humidity monitoring units put into the granary to the total quantity of the granary temperature and humidity monitoring units set in the granary.

Description

Monitoring system and implementation method thereof

Technical Field

The invention belongs to the technical field of granary safety, and particularly relates to a monitoring system of a granary and an implementation method thereof.

Background

As is well known, the storage of grains is easily affected by temperature, humidity and other factors, and may cause problems such as heat generation, mildew, insect pest breeding, etc. In order to reduce loss in the grain storage process and guarantee the quality of grains, the granary monitoring and management system takes corresponding measures according to the specific conditions that the sensing device of the end node monitors the temperature and the humidity of the grains in the uploaded granary, and carries out cooling, moisture removal or turning over treatment. At present, a granary monitoring and management system: according to the specific conditions of temperature and humidity uploaded by a sensing device of a terminal node, automatic completion can be achieved when temperature reduction and/or humidity elimination are needed, but manual participation is needed when the warehouse needs to be turned over, when the responsibility of a worker turning over the warehouse is not strong, the worker may turn over less or even not turn over, and an automatic detection means is not used for monitoring the warehouse turning quality at present unless a manager for monitoring the warehouse turning quality is on site.

As is well known, the sensing device node used for preventing burglary at the tail end in the granary monitoring and management system is generally a human body infrared sensor and/or a camera, and once other people break through the defense line of the human body infrared sensor and the camera, grains can be stolen. It is also known that most of grain storage adopts an accumulation type, and pressure change in a granary can be caused by reduction of grain accumulation and/or collapse of accumulated grains. When the grain is stolen, the grain accumulation amount can be reduced, and even the accumulated grain is collapsed. At present: during the anti-theft period, no terminal node of the granary monitoring and management system assists in anti-theft for the sensing device of pressure change in the stacked granary.

As is well known, the nodes of the temperature and humidity sensing devices, the ends of which are arranged in the stacked grain bin, in the monitoring and management system of the grain bin are required to be distributed in the grain stack, and the nodes of the temperature and humidity sensing devices in the grain stack are arranged in a horizontal direction with a row-column spacing not greater than 5 m and a vertical direction with a spacing not greater than 3 m, and the nodes of the temperature and humidity sensing devices are divided into two types, namely wireless (such as temperature and humidity sensing device nodes based on Zigbee technology) and wired (such as inserted rod type temperature and humidity sensing device nodes), from a communication mode. The temperature and humidity sensing device node in a wired mode is convenient to supply power, but is inconvenient to arrange in a grain pile; the wireless temperature and humidity sensing device nodes are conveniently buried in the grain pile, but the power supply needs to be wireless and/or battery-powered, and no battery is used for supplying power, so that the wireless temperature and humidity sensing device nodes cannot be monitored in real time if the temperature and humidity exceed the limit, namely cannot be uploaded to a granary monitoring and management system. The wired temperature and humidity sensing device can not only facilitate regular inspection of a granary monitoring and management system, but also facilitate real-time uploading of temperature and humidity overrun to the granary monitoring and management system when the granary monitoring and management system is not in an inspection period, and the wired temperature and humidity sensing device can be in a live working state at any time because the wired temperature and humidity sensing device is convenient to supply power, but the wired temperature and humidity sensing device node is inconvenient to arrange in a stacked granary; the wireless mode temperature and humidity sensing device node can make things convenient for the granary monitoring management system to patrol and examine regularly, and the temperature and humidity sensing device node of wireless mode is located and is piled up the formula granary and convenient than the temperature and humidity sensing device node of wired mode, but the granary monitoring management system is not in the period of patrolling and examining, if the temperature and humidity transfinites and need to upload to the granary monitoring management system in real time, the temperature and humidity sensing device node of wireless mode must be from taking the power supply battery, because the electric quantity of battery is limited, so must consider under the energy-conserving state, the granary monitoring management system is not in the period of patrolling and examining, if the temperature and humidity transfinites and uploads to the granary monitoring management system in real time, need consider the problem of conveniently supplementing the electric quantity. According to the prior art, no good scheme is provided, the energy-saving problem of the wireless temperature and humidity sensing device with the temperature and humidity over-limit real-time uploading to the granary monitoring and management system is solved, and the battery power supply problem is solved.

It is well known that: the higher the temperature is, the lower the safety moisture content of the grain is, and the water content of the grain is reduced by 1 percent when the temperature of the grain pile is increased by 5 ℃ according to the inspection. Thus, when the temperature rises, the original moisture content is maintained, and the grain deterioration is accelerated. Therefore, when the temperature rises to the limit, real-time prompting is particularly important.

The current granary monitoring and management system cannot evaluate the quality of the turned granary and alarm real-time theft.

Disclosure of Invention

The invention aims to solve the technical problem of the prior art, and provides a supervision system and an implementation method thereof, aiming at the defects existing in the prior art, and the supervision system and the implementation method thereof are implemented as follows: firstly, routing inspection and overtemperature real-time alarming are realized; secondly, prompting and alarming when the bin is turned over and the stealing behavior occurs are integrated; and thirdly, the system has the functions of quality evaluation of the turnover and graded alarm according to the stealing amount.

In order to achieve the purpose, the technical scheme of the invention is as follows:

a monitoring system comprises a granary management information system arranged in a monitoring center, an information receiving and transmitting control terminal arranged in each granary, a granary temperature and humidity monitoring unit, an excitation/charging source module and corresponding cooling, dehumidifying and ventilating equipment; the system comprises an information transceiving control terminal of each granary, an information transceiving control terminal, an excitation/charging source module, a control unit, a communication network and a ventilation device, wherein the information transceiving control terminal of each granary is connected with a granary management information system through the communication network, the information transceiving control terminal is connected with a cooling device, a dehumidifying device and a ventilation device through control signals, the granary temperature and humidity monitoring unit is connected with the information transceiving control terminal of the same granary in a high-frequency wireless mode, the excitation/charging source module is connected with the information transceiving control terminal of the same granary in a wireless or wired mode, and the excitation/charging source module is; the excitation/charging source module comprises an excitation signal program module and a charging signal program module which are controlled and transmitted by the information transceiving control terminal; the information receiving and transmitting control terminal comprises a cabin turning quality evaluation program module and a grading alarm program module according to the stealing amount;

the granary temperature and humidity monitoring unit comprises: the method comprises the following steps: the device comprises a rectification module, a demodulation and decoding control module, a battery charging module, a temperature and humidity acquisition module, a temperature-sensitive switch, a pressure switch module, a low-frequency antenna, a battery, a first field-effect tube, a second field-effect tube, a third field-effect tube, a fourth field-effect tube, a fifth field-effect tube, a sixth field-effect tube and a seventh field-effect tube; the low-frequency antenna is connected with an excitation/charging source module in the granary in a wireless mode and receives an excitation/charging source signal sent by the excitation/charging source module; the low-frequency antenna is respectively connected with the input of the rectifying module and the input of the demodulation and decoding control module; the output of the rectification module is respectively connected with the power input of the demodulation decoding control module and the source electrode of the third field effect transistor, the drain electrode of the third field effect transistor is connected with the input of the battery charging module, the gate electrode of the third field effect transistor is connected with the drain electrode of the second field effect transistor, the gate electrode of the second field effect transistor is connected with one output of the demodulation decoding control module, and the source electrode of the second field effect transistor is connected with the cathode of the battery; the charging output of the battery charging module is connected with the input of the pressure switch module in parallel and then is connected to the positive electrode of the battery; one signal output of the battery charging module 300 is connected with the input of the temperature and humidity acquisition module, and the other signal output of the battery charging module is connected with the input of the demodulation and decoding control module; the grid electrode of the first field effect tube is connected with the other output of the demodulation decoding control module, and the source electrode of the first field effect tube is connected with the cathode of the battery; the output of the pressure switch module is connected with a gate electrode of a fifth field effect transistor; the source electrode of the fifth field effect transistor is connected with the negative electrode of the battery; the grid electrode of the fourth field effect transistor is connected with the output of the temperature and humidity acquisition module, and the source electrode of the fourth field effect transistor is connected with the negative electrode of the battery; a source electrode of the sixth field effect tube, a source electrode of the seventh field effect tube and one end of the temperature-sensitive switch are mutually connected in parallel and then connected with the anode of the battery, a drain electrode of the sixth field effect tube, a drain electrode of the seventh field effect tube and the other end of the temperature-sensitive switch are mutually connected in parallel and then connected to the power input of the temperature-humidity acquisition module, and a grid electrode of the sixth field effect tube is mutually connected in parallel with a drain electrode of the first field effect tube and a drain electrode of the fourth field effect tube; the drain electrode of the fifth field effect transistor is connected with the gate electrode of the seventh field effect transistor, and leads from the connecting wire to the interrupt input and the digital input of the temperature and humidity acquisition module; the temperature and humidity acquisition module is connected with the information receiving and transmitting control terminal in a wireless mode; and the power supply cathode of the rectification module, the power supply cathode of the battery charging module, the power supply cathode of the temperature and humidity acquisition module and the power supply cathode of the pressure switch module are connected with the cathode of the battery.

The pressure switch module described above includes: a resistor R1, a resistor R2, a stress button and a capacitor; the positive electrode of the capacitor is connected with one end of a resistor R1 in parallel and then connected with the positive electrode of the battery, and the other end of a resistor R1 is connected with the normally open contact of the stress button in series and then connected with the negative electrode of the capacitor; the negative electrode of the capacitor is connected with one end of a resistor R2 after being connected in series with a normally closed contact of the stress button, and the other end of the resistor R2 is connected with the negative electrode of the battery; the gate of the fifth FET is connected to the connection of the normally closed contact of the force button and the resistor R2 through a lead.

The first field effect transistor, the second field effect transistor, the fourth field effect transistor and the fifth field effect transistor are all N-channel enhanced MOS transistors; the third field effect transistor, the sixth field effect transistor and the seventh field effect transistor are P-channel enhanced MOS transistors.

The temperature and humidity acquisition module comprises a temperature and humidity detection processing control unit, a wireless transceiving unit, a temperature sensor, a humidity sensor, a high-frequency antenna and an indicator light; the temperature and humidity detection processing control unit is sequentially connected with the wireless transceiving unit and the high-frequency antenna in series and then is connected with the information transceiving control terminal in a wireless mode; the temperature and humidity detection processing control unit is connected with a temperature sensor, a humidity sensor, a drain electrode of a fifth field effect transistor and a battery charging module in an input mode; the output of the temperature and humidity detection processing control unit is connected with a grid and an indicator light of a fourth field effect tube; and the drain electrode of the fifth field effect transistor is connected with the interrupt input and the digital input of the temperature and humidity detection processing control unit.

The capacitance described above is: a leaky tantalum capacitor or a niobium capacitor.

The stressed button is a two-way contact switch, one way is normally open, and the other way is normally closed.

In order to achieve the above object, another technical solution of the present invention is:

a method for implementing a supervision system comprises the following steps:

the method comprises the following steps:

the method comprises the steps that when an information receiving and transmitting control terminal outputs routing inspection control information to an excitation/charging source module, an excitation signal is sent out, and an electric work of a temperature and humidity acquisition module in a granary temperature and humidity monitoring unit is excited;

secondly, when the information transceiving control terminal outputs charging control information to the excitation/charging source module, a charging signal is sent out, and batteries in the granary temperature and humidity monitoring unit are charged wirelessly;

thirdly, when the response is to the interrupt application sent by the pressure switch module through the output of the fifth field effect transistor, the current turning over or grain discharging or grain stealing is determined, and the uploading pressure switch module outputs information to the information receiving and transmitting control terminal:

when the time period is set as a grain discharging time period or a grain turning time period, returning a grain turning/discharging identification code to a corresponding granary temperature and humidity monitoring unit, and when the time period is set as the grain turning time period, judging the grain turning quality: accumulating the granary temperature and humidity monitoring units which have output information and are uploaded in the granary in the time period, calculating the ratio of the granary temperature and humidity monitoring units to the total amount of the granary temperature and humidity monitoring units in the granary, and setting the ratio as: the total occupancy rate of the output information is set and used as an evaluation index of the turning quality, the higher the total occupancy rate of the output information is, the better the turning quality is determined, otherwise,

when the time period is set as an anti-theft time period, the anti-theft identification code is transmitted back to the corresponding granary temperature and humidity monitoring unit, alarm grading judgment is carried out: setting a specified time length, accumulating the granary temperature and humidity monitoring units which have the output information uploaded within the specified time length, calculating the ratio of the granary temperature and humidity monitoring units to the total amount of the granary temperature and humidity monitoring units arranged in the grain stack, and setting the ratio as follows: the score occupation ratio of the output information is adopted as an evaluation index of alarm grading, the higher the score occupation ratio of the output information in a short time is, the serious theft in the time is determined, the alarm frequency is increased, the higher the top level of upward alarm layer by layer is, and the opposite is realized.

Has the advantages that:

the invention relates to a monitoring system and a realization method thereof, which has the advantages that the monitoring system has the functions of routing inspection and overtemperature real-time alarming; secondly, prompting and alarming when the bin is turned over and the stealing behavior occurs; the battery in the terminal granary temperature and humidity monitoring unit is full, the battery supplies power to work after any condition that the pressure switch module generates the excitation signal is detected, and the overtemperature is detected, so that the battery energy conservation is facilitated; fourthly, the pressure switch module in the terminal granary temperature and humidity monitoring unit generates an excitation signal which can be used as a signal for the occurrence of a granary turning behavior and a signal for the occurrence of a stealing behavior, so that the granary turning behavior and the stealing behavior are monitored in real time; after the barn turning and discharging actions in the terminal barn temperature and humidity monitoring unit occur, the indicator lamp is lightened, so that the barn temperature and humidity monitoring unit can be found conveniently in the barn turning and discharging processes, and the barn temperature and humidity monitoring unit is reset; and sixthly, the warehouse turnover quality evaluation and the graded alarm according to the theft amount are realized, and the supervision of a manager is facilitated.

Drawings

FIG. 1 is a schematic diagram of a supervisory system according to the present invention;

FIG. 2 is a schematic block diagram of the granary temperature and humidity monitoring unit of the present invention shown in FIG. 2;

in the figure: 100. the system comprises a rectification module 200, a demodulation decoding control module 300, a battery charging module 400, a temperature and humidity acquisition module 500, a temperature sensing switch 700, a pressure switch module 600, a low-frequency antenna, a battery E, a Q1, a Q2, a Q3, a Q4, a Q5, a Q6, a first field-effect tube, a seventh field-effect tube, a temperature and humidity detection processing control unit 410, a wireless transceiving unit 420, a temperature sensor 430, a humidity sensor 440, a high-frequency antenna 450, an indicator light 460, an AN. stress button, a C capacitor, a resistor R1, a resistor R2, a1, a grain 2 and a grain bin An. temperature and humidity monitoring units n, and the number of grain bin temperature and humidity monitoring units arranged in a grain bin stack.

Detailed Description

As shown in fig. 1 and 2, a monitoring system includes a granary management information system disposed in a monitoring center, and an information transceiving control terminal disposed in each granary, a granary temperature and humidity monitoring unit, an excitation/charging source module and corresponding cooling, dehumidifying and ventilating devices; the system comprises an information transceiving control terminal of each granary, an information transceiving control terminal, an excitation/charging source module, a control unit, a communication network and a ventilation device, wherein the information transceiving control terminal of each granary is connected with a granary management information system through the communication network, the information transceiving control terminal is connected with a cooling device, a dehumidifying device and a ventilation device through control signals, the granary temperature and humidity monitoring unit is connected with the information transceiving control terminal of the same granary in a high-frequency wireless mode, the excitation/charging source module is connected with the information transceiving control terminal of the same granary in a wireless or wired mode, and the excitation/charging source module is; the excitation/charging source module comprises an excitation signal program module and a charging signal program module which are controlled and transmitted by the information transceiving control terminal; the information receiving and transmitting control terminal comprises a cabin turning quality evaluation program module and a grading alarm program module according to the stealing amount.

The granary temperature and humidity monitoring unit comprises: the device comprises a rectification module 100, a demodulation and decoding control module 200, a battery charging module 300, a temperature and humidity acquisition module 400, a temperature-sensitive switch 500, a pressure switch module 700, a low-frequency antenna 600, a battery E, a first field-effect tube Q1, a second field-effect tube Q2, a third field-effect tube Q3, a fourth field-effect tube Q4, a fifth field-effect tube Q5, a sixth field-effect tube Q6 and a seventh field-effect tube Q7; the low-frequency antenna 600 is connected with an excitation/charging source module in the granary in a wireless mode and receives an excitation/charging source signal sent by the excitation/charging source module; the low-frequency antenna 600 is respectively connected with the inputs of the rectifying module 100 and the demodulation and decoding control module 200; the output of the rectifying module 100 is respectively connected to the power input of the demodulation decoding control module 200 and the source of the third field effect transistor Q3, the drain of the third field effect transistor Q3 is connected to the input of the battery charging module 300, the gate of the third field effect transistor Q3 is connected to the drain of the second field effect transistor Q2, the gate of the second field effect transistor Q2 is connected to an output of the demodulation decoding control module 200, and the source of the second field effect transistor Q2 is connected to the cathode of the battery E; the charging output of the battery charging module 300 is connected in parallel with the input of the pressure switch module 700 and then connected to the positive electrode of the battery E; one signal output of the battery charging module 300 is connected with the input of the temperature and humidity acquisition module 400, and the other signal output of the battery charging module 300 is connected with the input of the demodulation decoding control module 200; the gate of the first field effect transistor Q1 is connected with the other output of the demodulation decoding control module 200, and the source of the first field effect transistor Q1 is connected with the cathode of the battery E; the output of the pressure switch module 700 is connected with the gate of the fifth field effect transistor Q5; the source electrode of the fifth field effect transistor Q5 is connected with the negative electrode of the battery E; the grid electrode of the fourth field-effect tube Q4 is connected with the output of the temperature and humidity acquisition module 400, and the source electrode of the fourth field-effect tube Q4 is connected with the negative electrode of the battery E; a source electrode of the sixth field-effect tube Q6, a source electrode of the seventh field-effect tube Q7 and one end of the temperature-sensitive switch 500 are connected in parallel and then connected with the anode of the battery E, a drain electrode of the sixth field-effect tube Q6, a drain electrode of the seventh field-effect tube Q7 and the other end of the temperature-sensitive switch 500 are connected in parallel and then connected to the power input of the temperature and humidity acquisition module 400, and a gate electrode of the sixth field-effect tube Q6 is connected in parallel with a drain electrode of the first field-effect tube Q1 and a drain electrode of the fourth field-effect tube Q4; the drain of the fifth field effect transistor Q5 is connected to the gate of the seventh field effect transistor Q7, and leads from its connection line to the interrupt input and digital input of the temperature and humidity acquisition module 400; the temperature and humidity acquisition module 400 is connected with the information receiving and transmitting control terminal in a wireless mode; the negative electrode of the power supply of the rectifying module 100, the negative electrode of the power supply of the battery charging module 300, the negative electrode of the power supply of the temperature and humidity acquisition module 400 and the negative electrode of the power supply of the pressure switch module 700 are connected with the negative electrode of the battery E.

The first field-effect transistor Q1, the second field-effect transistor Q2, the fourth field-effect transistor Q4 and the fifth field-effect transistor Q5 are all N-channel enhancement type MOS transistors; the third fet Q3, the sixth fet Q6, and the seventh fet Q7 are P-channel enhancement MOS transistors.

The pressure switch module 700 described above includes: a resistor R1, a resistor R2, a stress button AN and a capacitor C; the positive electrode of the capacitor C is connected with one end of the resistor R1 in parallel and then connected to the positive electrode of the battery E, and the other end of the resistor R1 is connected with the normally open contact of the stress button AN in series and then connected with the negative electrode of the capacitor C; the negative electrode of the capacitor C is connected with the normally closed contact of the stress button AN in series and then is connected with one end of the resistor R2, and the other end of the resistor R2 is connected with the negative electrode of the battery E; the gate of the fifth field effect transistor Q5 is connected with the lead from the connection line of the normally closed contact of the force button AN and the resistor R2.

The stress button AN is a double-path contact switch, one path is normally open, the other path is normally closed, and the stress surface of the stress button AN is set as follows: when the stress is more than or equal to 5 kilograms, one normally open contact is closed, and one normally closed contact is opened; when the stress is less than 5 kilograms, one path of normally open contact is opened (kept normally open), and one path of normally closed contact is closed (kept normally closed). That is, when the stress of the stress surface of the stress button AN is greater than or equal to 5 kgf, one normally open contact is closed, and one normally closed contact is opened, and when the stress of the stress surface of the stress button AN is less than 5 kgf, one normally open contact is returned to be opened, and one normally closed contact is returned to be connected (closed). The granary temperature and humidity monitoring unit in the monitoring system is arranged in the bearing box, and the stress surface of the stress button AN is arranged on the panel of the granary temperature and humidity monitoring unit bearing box in a concave mode, namely the stress surface of the stress button AN is concave into the panel of the bearing box, so that the granary temperature and humidity monitoring unit is not easily influenced by external pressure to trigger the power supply circuit of the battery E to be electrified in the transportation and standby storage processes, and the service life of the battery E is prolonged.

The capacitor C described above is selected to have a small leakage current, such as a tantalum capacitor and a niobium capacitor.

In the pressure switch module 700, the battery E passes through a charging circuit formed by the capacitor C, the normally closed contact of the stressed button AN and the resistor R2, and the opening and closing of the charging circuit is controlled by the normally closed contact of the stressed button AN. The normally closed contact of the stressed button AN is disconnected, the charging circuit formed by serially connecting the capacitor C and the resistor R2 is disconnected, the normally open contact of the stressed button AN is connected, and the capacitor C discharges through the resistor R1. Under the condition of ensuring safety, the resistor R1 is as small as possible to ensure that the capacitor C is discharged in a short time when the stress surface of the stress button AN is stressed by more than or equal to 5 kilograms force, namely after the normally open contact of the stress button AN is switched on. The voltage of a connecting line between the resistor R2 and the normally closed contact end of the stressed button AN is used as AN output signal, namely, the voltage dropped on the resistor R2 is used as the output signal of the pressure switch module 70, and the output signal is led to the grid electrode of the fifth field effect transistor Q5. In the charging process of a charging loop formed by the battery E through the capacitor C, the normally closed contact of the stressed button AN and the resistor R2, the voltage dropped on the resistor R2 is gradually reduced from equal to the voltage of the battery E along with the charging of the capacitor C, and when the capacitor C is fully charged or the normally closed contact of the stressed button AN is disconnected, the voltage dropped on the resistor R2 is zero. The requirements for the selection of the size of the capacitor C and the resistor R2 are: in the charging process, the control voltage which is obtained from the resistor R2 and is greater than or equal to the opening voltage UGS (th) of the fifth field effect transistor Q5 is kept after the temperature and humidity acquisition module 400 is electrified to control the fourth field effect transistor Q4 to enter the on state from the off state.

The on and off of the fifth field effect transistor Q5 are controlled by the output of the pressure switch module 700, the pressure switch module 700 outputs a voltage UGS (th) which is greater than or equal to the opening voltage of the fifth field effect transistor Q5, the fifth field effect transistor Q5 is on, otherwise, the fifth field effect transistor Q5 is off; the on and off of the seventh field effect transistor Q7 are controlled by the output of the fifth field effect transistor Q5, the fifth field effect transistor Q5 is switched on, and the seventh field effect transistor Q7 is switched on; the fifth fet Q5 is turned off and the seventh fet Q7 is turned off.

The switches of the sixth field effect transistor Q6, the seventh field effect transistor Q7 and the temperature-sensitive switch 500 are connected in parallel: and controlling the power input path of the battery E to the temperature and humidity acquisition module 400.

The excitation/charging source module is used for generating excitation and charging signals for the granary temperature and humidity monitoring unit, and comprises an excitation signal program module and a charging signal program module which are controlled and sent by the information transceiving control terminal. The excitation/charging source module is connected with the low-frequency antenna 600 in the granary temperature and humidity monitoring unit in a wireless mode. The excitation/charging source module is connected with the information receiving and transmitting control terminal, and signals transmitted by the excitation/charging source module are controlled by the information receiving and transmitting control terminal. When the information transceiving control terminal outputs the patrol inspection control information to the excitation/charging source module, the excitation/charging source module receives the patrol inspection control information, executes the excitation signal program module, and sends an excitation signal, wherein the sent excitation signal contains an excitation code, and the excitation codes in the granary temperature and humidity monitoring units in the same granary are consistent; when the information receiving and transmitting control terminal outputs the inspection stopping control information to the excitation/charging source module, the excitation/charging source module receives the inspection stopping control information, the excitation signal program module stops executing, and the excitation/charging source module stops sending the excitation signal. When the information transceiving control terminal outputs the charging control information to the excitation/charging source module, the excitation/charging source module receives the charging control information, executes the charging signal program module and sends a charging signal, wherein the sent charging signal contains a charging code, and the charging codes in the granary temperature and humidity monitoring units in the same granary are also set to be consistent; when the information transceiving control terminal outputs the charging stop control information to the excitation/charging source module, the excitation/charging source module receives the charging stop control information, the charging signal program module stops executing, and the excitation/charging source module stops sending the charging signal.

The information transceiving control terminal is an intermediate node and is used for specifically inspecting and receiving the granary temperature and humidity monitoring unit in the granary in real time and controlling the output signal of the excitation/charging source module, the information transceiving control terminal is connected with the temperature and humidity acquisition module 400 in the granary temperature and humidity monitoring unit in a high-frequency wireless mode, the information transceiving control terminal is connected with a granary management information system of a monitoring center through a network and is connected with the excitation/charging source module through a wire or a wireless mode, and corresponding control signals are output to the excitation/charging source module according to requirements; and the information receiving and transmitting control terminal is also connected with control signals to temperature adjusting, moisture removing and ventilating equipment and is connected with an infrared camera shooting and anti-theft end device.

When the information transceiving control terminal requires to inspect the granary temperature and humidity monitoring units, the inspection control information is output to the excitation/charging source module, and when the information transceiving control terminal establishes communication connection with more than 3 granary temperature and humidity monitoring units in the granary, the information transceiving control terminal outputs the inspection stopping control information to the excitation/charging source module and transmits the inspection information marks to all granary temperature and humidity monitoring units in the granary.

When the information transceiving control terminal requires to supplement electric quantity to the battery E in the granary temperature and humidity monitoring units, charging control information is output to the excitation/charging source module, the information transceiving control terminal sends out a battery full-charge signal to all the granary temperature and humidity monitoring units in the granary to be received, and charging stop control information is output to the excitation/charging source module.

When the polling is needed in the charging process, the information receiving and transmitting control terminal immediately outputs the charging stopping control information to the excitation/charging source module and then outputs the polling control information to the excitation/charging source module.

The low-frequency antenna 600 receives a signal from the excitation/charging source module, and sends the signal to the power input terminal of the rectification module 100 and the signal input terminal of the demodulation and decoding control module 200, and the rectification module 100 rectifies and stabilizes the voltage of the signal received by the low-frequency antenna 600 and outputs a working voltage to the power input terminal of the demodulation and decoding control module 200 and the source terminal of the third field-effect transistor Q3.

The demodulation decoding control module 200 demodulates and decodes signals received by the low-frequency antenna 600, the demodulation decoding control module 200 has excitation codes and charging codes, and the demodulation decoding control module 200 compares the demodulated codes with the stored excitation codes and charging codes: when the encoding is excited, a high potential (greater than or equal to the turn-on voltage UGS (th) of the first field effect transistor Q1) is output to the gate of the first field effect transistor Q1, a low potential (less than the turn-on voltage UGS (th) of the second field effect transistor Q2) is output to the gate of the second field effect transistor Q2, the first field effect transistor Q1 is turned on, and the second field effect transistor Q2 is turned off; in order to charge the code, the low potential (smaller than the turn-on voltage ugs (th) of the first fet Q1) is outputted to the gate of the first fet Q1, the high potential (greater than or equal to the turn-on voltage ugs (th) of the second fet Q2) is outputted to the gate of the second fet Q2, the first fet Q1 is turned off, and the second fet Q2 is turned on. The demodulation decoding control module 200 does not receive the excitation encoding and charging encoding signals, outputs a low potential to the gates of the first field effect transistor Q1 and the second field effect transistor Q2, and turns off both the first field effect transistor Q1 and the second field effect transistor Q2.

The demodulation and decoding control module 200 controls the conduction of the third field effect transistor Q3 through the second field effect transistor Q2, during the period that the output of the rectification module 100 is transmitted to the battery charging module 300 through the third field effect transistor Q3 to charge the battery E, the demodulation and decoding control module 200 responds to whether the battery charging module 300 inputs a full battery signal or not, the demodulation and decoding control module 200 waits to receive the full battery signal input by the battery charging module 300, the demodulation and decoding control module 200 outputs a high potential to the grid electrode of the first field effect transistor Q1 and a low potential to the grid electrode of the second field effect transistor Q2, the first field effect transistor Q1 is conducted, the second field effect transistor Q2 is cut off, the demodulation and decoding control module 200 temporarily stops the corresponding charging signal, the low potential is output to the grid electrode of the first field effect transistor Q1 after 3 seconds of delay, the first field effect transistor Q1 is turned off or is not delayed, and the demodulation and decoding control module 200 has no working power supply, that is, after the battery E is fully charged, the demodulation decoding control module 200 still keeps outputting the low potential to the gate of the second fet Q2, and keeps the control voltage output to the gate of the first fet Q1 unchanged.

When the demodulation decoding control module 200 is not powered, the voltage output to the gates of the first field effect transistor Q1 and the second field effect transistor Q2 is zero, the first field effect transistor Q1 and the second field effect transistor Q2 are cut off, and the pause function automatically disappears.

During the period that the demodulation decoding control module 200 suspends the corresponding charging signal, the demodulation decoding control module 200 does not lose the working power supply, and under the condition, after receiving the excitation code, the suspended charging function is released, namely after receiving the excitation code, the demodulation decoding control module 200 correspondingly charges the signal next time.

The second field effect transistor Q2 is cut off, and the third field effect transistor Q3 is cut off; the second fet Q2 is turned on and the third fet Q3 is turned on.

The third fet Q3 is turned off, the output of the rectifier module 100 cannot charge the battery E through the battery charging module 300 via the third fet Q3, i.e., the third fet Q3 is turned off, and the voltage output by the rectifier module 100 stops charging the battery E through the battery charging module 300 via the third fet Q3. The third fet Q3 is turned on, and the voltage output from the rectifying module 100 charges the battery E through the battery charging module 300 via the third fet Q3.

The battery charging module 300 includes a charging circuit for charging the battery E and a circuit for monitoring whether the battery E is fully charged. The charging output of the battery charging module 300 is connected to the positive electrode of the battery E, and the output of the monitoring circuit for detecting whether the battery E is fully charged is connected to the input of the demodulation and decoding control module 200 and the input of the temperature and humidity acquisition module 400.

When any one of the first field effect transistor Q1 and the fourth field effect transistor Q4 is turned on, the gate-source control voltage UGS applied to the sixth field effect transistor Q6 is less than or equal to the turn-on voltage UGS (th), and the sixth field effect transistor Q6 is turned on.

When the first field effect transistor Q1 and the fourth field effect transistor Q4 are both turned off, the control voltage UGS applied between the gate and the source of the sixth field effect transistor Q6 is greater than the turn-on voltage UGS (th), and the sixth field effect transistor Q6 is turned off.

The temperature-sensing switch 500 is used for starting the battery E to supply power when overtemperature occurs, and overtemperature real-time alarming is achieved.

The temperature-sensing switch 500 is a passive physical contact switch, and the contacts thereof are normally open, that is: when the temperature-sensitive switch 500 senses that the temperature is lower than the set temperature, the contact of the temperature-sensitive switch 500 is disconnected, and the normal working state is realized; when the temperature-sensitive switch 500 senses that the temperature is higher than or equal to the set temperature, the contact of the temperature-sensitive switch 500 is turned on (closed), and when the temperature-sensitive switch 500 after being turned on senses that the temperature is lower than the set temperature, the contact of the temperature-sensitive switch 500 is restored to the normal working state, i.e., turned off.

Generally, the temperature in the granary is required to be kept below 30 ℃ throughout the year, and the set temperature of the temperature-sensitive switch 500 is as follows: when the temperature is sensed to be higher than or equal to 35 ℃ by the temperature-sensitive switch 500, the battery E is connected to the temperature and humidity acquisition module 400 through the temperature-sensitive switch 500, and the temperature and humidity acquisition module 400 is powered on to work.

The temperature and humidity acquisition module 400 is used for reading specific temperature and humidity, theft prevention, turning over a warehouse, grain discharging, battery E electric quantity and the like and sending the collected data to an information receiving and sending control terminal for corresponding control, and comprises a temperature and humidity detection processing control unit 410, a wireless receiving and sending unit 420, a temperature sensor 430, a humidity sensor 440, a high-frequency antenna 450 and an indicator lamp 460; the temperature and humidity detection processing control unit 410 is connected in series with the wireless transceiving unit 420 and the high-frequency antenna 450 in sequence and then is connected with the information transceiving control terminal in a wireless manner; the temperature and humidity detection processing control unit 410 is connected with a temperature sensor 430, a humidity sensor 440, a drain of a fifth field effect transistor Q5 and the battery charging module 300 in an input manner; the output of the temperature and humidity detection processing control unit 410 is connected with the grid of a fourth field effect transistor Q4 and an indicator lamp 460; the drain of the fifth fet Q5 is connected to the interrupt input and the digital input of the temperature and humidity detection processing control unit 410, and sets the low level of the temperature and humidity detection processing control unit 410 to respond to the interrupt request output from the fifth fet Q5. The temperature and humidity detection processing control unit 410 is an information processing control unit, collects, processes and uploads corresponding input signals, and correspondingly controls through output according to a processing result, and the temperature and humidity detection processing control unit 410 includes: the CPU, the input/output interface and the EEPROM memory which are matched with the input/output circuit are provided with corresponding ID codes, and a corresponding detection identification control program module and a program module which is communicated with the information transceiving control terminal are embedded, and an interrupt service program module which responds to the output of the fifth field effect transistor Q5 at a low level is also embedded; and a voltage monitoring circuit of the battery E is also contained.

When the output of the pressure switch module 700 is greater than zero voltage, it indicates that the normally closed contact of the stressed button AN is on, that is, the stressed surface of the stressed button AN is stressed by less than 5 kgf, and the time for which the normally closed contact is on is less than the time required for the capacitor C to be fully charged, or the time for which the normally closed contact is on to be maintained is less than the time required for the capacitor C to be fully charged. When the voltage output by the pressure switch module 700 is closer to the terminal voltage of the battery E, it indicates that the normally closed contact is just turned on, and the smaller the voltage output by the pressure switch module 700, it indicates that the normally closed contact is turned on and maintained for the longer time. When the output of the pressure switch module 700 is equal to zero voltage, it indicates that the normally closed contact of the force button AN is in AN off state or the normally closed contact is on and maintained until the current time is longer than the time required for the capacitor C to be fully charged, i.e., when the output of the pressure switch module 700 is equal to zero voltage, it indicates that the force applied to the force-applying surface of the force button AN is greater than or equal to 5 kgf or that the normally closed contact is on and maintained until the current time is long.

Because the granary temperature and humidity monitoring unit arranged in the granary is in a static state at ordinary times, and the time of the granary temperature and humidity monitoring unit in the static state is far longer than the time required for filling the capacitor C, the granary temperature and humidity monitoring unit in the granary is in the static state at ordinary times, and the output of the pressure switch module 700 is equal to zero voltage no matter how large the stress surface of the stress button AN is.

Therefore, when the granary temperature and humidity monitoring unit is arranged in the grain pile, the stress surface of the stress button AN on the upper layer is ensured to be more than or equal to 5 kilograms force.

Because the current behaviors of turning over the granary, discharging the grains and preventing burglary are captured in real time, the interruption service program module is set to be low-level response interruption in the process of responding to the output of the fifth field-effect tube Q5, and the current granary turning over, discharging the grains or stealing the grains is determined when the output of the fifth field-effect tube Q5 is responded to the interruption; and the fifth field effect transistor Q5 is not responded to, and the grain is determined not to be turned over and discharged at present and is not stolen.

After the power-on position of the temperature and humidity detection processing control unit 410 in the temperature and humidity acquisition module 400 is initialized, a high level is immediately output to the gate of the fourth field-effect tube Q4, and the fourth field-effect tube Q4 is turned on, so that the sixth field-effect tube Q6 is turned on/kept on; when an interruption application is sent out by the output of the fifth field effect transistor Q5, the pressure switch module 700 is determined to have output information, which indicates that the grain is being turned over or put away or the grain is stolen at present, the interruption application output by the fifth field effect transistor Q5 is shielded, the fourth field effect transistor Q4 is controlled to be switched off, the pressure switch module 700 is uploaded to have output information to an information receiving and sending control terminal, and otherwise, the grain is determined not to be turned over or put away at present and the grain is not stolen.

And responding to the output of the fifth field effect transistor Q5 to send an interrupt application, and simultaneously shielding the temperature and humidity detection and the battery full charge identification until the temperature and humidity acquisition module 400 loses power.

The indicator lamp 460 is used for identifying that the granary is being turned over or grain is being discharged at the position during the granary turning and grain discharging, and the indicator lamp is turned on in a twinkling mode, so that the corresponding granary temperature and humidity monitoring unit can be found conveniently in the granary turning and grain discharging processes.

The information receiving and transmitting control terminal is embedded with a storehouse turning quality evaluation program module and a grading alarm program module according to the stealing amount. And executing a bin turning quality evaluation program module when the time period is set to be bin turning, and executing a grading alarm program module according to the theft amount when the time period is set to be anti-theft.

When the temperature and humidity detection processing control unit 410 uploads the output information of the pressure switch module 700 to the information transceiving control terminal, the temperature and humidity detection processing control unit 410 waits for the response information of the information transceiving control terminal to the information transceiving control terminal, when the time period is set as turning over or discharging, no matter turning over or discharging, the turning over/discharging identification code is uniformly fed back to the temperature and humidity detection processing control unit 410 in the corresponding granary temperature and humidity monitoring unit, and if the time period is the turning over time period, the turning over quality is judged; when the time period is set to be antitheft, feeding back an antitheft identification code to the corresponding temperature and humidity detection processing control unit 410 in the granary temperature and humidity monitoring unit, and carrying out antitheft alarm prompting; and if the grain release time period is the grain release time period, no evaluation is performed.

The temperature and humidity detection processing control unit 410 recognizes that the feedback is the silo turning/grain discharging identification code, and the temperature and humidity detection processing control unit 410 lights the indicator lamp 460. After the temperature and humidity detection processing control unit 410 lights the indicator lamp 460, the temperature and humidity detection processing control unit 410 reads the output of the fifth field effect transistor Q5 through the digital input port, sets that the output of the fifth field effect transistor Q5 is from high level to low level when 3 times of continuous detection are detected and identified, and the time of 3 times of continuous detection is less than 10 seconds, the temperature and humidity detection processing control unit 410 extinguishes the lighted indicator lamp 460, otherwise, keeps the indicator lamp lighted 460; after the lighted indicator lamp 460 is turned off, a low level is output to the gate of the fourth field effect transistor Q4, and the state enters a sleep state until the temperature and humidity acquisition module 400 loses power.

The temperature and humidity detection processing control unit 410 recognizes that the feedback is the anti-theft identification code, outputs a low level to the gate of the fourth field effect transistor Q4, and enters a dormant state until the temperature and humidity acquisition module 400 loses power.

When the information receiving and sending control terminal is in the bin turning time period set by the information receiving and sending control terminal, the bin turning quality is judged: accumulating the granary temperature and humidity monitoring units which have output information and are uploaded in the granary in the time period, calculating the ratio of the granary temperature and humidity monitoring units to the total amount of the granary temperature and humidity monitoring units in the granary, and setting the ratio as: the total occupancy rate of the output information is set to be used as an evaluation index of the turning quality, the higher the total occupancy rate of the output information is, the better the turning quality is determined, and the contrary is. The invention sets the following steps: when the total proportion of the output information reaches more than or equal to 95%, the quality of turning over the bin is determined to be excellent; the total proportion of the output information is more than or equal to 85 percent and less than 95 percent, and the quality of turning over the bin is qualified; the total occupied ratio of the output information is less than 85%, and the quality of the turnover bin is determined to be unqualified.

When the information receiving and transmitting control terminal is in the anti-theft time period set by the information receiving and transmitting control terminal, alarm grading judgment is carried out: setting a specified time length, accumulating the granary temperature and humidity monitoring units which have the output information uploaded within the specified time length, calculating the ratio of the granary temperature and humidity monitoring units to the total amount of the granary temperature and humidity monitoring units arranged in the grain stack, and setting the ratio as follows: the score occupation ratio of the output information is set, the score occupation ratio of the output information is used as an evaluation index of alarm grading, the higher the score occupation ratio of the output information in a short time is, the serious theft in the time is determined, the alarm frequency is increased, the higher the top level of upward alarm layer by layer is, and the opposite is realized. Examples are: if it is assumed that: the lowest level is specific staff, the middle level is a specific management layer, and the highest level is a local government and a local citizen; the invention sets the specified time length to be 4 hours, and sets the following parameters: the percentage of the output information is less than 1 percent (and more than 0), only alarming the specific staff of the lowest level, and 2 times per day until the theft prevention is relieved; if the proportion of the output information reaches more than or equal to 1 percent and less than 5 percent, alarming to specific staff at the lowest level and alarming to a specific management layer at the middle level, wherein the alarming times are increased to 4 times every day until the theft prevention is removed; the proportion ratio of the output information reaches more than or equal to 5 percent, except for the specific staff at the lowest level and the specific management layer at the middle level, the alarm is also given to the local government and the citizen at the highest level, and the number of the alarm is increased to 6 times per day until the theft prevention is relieved. The alarm can be displayed through terminals such as a mobile phone, a television, a network and the like.

After the temperature and humidity acquisition module 400 in the granary temperature and humidity monitoring unit is electrified to control the conduction of the fourth field-effect tube Q4, and the interruption application output by the fifth field-effect tube Q5 is responded, the fourth field-effect tube Q4 is controlled to be switched off, the control is determined by the bin turning/grain discharging identification code and the anti-theft identification code returned by the information receiving and transmitting control terminal, and otherwise, the control is determined by the original function. The original function is determined as follows: after the tasks of detecting, identifying and uploading the temperature, the humidity and the battery E full charge mark are finished, outputting a low level to a grid electrode of a fourth field effect transistor Q4; after outputting the low level to the gate of the fourth field effect transistor Q4, if the temperature and humidity acquisition module 400 does not lose power, the temperature and humidity detection and uploading continues until the temperature and humidity acquisition module 400 loses power.

And the information receiving and transmitting control terminal processes the received temperature and humidity information and performs corresponding cooling and dehumidifying control according to the result.

The process of distributing the granary temperature and humidity monitoring units into the grain pile is as follows: and in the grain stacking process, the grain temperature and humidity monitoring units are vertically placed into the granary from bottom to top in a layer thickness of 1.5 meters, the grain temperature and humidity monitoring units are placed on each layer at intervals of less than 5 meters, and the corresponding ID numbers of the granary temperature and humidity monitoring units specifically placed on a set layer are recorded into the granary management system.

Claims (6)

1. A monitoring system comprises a granary management information system arranged in a monitoring center, an information receiving and transmitting control terminal arranged in each granary, a granary temperature and humidity monitoring unit, an excitation/charging source module and corresponding cooling, dehumidifying and ventilating equipment; the system comprises an information transceiving control terminal of each granary, an information transceiving control terminal, an excitation/charging source module, a control unit, a communication network and a ventilation device, wherein the information transceiving control terminal of each granary is connected with a granary management information system through the communication network, the information transceiving control terminal is connected with a cooling device, a dehumidifying device and a ventilation device through control signals, the granary temperature and humidity monitoring unit is connected with the information transceiving control terminal of the same granary in a high-frequency wireless mode, the excitation/charging source module is connected with the information transceiving control terminal of the same granary in a wireless or wired mode, and the excitation/charging source module is; the excitation/charging source module comprises an excitation signal program module and a charging signal program module which are controlled and transmitted by the information transceiving control terminal; the information receiving and transmitting control terminal comprises a cabin turning quality evaluation program module and a grading alarm program module according to the stealing amount;

the granary temperature and humidity monitoring unit comprises: the device comprises a rectification module, a demodulation and decoding control module, a battery charging module, a temperature and humidity acquisition module, a temperature-sensitive switch, a pressure switch module, a low-frequency antenna, a battery, a first field-effect tube, a second field-effect tube, a third field-effect tube, a fourth field-effect tube, a fifth field-effect tube, a sixth field-effect tube and a seventh field-effect tube; the low-frequency antenna is connected with an excitation/charging source module in the granary in a wireless mode and receives an excitation/charging source signal sent by the excitation/charging source module; the low-frequency antenna is respectively connected with the input of the rectifying module and the input of the demodulation and decoding control module; the output of the rectification module is respectively connected with the power input of the demodulation decoding control module and the source electrode of the third field effect transistor, the drain electrode of the third field effect transistor is connected with the input of the battery charging module, the gate electrode of the third field effect transistor is connected with the drain electrode of the second field effect transistor, the gate electrode of the second field effect transistor is connected with one output of the demodulation decoding control module, and the source electrode of the second field effect transistor is connected with the cathode of the battery; the charging output of the battery charging module is connected with the input of the pressure switch module in parallel and then is connected to the positive electrode of the battery; one signal output of the battery charging module is connected with the input of the temperature and humidity acquisition module, and the other signal output of the battery charging module is connected with the input of the demodulation and decoding control module; the grid electrode of the first field effect tube is connected with the other output of the demodulation decoding control module, and the source electrode of the first field effect tube is connected with the cathode of the battery; the output of the pressure switch module is connected with a gate electrode of a fifth field effect transistor; the source electrode of the fifth field effect transistor is connected with the negative electrode of the battery; the grid electrode of the fourth field effect transistor is connected with the output of the temperature and humidity acquisition module, and the source electrode of the fourth field effect transistor is connected with the negative electrode of the battery; a source electrode of the sixth field effect tube, a source electrode of the seventh field effect tube and one end of the temperature-sensitive switch are mutually connected in parallel and then connected with the anode of the battery, a drain electrode of the sixth field effect tube, a drain electrode of the seventh field effect tube and the other end of the temperature-sensitive switch are mutually connected in parallel and then connected to the power input of the temperature-humidity acquisition module, and a grid electrode of the sixth field effect tube is mutually connected in parallel with a drain electrode of the first field effect tube and a drain electrode of the fourth field effect tube; the drain electrode of the fifth field effect transistor is connected with the gate electrode of the seventh field effect transistor, and leads from the connecting wire to the interrupt input and the digital input of the temperature and humidity acquisition module; the temperature and humidity acquisition module is connected with the information receiving and transmitting control terminal in a wireless mode; the negative electrode of the power supply of the rectifying module, the negative electrode of the power supply of the battery charging module, the negative electrode of the power supply of the temperature and humidity acquisition module and the negative electrode of the power supply of the pressure switch module are connected with the negative electrode of the battery; the first field effect transistor, the second field effect transistor, the fourth field effect transistor and the fifth field effect transistor are all N-channel enhanced MOS transistors; the third field effect transistor, the sixth field effect transistor and the seventh field effect transistor are all P-channel enhanced MOS transistors.

2. A regulatory system as defined in claim 1, wherein the pressure switch module comprises: a resistor R1, a resistor R2, a stress button and a capacitor; the positive electrode of the capacitor is connected with one end of a resistor R1 in parallel and then connected with the positive electrode of the battery, and the other end of a resistor R1 is connected with the normally open contact of the stress button in series and then connected with the negative electrode of the capacitor; the negative electrode of the capacitor is connected with one end of a resistor R2 after being connected in series with a normally closed contact of the stress button, and the other end of the resistor R2 is connected with the negative electrode of the battery; the gate of the fifth FET is connected to the connection of the normally closed contact of the force button and the resistor R2 through a lead.

3. The monitoring system according to claim 1, wherein the temperature and humidity acquisition module comprises a temperature and humidity detection processing control unit, a wireless transceiver unit, a temperature sensor, a humidity sensor, a high-frequency antenna and an indicator light; the temperature and humidity detection processing control unit is sequentially connected with the wireless transceiving unit and the high-frequency antenna in series and then is connected with the information transceiving control terminal in a wireless mode; the temperature and humidity detection processing control unit is connected with a temperature sensor, a humidity sensor, a drain electrode of a fifth field effect transistor and a battery charging module in an input mode; the output of the temperature and humidity detection processing control unit is connected with a grid and an indicator light of a fourth field effect tube; and the drain electrode of the fifth field effect transistor is connected with the interrupt input and the digital input of the temperature and humidity detection processing control unit.

4. A regulatory system as defined in claim 2 wherein the capacitor is a tantalum capacitor or a niobium capacitor.

5. A regulatory system as in claim 2 wherein the force button is a two-way contact switch, one of which is normally open and the other of which is normally closed.

6. A method for implementing a supervision system according to any of claims 1 to 3, characterized in that it comprises the following steps:

the method comprises the steps that when an information receiving and transmitting control terminal outputs routing inspection control information to an excitation/charging source module, an excitation signal is sent out, and an electric work of a temperature and humidity acquisition module in a granary temperature and humidity monitoring unit is excited;

secondly, when the information transceiving control terminal outputs charging control information to the excitation/charging source module, a charging signal is sent out, and batteries in the granary temperature and humidity monitoring unit are charged wirelessly;

thirdly, when the response is to the interrupt application sent by the pressure switch module through the output of the fifth field effect transistor, the current turning over or grain discharging or grain stealing is determined, the uploading pressure switch module outputs information to the information transceiving control terminal, and the information transceiving control terminal performs corresponding control according to the setting of the time period function:

when the time period is set as a grain discharging time period or a grain turning time period, returning a grain turning/discharging identification code to a corresponding granary temperature and humidity monitoring unit, and when the time period is set as the grain turning time period, judging the grain turning quality: accumulating the granary temperature and humidity monitoring units which have output information and are uploaded in the granary in the time period, calculating the ratio of the granary temperature and humidity monitoring units to the total amount of the granary temperature and humidity monitoring units in the granary, and setting the ratio as: the total occupancy rate of the output information is set and used as an evaluation index of the turning quality, the higher the total occupancy rate of the output information is, the better the turning quality is determined, otherwise,

when the time period is set as an anti-theft time period, the anti-theft identification code is transmitted back to the corresponding granary temperature and humidity monitoring unit, alarm grading judgment is carried out: setting a specified time length, accumulating the granary temperature and humidity monitoring units which have the output information uploaded within the specified time length, calculating the ratio of the granary temperature and humidity monitoring units to the total amount of the granary temperature and humidity monitoring units arranged in the grain stack, and setting the ratio as follows: the score occupation ratio of the output information is adopted as an evaluation index of alarm grading, the higher the score occupation ratio of the output information in a short time is, the serious theft in the time is determined, the alarm frequency is increased, the higher the top level of upward alarm layer by layer is, and the opposite is realized.

Images