CN204741999U - Realize intelligent warmhouse booth system of high in clouds control - Google Patents

Abstract

The utility model relates to a realize intelligent warmhouse booth system of high in clouds control, including the warmhouse booth who plants the plant, management terminal, high in the clouds server and terminal in coordination, socket and mains connection are far controlled through intelligence to warmhouse booth, warmhouse booth includes central control system, the zigBee repeater, environmental monitoring system, environmental factor compensating system and security protection system, control terminal and central processing unit communication back, the data transmission that physiological feature collection system gathered each sensor gives central processing unit, environmental monitoring system's sensor and the security protection device in the security protection system send the data that detect for central processing unit respectively, central processing unit gives control terminal with the data transmission who receives, central processing unit receives the control terminal order, device among the order environmental factor compensating system starts, the terminal obtains the supplementary back of control terminal approval in coordination, and lug connection central processing unit uses, controls the device in the warmhouse booth, has realized the long -range guidance of agriculture expert to planting the family.

Description

A kind of Intelligent greenhouse system realizing high in the clouds monitoring

Technical field

The utility model relates to green house field, particularly relates to a kind of Intelligent greenhouse system realizing high in the clouds monitoring.

Background technology

In recent years, along with the development of the communication technology, computer technology and sensor technology, the technology of Internet of things grown up in conjunction with three kinds of technical advantages is increasingly mature.Along with the pay attention to day by day of country to agriculture, rural areas and farmers problem, accelerate development agriculture Internet of Things, promote the degree of depth that is information-based, agricultural modernization to merge, become the new trend of modern agricultural development, technology of Internet of things is also day by day extensive in the application of agriculture field, green house plant husbandry, as the pith of agriculture field, also strengthens gradually to the application demand of technology of Internet of things.

Green house plantation, as the pith of agriculture field, has extremely important impetus for solution agriculture, rural areas and farmers problem.In green house, the growth of plant is not only subject to the impact of greenhouse factor, such as booth air themperature, air humidity, intensity of illumination etc., and is subject to the impact of the plant own growth factor.

But, still there are some problems in existing green house plantation: on the one hand, greenhouse gardening personnel are not owing to possessing specialized knowledge, can not suit the remedy to the case for the illness that may occur in plant strain growth, often need to invite nonlocal expert's field observation, suit the remedy to the case, this has delayed the time of personnel undoubtedly, have impact on the therapeutic efficiency of plant illness, and in the green house that cultivated area is larger, accurately cannot locate those plant occurring illness, add the difficulty finding illness plant; Moreover current greenhouse gardening trends towards large area, the plantation of many slum-dwellers, but in existing greenhouse gardening process, become more meticulous, automation plantation degree is lower, and workload is large, efficiency is low; On the other hand, the design of existing green house can not carry out effective safety monitoring conscientiously, and green house is destroyed by natural calamity or is that the phenomenon destroyed of setting on fire happens occasionally by people, seriously compromises the interests at plantation family, have impact on social stability harmony.

Utility model content

Technical problem to be solved in the utility model provides a kind of for above-mentioned prior art can realize becoming more meticulous in green house, automation plantation, real-time monitoring green house secure environment, can obtain again the Intelligent greenhouse system realizing high in the clouds monitoring of agricultural experts' remote diagnosis, guidance in time.

The technical scheme in the invention for solving the above technical problem is: a kind of Intelligent greenhouse system realizing high in the clouds monitoring, it is characterized in that, comprise the green house of plant of planting, office terminal, cloud server and collaborative terminal, described green house is electrically connected with city by intelligent remote control socket, wherein:

Described plant is provided with RFID label chip, GPS locating module and physiological characteristic harvester, described physiological characteristic harvester comprises first microprocessor and the first ZigBee module be connected with first microprocessor respectively, displacement transducer, timer, blade humidity sensor, leaf temperature sensor and micro-sensor, described first microprocessor is connected with RFID label chip, GPS locating module respectively, wherein:

Plant title, numbering data for storing title and the numbering of described plant, and are sent to first microprocessor by described RFID label chip;

Described GPS locating module, for locating the position of current plant, and sends to first microprocessor by locator data;

Growth length data for gathering the growth length data of plant, and are sent to first microprocessor by institute's displacement sensors;

Described blade humidity sensor, leaf temperature sensor and micro-sensor, be respectively used to gather blade humidity data, leaf temperature data, trace element data, and the blade humidity data of collection, leaf temperature data, trace element data are sent to first microprocessor;

Described first microprocessor, for the growth length data that the chronometric data according to timer, displacement transducer gather, calculate the growth rate of plant, and plant title and numbering data, plant strain growth speed, trace element data are sent to the central processing unit of central control system by the first ZigBee module;

Described green house comprises environmental monitoring system, envirment factor bucking-out system, safety-protection system, ZigBee repeater and central control system, wherein:

Described environmental monitoring system comprises the air temperature sensor, air humidity sensor, intensity of illumination sensor, oxygen concentration sensor, CO2 concentration sensor, air velocity transducer, NH3 sensor, soil temperature sensor, soil humidity sensor and the P in soil H value sensor that are respectively arranged with the second ZigBee module;

Described envirment factor bucking-out system comprises the illumination lamp of the tunable radiation emitting color being respectively equipped with the 3rd ZigBee module, heating lamp, fan, CO2 generator, ventilation unit and spray equipment;

Described safety-protection system comprises the infrared sensor, CO concentration sensor, Smoke Sensor, rotating camera, ultraviolet sterilizer and the inclination sensor that are respectively equipped with the 4th ZigBee module, and described inclination sensor is arranged on the sidewall of green house;

Described ZigBee repeater, for receiving, forwarding data that the first ZigBee module, the 2nd ZigBee mould, the 3rd ZigBee module and the 4th ZigBee module send respectively to central processing unit, and the order forwarding central processing unit is to the first ZigBee module, the second ZigBee module, the 3rd ZigBee module and the 4th ZigBee module;

Described central control system is comprised central processing unit, memory and is realized the communication module of wired connection by the network port and outer net, and described central processing unit is connected respectively with memory, communication module, ZigBee repeater, wherein:

Described central processing unit, on the one hand for receiving, the unloading first microprocessor data of being sent by the first ZigBee module are to memory, receive, each sensor sends respectively by the second ZigBee module in unloading environmental monitoring system data to memory, the data that each sensor in first microprocessor, infrared sensor, CO concentration sensor, Smoke Sensor, inclination sensor, environmental monitoring system sends are supplied to office terminal by communication module simultaneously; On the other hand, the control instruction of receiving management terminal, order heating lamp, fan, CO2 generator, ventilation unit, spray equipment, rotating camera, ultraviolet sterilizer perform the operation corresponding with office terminal instruction; Order illumination lamp sends the light of office terminal designated color;

Described memory, for storing the various data of central processing unit unloading, and calls for office terminal;

Described communication module, for realizing the data transmission between central processing unit and office terminal;

Described ZigBee repeater, for receiving, forwarding data that the first ZigBee module, the 2nd ZigBee mould, the 3rd ZigBee module and the 4th ZigBee module send respectively to central processing unit, and the order forwarding central processing unit is to the first ZigBee module, the second ZigBee module, the 3rd ZigBee module and the 4th ZigBee module;

Described office terminal, is connected with the central processing unit of cloud server and central control system respectively, for sending controling instruction to central processing unit, sends and disconnects socket power instruction to intelligent remote control socket; After establishing a communications link with collaborative terminal, the collaborative terminal of license is called, sending controling instruction is to central processing unit;

Described cloud server connects described collaborative terminal, and after collaborative terminal is by the authorization information of cloud server, realizes the communication connection of office terminal and collaborative terminal;

Described collaborative terminal, for realizing and the communication of office terminal, and after obtaining the license of office terminal, call, sending controling instruction is to central processing unit;

Described intelligent remote control socket comprises the gsm communication module, the second microprocessor and the relay control module that are provided with SIM, described second microprocessor is connected with gsm communication module, relay control module respectively, wherein, described second microprocessor, for after the cut-offing instruction receiving default SIM, order relay control module disconnects socket power, stops civil power to the power supply of green house;

Described first ZigBee module, the second ZigBee module, the 3rd ZigBee module and the 4th ZigBee module are equipped with thermo-electric conversion module and chargeable power module, and described thermo-electric conversion module is connected with power module.

Further, described micro-sensor is the sensor gathering Zn-ef ficiency or manganese element or boron element or molybdenum element or ferro element or copper.

Further, described physiological characteristic harvester also comprises any combination of photosynthetic rate sensor or transpiration rate sensor or stem stalk thickness change sensor or fruit growth sensor or photosynthetic rate sensor, transpiration rate sensor, stem stalk thickness change sensor and fruit growth sensor.

Further, described environmental monitoring system also comprises the soil salinity sensor and level sensor that are respectively arranged with the second ZigBee module.

Further, described green house also comprises the trapping lamp communicated to connect with central processing unit.

Further, described central control system also comprises the GPRS communication module or gsm communication module or LTE communication module of carrying out wireless connections with central processing unit, and described office terminal and collaborative terminal are smart mobile phone or panel computer or PC computer.

Further, the light color that described illumination lamp sends is red or blue or purple.

Compared with prior art, the utility model has the advantage of: after the central processing unit in control terminal and central control system establishes a communications link, the data that each sensor gathers by the physiological characteristic harvester on plant send to central processing unit through the first ZigBee module, various safety devices in the sensor of environmental monitoring system and safety-protection system then by the data that detect respectively through the second ZigBee module, 3rd ZigBee module sends to central processing unit, then by central processing unit, the data of reception are sent to control terminal, simultaneously, central processing unit receives the order of control terminal, device startup work in command environment compensation factors system, after the collaborative terminal of control terminal license is auxiliary, collaborative terminal is directly connected with central processing unit, call, the device controlled in green house, thus both achieved becoming more meticulous in green house, automation plantation, real-time monitoring green house secure environment, can obtain agricultural experts' remote diagnosis, guidance again in time.

Accompanying drawing explanation

Fig. 1 is the Intelligent greenhouse system architecture schematic diagram realizing high in the clouds monitoring in the utility model embodiment;

Fig. 2 is the apparatus structure schematic diagram on plant in green house shown in Fig. 1;

Fig. 3 is the structural representation of environmental monitoring system in green house shown in Fig. 1;

Fig. 4 is the structural representation of envirment factor bucking-out system in green house shown in Fig. 1;

Fig. 5 is the structural representation of safety-protection system in green house shown in Fig. 1;

Fig. 6 is the structural representation of the central control system of green house shown in Fig. 1;

Fig. 7 is the annexation schematic diagram of power module, thermo-electric conversion module and each ZigBee module in green house shown in Fig. 1;

Fig. 8 is the structural representation of intelligent remote control socket in the system of Intelligent greenhouse shown in Fig. 1.

Embodiment

Below in conjunction with accompanying drawing embodiment, the utility model is described in further detail.

As shown in Figure 1, the Intelligent greenhouse system realizing high in the clouds monitoring in the utility model embodiment, comprise the green house 1 of plant 10 of planting, office terminal 2, cloud server 3 and collaborative terminal 4, green house 1 is electrically connected with city by intelligent remote control socket 5, wherein, the situation of green house 1 and plant 10, for for plantation family, is grasped in office terminal 2, controls the various device work in green house 1; Collaborative 4, terminal is supplied to agricultural experts and uses, for plantation family provides long-range technical support and guidance.

As shown in Figure 2, plant 10 is provided with RFID label chip 100, GPS locating module 102 and physiological characteristic harvester 101, the first ZigBee module 1011, displacement transducer 1012, timer 1013, blade humidity sensor 1014, leaf temperature sensor 1020 and micro-sensor 1015 that physiological characteristic harvester 101 comprises first microprocessor 1010 and is connected with first microprocessor 1010 respectively, first microprocessor 1010 connects RFID label chip 100 and GPS locating module 102 respectively.Wherein, plant title, numbering data for storing title and the numbering of plant 10, and are sent to first microprocessor 1010 by RFID label chip 100; Described GPS locating module 102, for locating the position of current plant 10, and sends to first microprocessor 1010 by locator data;

First ZigBee module 1011, as the communication module of physiological characteristic harvester 101, is used for outwards transmitting the data that first microprocessor 1010 processes.

Growth length data for gathering the growth length data of plant 10, and are sent to first microprocessor 1010 by displacement transducer 1012;

Blade humidity sensor 1014, leaf temperature sensor 1020 and micro-sensor 1015, be respectively used to gather blade humidity data, leaf temperature data, trace element data, and the blade humidity data of collection, leaf temperature data, trace element data are sent to first microprocessor 1010;

First microprocessor 1010, according to the chronometric data of timer 1013, the growth length data of displacement transducer 1012 collection, calculate the growth rate of plant 10, such as, in the t of timer 1013, two moment of t+24h, the displacement data that displacement transducer 1012 collects plant 10 is respectively Hmm, (H+2.4) mm, then can know, the growth rate of plant 10 in 24 hours is 0.1mm/h; Then plant title and numbering data, plant strain growth speed, trace element data are sent to the central processing unit 111 of central control system 11 by first microprocessor 1010 by the first ZigBee module 1011.

As shown in Figure 1, green house 1 comprises central control system 11, ZigBee repeater 12, environmental monitoring system 13, envirment factor bucking-out system 14 and safety-protection system 15, wherein:

Environmental monitoring system 13 comprises the air temperature sensor 131, air humidity sensor 132, intensity of illumination sensor 133, oxygen concentration sensor 134, CO2 concentration sensor 135, air velocity transducer 136, NH3 sensor 137, soil temperature sensor 138, soil humidity sensor 139 and the P in soil H value sensor 1310 that are respectively arranged with the second ZigBee module 130, as shown in Figure 3;

Envirment factor bucking-out system 14 comprises the illumination lamp 141 of the tunable radiation emitting color being respectively equipped with the 3rd ZigBee module 140, heating lamp 142, fan 143, CO2 generator 144, ventilation unit 145 and spray equipment 146, as shown in Figure 4.Because plant is in process of growth, the color for light is more responsive, and especially ruddiness, blue light and purple light are particularly evident for the photosynthesis of plant, and therefore, as preferably, the light color that illumination lamp 141 sends is red or blue or purple.

Safety-protection system 15 comprises the infrared sensor 151, CO concentration sensor 152, Smoke Sensor 153, rotating camera 154, ultraviolet sterilizer 155 and the inclination sensor 156 that are respectively equipped with the 4th ZigBee module 150, as shown in Figure 5, wherein,

Infrared sensor 151 detects in green house 1 whether have personnel activity;

CO concentration sensor 152 detects the concentration of the toxic gas-CO in green house 1, can not be poisoning because sucking CO when guaranteeing that personnel enter in green house 1;

Smoke Sensor 153 detects in green house 1 whether have smog, to detect whether fire-prone;

Rotating camera 154, for rotating, adjusting the angle of camera, is used for monitoring the situation in green house 1, is convenient to plant 10 is observed in office terminal 2 growing way situation by camera 154 simultaneously;

Ultraviolet sterilizer 155, for after the sterilization instruction receiving central processing unit 111, carries out sterilization in green house 1;

Inclination sensor 156 is arranged on the sidewall of green house 1, is used for detecting green house 1 whether run-off the straight, to guarantee that green house 1 can not cause damage because toppling in time.

Central control system 11 is comprised central processing unit 111, memory 112 and is realized the communication module 113 of wired connection by the network port and outer net, central processing unit 111 is connected, see Fig. 6 respectively with memory 112, communication module 113, ZigBee repeater 12.Wherein:

Central processing unit 111, on the one hand for receiving, unloading first microprocessor 1010 data of being sent by the first ZigBee module 1011 are to memory 112, receive, each sensor sends respectively by the second ZigBee module 130 in unloading environmental monitoring system 13 data to memory 112, the data that each sensor in first microprocessor 1010, infrared sensor 132, CO concentration sensor 152, Smoke Sensor 153, inclination sensor 135, environmental monitoring system 13 sends are supplied to office terminal 2 by communication module 113 simultaneously; On the other hand, the control instruction of receiving management terminal 2, order heating lamp 142, fan 143, CO2 generator 144, ventilation unit 145, spray equipment 146, rotating camera 154, ultraviolet sterilizer 155 perform the operation corresponding with office terminal 2 instruction; Order illumination lamp 141 sends the light of office terminal 2 designated color.

Memory 112, for storing the various data of central processing unit 111 unloading, and calls for office terminal 2.

Communication module 113, for realizing the data transmission between central processing unit 111 and office terminal 2.

ZigBee repeater 12, transponder when communicating with central processing unit 111 as each ZigBee module, for receiving, forwarding data that the first ZigBee module 1011, the 2nd ZigBee mould 130, the 3rd ZigBee module 140 and the 4th ZigBee module 150 send respectively to central processing unit 111, and the order forwarding central processing unit 111 is to the first ZigBee module 1011, second ZigBee module 130, the 3rd ZigBee module 140 and the 4th ZigBee module 150.

Office terminal 2, connects the central processing unit 111 of cloud server 3 and central control system 11 respectively, for sending controling instruction to central processing unit 111, sends and disconnects socket power instruction to intelligent remote control socket 5; And after establishing a communications link with collaborative terminal 4 in office terminal 2, the collaborative terminal 4 of license is called, sending controling instruction to central processing unit 111, completed the auxiliary operation of collaborative terminal 4 pairs of office terminals 2.

Cloud server 3 connects collaborative terminal 4, and after collaborative terminal 4 is by the authorization information of cloud server 3, realizes the intercommunication mutually of connecting management terminal 2 and collaborative terminal 4.

Collaborative terminal 4, for realizing the communication with office terminal 2, and after obtaining the license of office terminal 2, call, sending controling instruction is to central processing unit 111.Specifically, after permitting that collaborative terminal 4 is called in office terminal 2, controlling central processing unit 111, collaborative 4, terminal directly can obtain the various situations in green house 1, and the various equipment in green house 1 are directly controlled, thus realize the Illnesses Diagnoses that agricultural experts utilize plant 10 in collaborative terminal 4 pairs of green houses 1, and then provide technological guidance and help for planting family.

Intelligent remote control socket 5 comprises gsm communication module 50, second microprocessor 51 that is provided with SIM and relay control module 52, second microprocessor 51 is connected with gsm communication module 50, relay control module 52 respectively, shown in Figure 8.Wherein, the second microprocessor 51, for after the cut-offing instruction being received default SIM by gsm communication module 50, order relay control module 52 disconnects socket power, stops civil power to the power supply of green house 1.Such as, second micro-process 51 performs the cut-offing instruction preset SIM1 card and send, and does not perform any instruction of other SIMs transmission.When green house 1 once there is fire condition, and plant family away from green house 1 time, plantation family then utilizes the control terminal 2 of built-in default SIM1 card to send the instruction of disconnection socket power, carry out power-off in green house 1, again cause fire spread to prevent electric wire and electrical equipment by influence of fire.

First ZigBee module 1011, second ZigBee module 130, the 3rd ZigBee module 140 and the 4th ZigBee module 150 are equipped with thermo-electric conversion module 6 and chargeable power module 7, thermo-electric conversion module 6 is connected with power module 7, shown in Figure 7.Owing to usually having higher temperature in green house 1, therefore according to the principle of thermoelectricity conversion, can utilize thermo-electric conversion module 6 that the heat in green house 1 is converted to electric energy, thus charge for power module 7, the green achieving the energy is produced.Much more no longer wherein, thermoelectricity transfer principle belongs to prior art, to repeat herein.

In order to the needs of the different cultivars plant that adapts to plant in green house 1, accurately to obtain the absorbing state of different cultivars plant to micro-Zn-ef ficiency, manganese element, boron element, molybdenum element, ferro element or copper, micro-sensor 1015 is the sensor gathering Zn-ef ficiency or manganese element or boron element or molybdenum element or ferro element or copper.According to actual needs, micro-sensor 1015 can also set up the sensor gathering other trace elements.

In order to obtain the Photosynthetic rate of plant 10, stem stalk thickness situation of change or fruit growth situation further, physiological characteristic harvester 101 also comprises any combination of photosynthetic rate sensor 1016 or transpiration rate sensor 1017 or stem stalk thickness change sensor 1018 or fruit growth sensor 1019 or photosynthetic rate sensor 1016, transpiration rate sensor 1017, stem stalk thickness change sensor 1018 and fruit growth sensor 1019.

In order to detect salinity situation and the water level conditions of soil in green house 1, soil salinity sensor 1311 and the level sensor 1312 with the second ZigBee module 130 are also set respectively in environmental monitoring system 13.

In order to prevent insect pest to the harm of plant 10 in green house 1, green house 1 also comprises trapping lamp 16, and trapping lamp 16 and central processing unit 111 communicate to connect.When trapping lamp 16 receives the startup desinsection order of central processing unit 111, then start to carry out insect pest and kill work.

Utilize office terminal 2 to control in real time in different place for the ease of plantation family, understand the situation of green house 1, central control system 11 also comprises the GPRS communication module or gsm communication module or LTE communication module of carrying out wireless connections with central processing unit 111.

Conveniently agricultural experts utilize different collaborative terminals 4 to carry out technical support and help to plantation family, and office terminal 2 and collaborative terminal 4 are smart mobile phone or panel computer or PC computer.

Below in conjunction with Fig. 1 to Fig. 8, the working condition of the Intelligent greenhouse system of high in the clouds monitoring in the utility model embodiment is described:

(1) green house 1 is electrically connected with city by intelligent remote control socket 5, thus ensures the various power devices in green house 1 to provide electric energy;

(2) planting family utilizes office terminal 2 to establish a communications link with the central processing unit 111 in green house 1;

(3) data obtained after processing through first microprocessor 1010 are outwards sent by the first ZigBee module 1011 by the physiological characteristic harvester 101 on plant 10, and are transmitted to central processing unit 111 through ZigBee repeater 12;

(4) plant 10 title, numbering data are sent to first microprocessor 1010 by RFID label chip 100; Meanwhile, the current location information of this plant 10 is also sent to first microprocessor 1010 by GPS locating module 102;

(5) corresponding data collected separately is outwards sent by the second ZigBee module 130 by the air temperature sensor 131 in environmental monitoring system 13, air humidity sensor 132, intensity of illumination sensor 133, oxygen concentration sensor 134, CO2 concentration sensor 135, air velocity transducer 136, NH3 sensor 137, soil temperature sensor 138, soil humidity sensor 139 and P in soil H value sensor 1310 respectively, and after ZigBee repeater 12 forwards, send to central processing unit 111;

(6) corresponding data collected separately is outwards sent by the 4th ZigBee module 150 by the infrared sensor 151 in safety-protection system 15, CO concentration sensor 152, Smoke Sensor 153, inclination sensor 156 respectively, and also after ZigBee repeater 12 forwards, send to central processing unit 111;

(7) the family corresponding data situation that environmentally each sensor collects in monitoring system 13 and safety-protection system 15 is planted, judge, and as required, control terminal 2 is utilized to send the compensation order of the respective environment factor to envirment factor bucking-out system 14, order heating lamp 142, fan 143, CO2 generator 144, ventilation unit 145 or spray equipment 146 perform corresponding startup work, and order illumination lamp 141 sends the light of designated color; Thus make the state that envirment factor reaches required;

(8) if plantation family needs to understand the growing way situation of video information in green house 1 or plant 10, then utilize control terminal 2 to send order respectively and carry out video acquisition to rotating camera 154, then feedback video data is to control terminal 2; As sterilization need be carried out to green house 1 environment, then send sterilization order and carry out sterilization to ultraviolet sterilizer 155;

(9) when planting the plant 10 in family discovery green house 1 and occurring illness, then to set up with cloud server 3 at control terminal 2 and communicate, and after agricultural experts use collaborative terminal 4 and cloud server 3 also to establish a communications link, the collaborative terminal 4 of license is directly called, is controlled central processing unit 111; Agricultural experts then directly send dependent instruction to central processing unit 111 by collaborative terminal 4, and the device be transmitted in green house 1 by central processing unit 111 performs relevant corresponding instruction, thus achieve the accurate location of agricultural experts to plant 10 in green house 1 and the remote diagnosis of plant illness, reach the remote guide to plantation family and technical support;

(10) when fire condition appears in green house 1, and time plantation family distance green house 1 is distant again, plantation family sends deenergization instruction to intelligent remote control socket 5 by the control terminal 2 with default SIM1 card;

(11) the second microprocessor 52 in intelligent remote control socket 5 is through judging that this SIM1 card is as after default card, then order relay control module 52 deenergization, cut off the connection of green house 1 and civil power, thus prevent electric wire and electrical equipment again to cause the generation of fire spread situation by influence of fire.

Claims (7)

1. realize an Intelligent greenhouse system for high in the clouds monitoring, it is characterized in that, comprise the green house of plant of planting, office terminal, cloud server and collaborative terminal, described green house is electrically connected with city by intelligent remote control socket, wherein:

Described plant is provided with RFID label chip, GPS locating module and physiological characteristic harvester, described physiological characteristic harvester comprises first microprocessor and the first ZigBee module be connected with first microprocessor respectively, displacement transducer, timer, blade humidity sensor, leaf temperature sensor and micro-sensor, described first microprocessor is connected with RFID label chip, GPS locating module respectively, wherein:

Plant title, numbering data for storing title and the numbering of described plant, and are sent to first microprocessor by described RFID label chip;

Described GPS locating module, for locating the position of current plant, and sends to first microprocessor by locator data;

Growth length data for gathering the growth length data of plant, and are sent to first microprocessor by institute's displacement sensors;

Described blade humidity sensor, leaf temperature sensor and micro-sensor, be respectively used to gather blade humidity data, leaf temperature data, trace element data, and the blade humidity data of collection, leaf temperature data, trace element data are sent to first microprocessor;

Described first microprocessor, for the growth length data that the chronometric data according to timer, displacement transducer gather, calculate the growth rate of plant, and plant title and numbering data, plant strain growth speed, trace element data are sent to the central processing unit of central control system by the first ZigBee module;

Described green house comprises environmental monitoring system, envirment factor bucking-out system, safety-protection system, ZigBee repeater and central control system, wherein:

Described environmental monitoring system comprises the air temperature sensor, air humidity sensor, intensity of illumination sensor, oxygen concentration sensor, CO2 concentration sensor, air velocity transducer, NH3 sensor, soil temperature sensor, soil humidity sensor and the P in soil H value sensor that are respectively arranged with the second ZigBee module;

Described envirment factor bucking-out system comprises the illumination lamp of the tunable radiation emitting color being respectively equipped with the 3rd ZigBee module, heating lamp, fan, CO2 generator, ventilation unit and spray equipment;

Described safety-protection system comprises the infrared sensor, CO concentration sensor, Smoke Sensor, rotating camera, ultraviolet sterilizer and the inclination sensor that are respectively equipped with the 4th ZigBee module, and described inclination sensor is arranged on the sidewall of green house;

Described ZigBee repeater, for receiving, forwarding data that the first ZigBee module, the 2nd ZigBee mould, the 3rd ZigBee module and the 4th ZigBee module send respectively to central processing unit, and the order forwarding central processing unit is to the first ZigBee module, the second ZigBee module, the 3rd ZigBee module and the 4th ZigBee module;

Described central control system is comprised central processing unit, memory and is realized the communication module of wired connection by the network port and outer net, and described central processing unit is connected respectively with memory, communication module, ZigBee repeater, wherein:

Described central processing unit, on the one hand for receiving, the unloading first microprocessor data of being sent by the first ZigBee module are to memory, receive, each sensor sends respectively by the second ZigBee module in unloading environmental monitoring system data to memory, the data that each sensor in first microprocessor, infrared sensor, CO concentration sensor, Smoke Sensor, inclination sensor, environmental monitoring system sends are supplied to office terminal by communication module simultaneously; On the other hand, the control instruction of receiving management terminal, order heating lamp, fan, CO2 generator, ventilation unit, spray equipment, rotating camera, ultraviolet sterilizer perform the operation corresponding with office terminal instruction; Order illumination lamp sends the light of office terminal designated color;

Described memory, for storing the various data of central processing unit unloading, and calls for office terminal;

Described communication module, for realizing the data transmission between central processing unit and office terminal;

Described ZigBee repeater, for receiving, forwarding data that the first ZigBee module, the 2nd ZigBee mould, the 3rd ZigBee module and the 4th ZigBee module send respectively to central processing unit, and the order forwarding central processing unit is to the first ZigBee module, the second ZigBee module, the 3rd ZigBee module and the 4th ZigBee module;

Described office terminal, is connected with the central processing unit of cloud server and central control system respectively, for sending controling instruction to central processing unit, sends and disconnects socket power instruction to intelligent remote control socket; After establishing a communications link with collaborative terminal, the collaborative terminal of license is called, sending controling instruction is to central processing unit;

Described cloud server connects described collaborative terminal, and after collaborative terminal is by the authorization information of cloud server, realizes the communication connection of office terminal and collaborative terminal;

Described collaborative terminal, for realizing and the communication of office terminal, and after obtaining the license of office terminal, call, sending controling instruction is to central processing unit;

Described intelligent remote control socket comprises the gsm communication module, the second microprocessor and the relay control module that are provided with SIM, described second microprocessor is connected with gsm communication module, relay control module respectively, wherein, described second microprocessor, for after the cut-offing instruction receiving default SIM, order relay control module disconnects socket power, stops civil power to the power supply of green house;

Described first ZigBee module, the second ZigBee module, the 3rd ZigBee module and the 4th ZigBee module are equipped with thermo-electric conversion module and chargeable power module, and described thermo-electric conversion module is connected with power module.

2. the Intelligent greenhouse system of high in the clouds according to claim 1 monitoring, is characterized in that, described micro-sensor is the sensor gathering Zn-ef ficiency or manganese element or boron element or molybdenum element or ferro element or copper.

3. the Intelligent greenhouse system of high in the clouds according to claim 1 monitoring, it is characterized in that, described physiological characteristic harvester also comprises any combination of photosynthetic rate sensor or transpiration rate sensor or stem stalk thickness change sensor or fruit growth sensor or photosynthetic rate sensor, transpiration rate sensor, stem stalk thickness change sensor and fruit growth sensor.

4. the Intelligent greenhouse system of high in the clouds according to claim 1 monitoring, it is characterized in that, described environmental monitoring system also comprises the soil salinity sensor and level sensor that are respectively arranged with the second ZigBee module.

5. the Intelligent greenhouse system of high in the clouds according to claim 1 monitoring, it is characterized in that, described green house also comprises the trapping lamp communicated to connect with central processing unit.

6. the Intelligent greenhouse system of high in the clouds according to any one of claim 1 to 5 monitoring, it is characterized in that, described central control system also comprises the GPRS communication module or gsm communication module or LTE communication module of carrying out wireless connections with central processing unit, and described office terminal and collaborative terminal are smart mobile phone or panel computer or PC computer.

7. the Intelligent greenhouse system of high in the clouds according to any one of claim 1 to 5 monitoring, is characterized in that, the light color that described illumination lamp sends is red or blue or purple.