CN211979514U - Modernization big-arch shelter environment monitoring device - Google Patents

Abstract

The utility model discloses a modernization big-arch shelter environment monitoring device, including the butt joint, the butt joint upper end just is located the upper end surface of burying branch underground and has set firmly the basin body that catchments, the fat body shell is installed to the upper end of the basin body that catchments, the upper end surface of the basin body that catchments is close to the intermediate position and has seted up the arc groove that catchments, the upper end surface intermediate position of the basin body that catchments has set firmly the top end, the inboard intermediate position of top end is provided with the central pillar, the lower extreme surface intermediate position of butt joint is provided with buries branch underground, the lower extreme surface of burying branch underground has set firmly the conical head, the surface both sides of central pillar all are provided with two sets of conveying poles. This big-arch shelter monitoring device can the energy saving in the time, effectively simplifies the numerous and diverse process of installation, effectively utilizes unnecessary solar energy, utilizes the water of enrichment to water crops, and the water economy resource, air composition oxygen content carry out the secondary and detect, ensure the accurate nature of environmental monitoring detection data.

Description

Modernization big-arch shelter environment monitoring device

Technical Field

The utility model relates to a big-arch shelter environmental monitoring technical field specifically is a modernization big-arch shelter environmental monitoring device.

Background

The environment monitoring module realizes the real-time environment data display of the greenhouse such as air temperature, air humidity, soil temperature, soil humidity, illuminance, carbon dioxide concentration, oxygen concentration, soil pH value and the like, and can also check the historical data of various sensors, thereby being convenient for analyzing the crop growth condition; a sensor position map can be checked, so that the environmental data of each position of the greenhouse can be analyzed conveniently;

the greenhouse monitoring device on the market can not effectively utilize the existing solar energy, the installation process of the monitoring device is complex, moisture can not be enriched to water crops, the secondary verification detection function is not provided, the accuracy of environment monitoring detection data is not high, and therefore the modern greenhouse environment monitoring device is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a modernization big-arch shelter environment monitoring device to solve the big-arch shelter monitoring device on the market that proposes in the above-mentioned background art and can't effectively utilize current solar energy by large, monitoring device's installation is more complicated, can not enrich moisture and water crops, does not have the secondary check-up and detects the function, and the environmental monitoring detects the problem that the accuracy nature of data is not high.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a modernization big-arch shelter environment monitoring device, includes the butt joint, the upper end surface that butt joint upper end and lie in buried branch underground has set firmly the basin body that catchments, fat body shell is installed to the upper end of the basin body that catchments, the upper end surface of the basin body that catchments has seted up the arc groove that catchments near the intermediate position, the upper end surface intermediate position of the basin body that catchments has set firmly the apical cap, the inboard intermediate position of apical cap is provided with the central pillar, the lower extreme surface of fat body shell has set firmly waist post portion, the upper end surface intermediate position of fat body shell is provided with the bull stick, the bull stick is installed to the upper end of bull stick, the surface both sides of bull stick all are connected with solar panel, four groups steam through-holes have been seted up to the.

Preferably, a buried supporting rod is arranged at the middle position of the lower end surface of the butt joint, a conical head is fixedly arranged on the lower end surface of the buried supporting rod, two groups of transmission rods are arranged on both sides of the outer surface of the central pillar, oxygen probes are arranged on the transmission rods, an air component detector is arranged at the middle position inside the water collecting basin body, a power supply is arranged inside the fat shell close to the upper side, the middle position inside the boat-shaped hull close to the upper side is provided with a motor, the lower end of the power supply is provided with a central processing module, the right side of the central processing module is provided with a wireless communication module, the right end surface of the wireless communication module and the inner part of the fat shell are provided with wireless network interfaces, the inside of fat body shell is close to the downside and is located the upper end of central pillar and installs temperature sensor, the internally mounted of butt joint has soil moisture sensor.

Preferably, the basin body of catchmenting establishes the installation through burying branch and butt joint cover underground, fat body shell establishes the installation through waist post portion and top head cooperation and basin body cover of catchmenting, and wherein, the internal diameter of top head is less than the internal diameter of waist post portion.

Preferably, the transmission rod penetrates through the top end head and is connected with the central support, the waist column part is in a horn mouth shape, and the component detector is fixedly installed with the water collecting basin body through the central support.

Preferably, the rotating head is movably mounted with the motor through the rotating rod, and the water vapor through hole penetrates through the lumbar column part and is communicated with the fat shell.

Preferably, the output of the power supply is electrically connected with the input of the wireless communication module, the output of the wireless communication module is electrically connected with the input of the wireless network interface, the output of the central processing module is electrically connected with the input of the wireless communication module, the output of the composition detector is electrically connected with the input of the central processing module, and the outputs of the temperature sensor and the soil humidity sensor are respectively electrically connected with the input of the central processing module.

Compared with the prior art, the beneficial effects of the utility model are that:

the greenhouse monitoring device is provided with a solar panel and a motor, a support rod is embedded at the bottom of the greenhouse monitoring device and inserted into soil together with a conical head, the whole greenhouse monitoring device is installed and fixed, then sufficient illumination in the greenhouse is utilized to continuously provide solar energy for the solar panel, the electric energy of the solar panel is converted and stored in a power supply, the solar temperature on the surface of the solar panel is monitored in real time through the mutual cooperation of a central processing module and a temperature sensor, when the temperature is reduced to the daily irradiation average temperature, the central processing module reversely controls the power supply to be connected with the motor to rotate, so that the real-time tracking of the solar panel to the sunlight direction is adjusted, the electric energy is stored in advance, the energy is saved, meanwhile, the complicated installation process is effectively simplified, and redundant solar energy is effectively utilized;

the greenhouse monitoring device is provided with a water collecting pot body and a waist column part, water vapor in the greenhouse is enriched and collected by utilizing the horn mouth-shaped cambered surface of the waist column part, the water vapor in the air is enriched into the water collecting arc groove on the water collecting pot body, the water content is fully contacted with the water content through the transmission rod, the partial water content is transmitted to the air composition detector through the transmission rod for oxygen content detection, thereby judging the oxygen content in the air, realizing the real-time monitoring of the oxygen content in the air in the greenhouse, irrigating crops by using enriched water, saving water resources, then through the transpiration of steam, make steam pass through inside the steam through-hole gets into the fat shell, carry out the secondary by air composition detector to air composition oxygen content and detect, two sets of data contrast proofreading around the rethread central processing module is to the rethread central processing module, and accurate nature that environmental monitoring detected data is ensured to accurate detection data.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a schematic view of a partial structure of the present invention;

FIG. 3 is a partial front view of the present invention;

fig. 4 is a bottom view of the fat shell of the present invention;

fig. 5 is a schematic diagram of the circuit control of the present invention.

In the figure: 1. a butt joint; 2. burying a support rod; 3. a conical head; 4. a water collecting basin body; 5. boat-fruited sterculia seed shell; 7. a water collecting arc groove; 8. a top end; 9. a central support; 10. a transfer rod; 11. an oxygen probe; 12. a lumbar pillar portion; 13. an air composition detector; 14. a power source; 15. an electric motor; 16. a rotating rod; 17. turning the head; 18. a solar panel; 19. a water vapor through hole; 20. a wireless communication module; 21. a central processing module; 22. a wireless network interface; 23. a temperature sensor; 24. a soil moisture sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a modern greenhouse environment monitoring device comprises a butt joint 1, an embedded support rod 2 is arranged at the middle position of the lower end surface of the butt joint 1, a cone 3 is fixedly arranged on the lower end surface of the embedded support rod 2, a water collecting pot 4 is fixedly arranged at the upper end of the butt joint 1 and positioned at the upper end surface of the embedded support rod 2, a fat shell 5 is arranged at the upper end of the water collecting pot 4, a water collecting arc groove 7 is formed in the upper end surface of the water collecting pot 4 close to the middle position, a top end 8 is fixedly arranged at the middle position of the upper end surface of the water collecting pot 4, the water collecting pot 4 is sleeved with the butt joint 1 through the embedded support rod 2, the fat shell 5 is sleeved with the water collecting pot 4 through a waist column part 12 and the top end 8 in a matching mode, wherein the inner diameter of the top end 8 is smaller than that of the waist column part 12, the water collecting pot 4 and the waist column part 12 are arranged through the greenhouse monitoring device, and water vapor inside a greenhouse is enriched and, the water vapor in the air is enriched into the water collecting arc groove 7 on the water collecting basin body 4, the water is fully contacted with the water through the transmission rod 10, and the partial water is transmitted to the air component detector 13 through the transmission rod 10 to be detected by the oxygen content, so as to judge the oxygen content in the air;

a central pillar 9 is arranged at the middle position of the inner side of the top end 8, two groups of transmission rods 10 are arranged on two sides of the outer surface of the central pillar 9, an oxygen probe 11 is installed on each transmission rod 10, a waist pillar part 12 is fixedly arranged on the lower end surface of the fat shell 5, an air composition detector 13 is arranged at the middle position of the inner part of the water collecting basin body 4, a power supply 14 is arranged near the upper side in the fat shell 5, a motor 15 is installed near the upper side in the middle position of the inner part of the fat shell 5, a rotating rod 16 is arranged at the middle position of the upper end surface of the fat shell 5, the transmission rods 10 penetrate through the top end 8 and are connected with the central pillar 9, the waist pillar part 12 is in a horn mouth shape, the air composition detector 13 is fixedly installed with the water collecting basin body 4 through the central pillar 9, the output end of the power supply 14 is electrically connected with the input end of the wireless, due to the close fit of the top end 8 and the lumbar column part 12, water vapor can be effectively prevented from directly entering the fat shell 5, and internal elements are prevented from being directly eroded by the water vapor;

the upper end of the rotating rod 16 is provided with a rotating head 17, both sides of the outer surface of the rotating head 17 are connected with solar panels 18, four groups of water vapor through holes 19 are arranged on the outer surface of the waist column part 12 at equal intervals, the right side of the central processing module 21 is provided with a wireless communication module 20, the lower end of the power supply 14 is provided with a central processing module 21, the right end surface of the wireless communication module 20 and the inside of the fat shell 5 are provided with wireless network interfaces 22, the inside of the fat shell 5 is close to the lower side and the upper end of the central support 9 is provided with a temperature sensor 23, the inside of the butt joint 1 is provided with a soil humidity sensor 24, the rotating head 17 is movably arranged with the motor 15 through the rotating rod 16, the water vapor through holes 19 penetrate through the waist column part 12 and are communicated with the fat shell 5, the output end of the wireless communication module 20 is electrically, the output ends of the temperature sensor 23 and the soil humidity sensor 24 are respectively electrically connected with the input end of the central processing module 21, and the soil humidity sensor 24 inside the joint 1 is electrically connected with the central processing module 21 to complete the real-time monitoring of the soil humidity.

The working principle is as follows: for the greenhouse monitoring device, firstly, the solar panel 18 and the motor 15 are arranged on the greenhouse monitoring device, the support rod 2 embedded at the bottom of the greenhouse monitoring device and the conical head 3 are inserted into soil, the whole greenhouse monitoring device is installed and fixed, then, the solar panel 18 is continuously provided with solar energy by utilizing sufficient illumination inside the greenhouse, the electric energy of the solar panel 18 is converted and stored in the power supply 14, the central processing module 21 is matched with the temperature sensor 23 (model: DS18B20) to monitor the sunlight temperature on the surface of the solar panel 18 in real time, when the temperature is reduced to the average daily irradiation temperature, the central processing module 21 reversely controls the power supply 14 to switch on the motor 15 to rotate so as to adjust the real-time tracking of the solar panel 18 to the sunlight direction, the electric energy is stored in advance, the energy is saved, and the complicated installation process is effectively simplified, the redundant solar energy is effectively utilized; then, the soil humidity sensor 24 (model: SNT952WLT) in the joint 1 is electrically connected with the central processing module 21 to complete real-time monitoring of soil humidity, because the top end 8 is tightly matched with the waist column part 12, water vapor can be effectively prevented from directly entering the fat shell 5, the internal elements are prevented from being directly eroded by the water vapor, the oxygen probe 11 is effectively connected with the air composition detector 13 (model: CGS1) through the transmission rod 9 by the central support 9, the detection of the oxygen content in water is realized, the rotary head 17 can rotate around the rotary rod 16, the horizontal position of the solar panel 18 is adjusted in real time to reach the maximum contact area with sunlight, wherein when the central processing module 21 receives abnormal data, information is timely transmitted to a user through the wireless communication module 20, and the real condition of the internal environment of the greenhouse is timely informed; finally, the greenhouse monitoring device is provided with a water collecting pot body 4 and a waist column part 12, the water vapor in the greenhouse is collected by utilizing the horn-shaped cambered surface of the waist column part 12, the water vapor in the air is collected into a water collecting arc groove 7 on the water collecting pot body 4, the water vapor is fully contacted with the water through a transmission rod 10, part of the water is transmitted to an air component detector 13 through the transmission rod 10 for oxygen content detection, so that the oxygen content in the air is judged, the oxygen content in the air in the greenhouse is monitored in real time, the crops can be irrigated by utilizing the collected water, water resources are saved, then the water vapor enters the inside of the fat shell 5 through a water vapor through hole 19 under the transpiration effect of the water vapor, the air component detector 13 carries out secondary detection on the oxygen content in the air component, and then the central processing module 21 is used for comparing and correcting the front and back two groups of data, and the data are, the accuracy of environment monitoring is ensured.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a modernization big-arch shelter environment monitoring device, includes butt joint (1), its characterized in that: a water collecting pot body (4) is fixedly arranged on the upper end of the butt joint (1) and positioned on the upper end surface of the embedded support rod (2), the upper end of the water collecting pot body (4) is provided with a fat shell (5), the upper end surface of the water collecting pot body (4) close to the middle position is provided with a water collecting arc groove (7), a top end head (8) is fixedly arranged at the middle position of the upper end surface of the water collecting pot body (4), a central pillar (9) is arranged in the middle of the inner side of the top end head (8), a lumbar column part (12) is fixedly arranged on the lower end surface of the fat shell (5), a rotating rod (16) is arranged in the middle of the upper end surface of the fat shell (5), a rotary head (17) is arranged at the upper end of the rotary rod (16), solar panels (18) are connected with both sides of the outer surface of the rotary head (17), four groups of water vapor through holes (19) are formed in the outer surface of the waist column part (12) at equal intervals.

2. The modern greenhouse environment monitoring device of claim 1, wherein: the lower end surface middle position of butt joint (1) is provided with buries branch (2) underground, the lower end surface of burying branch (2) underground has set firmly conical head (3), the surface both sides of central pillar (9) all are provided with two sets of conveying pole (10), install oxygen probe (11) on conveying pole (10), the inside middle position of the basin body that catchments (4) is provided with air composition detector (13), the inside of fat shell (5) is close to the upside and is provided with power (14), the inside middle position of fat shell (5) is close to the upside and installs motor (15), the lower extreme of power (14) is provided with central processing module (21), the right side of central processing module (21) is provided with wireless communication module (20), the right-hand member surface of wireless communication module (20) just is located the internally mounted of fat shell (5) has wireless network interface (22), the inside of fat body shell (5) is close to the downside and is located the upper end of central pillar (9) and installs temperature sensor (23), the internally mounted of butt joint (1) has soil moisture sensor (24).

3. The modern greenhouse environment monitoring device of claim 1, wherein: the installation is established through burying branch (2) and butt joint (1) cover underground in catchment basin body (4), and installation is established with catchment basin body (4) cover through waist post portion (12) and top end (8) cooperation in fat body shell (5), and wherein, the internal diameter of top end (8) is less than the internal diameter of waist post portion (12).

4. The modern greenhouse environment monitoring device of claim 2, wherein: the transfer rod (10) penetrates through the top end head (8) and is connected with the central support column (9), the waist column part (12) is in a horn mouth shape, and the air component detector (13) is fixedly installed with the water collecting pot body (4) through the central support column (9).

5. The modern greenhouse environment monitoring device of claim 1, wherein: the rotating head (17) is movably arranged with the motor (15) through a rotating rod (16), and a water vapor through hole (19) penetrates through the waist column part (12) and is communicated with the fat shell (5).

6. The modern greenhouse environment monitoring device of claim 2, wherein: the output of power (14) and the input electric connection of wireless communication module (20), and the output of wireless communication module (20) and the input electric connection of wireless network interface (22), the output of central processing module (21) and the input electric connection of wireless communication module (20), the output of air composition detector (13) and the input electric connection of central processing module (21), the output of temperature sensor (23) and soil moisture sensor (24) respectively with the input electric connection of central processing module (21).

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