CN111386935A

CN111386935A - Geothermal supplementary circulation system based on modern agriculture and operation method thereof

Info

Publication number: CN111386935A
Application number: CN202010212888.0A
Authority: CN
Inventors: 鲍义东; 吴世海; 王江
Original assignee: Guizhou Aerospace Intelligent Agriculture Co ltd
Current assignee: Guizhou Aerospace Intelligent Agriculture Co ltd
Priority date: 2020-03-24
Filing date: 2020-03-24
Publication date: 2020-07-10
Anticipated expiration: 2040-03-24
Also published as: CN111386935B

Abstract

The invention discloses a geothermal supplementary circulation system based on modern agriculture and an operation method thereof. The technical field of modern agricultural greenhouses is related to, the temperature of soil in the greenhouses can be controlled, light entering the greenhouses can irradiate the upper surfaces of crops in the greenhouses, and meanwhile the side surfaces of the crops in the greenhouses can be irradiated. Comprises a main controller and a memory; a plurality of crop planting areas are uniformly distributed and divided on the ground in the greenhouse; shed top holes are oppositely arranged on the shed tops of the greenhouses right above each crop planting area in a one-to-one mode, so that a plurality of shed top holes are uniformly distributed on the shed tops of the greenhouses; an intelligent illumination control device is respectively and independently arranged in each shed roof hole one by one; each intelligent illumination control device comprises an upper illumination control mechanism and a side illumination control mechanism; the system also comprises a water heater, and geothermal heating pipes are buried under the ground of each crop planting area respectively.

Description

Geothermal supplementary circulation system based on modern agriculture and operation method thereof

Technical Field

The invention relates to the technical field of modern agriculture greenhouses, in particular to a geothermal supplementary circulation system based on modern agriculture and an operation method thereof.

Background

The greenhouse is arranged in the farmland to plant crops, and the temperature of soil in the greenhouse is low in low-temperature weather, so that a system capable of controlling the temperature of the soil in the greenhouse is very necessary.

In addition, generally all can set up a plurality of big-arch shelter next in the farmland, adjacent big-arch shelter directly will have the phenomenon of sheltering from sunshine, especially can shelter from the side illumination sunshine that gets into in the big-arch shelter from the big-arch shelter side. Among a plurality of adjacently arranged greenhouses, the side-illuminated sunlight of the greenhouse located in the middle is most easily blocked. After the side irradiation sunshine in the greenhouse is shielded, the illumination of crops in the greenhouse is poor, and the growth of the crops in the greenhouse is influenced. Therefore, it is necessary to design a system capable of illuminating the crops in the greenhouse from the side and the top.

Disclosure of Invention

The invention provides a geothermal supplementary circulation system based on modern agriculture and an operation method thereof, which can control the temperature of soil in a greenhouse, can control the light entering the greenhouse to irradiate the upper surface of crops in the greenhouse and the side surface of the crops in the greenhouse, and can control the intensity of the light.

In order to achieve the purpose, the invention adopts the following technical scheme:

the geothermal supplementary circulation system based on the modern agriculture comprises a main controller and a memory; a plurality of crop planting areas are uniformly distributed and divided on the ground in the greenhouse; shed top holes are oppositely arranged on the shed tops of the greenhouses right above each crop planting area in a one-to-one mode, so that a plurality of shed top holes are uniformly distributed on the shed tops of the greenhouses; an intelligent illumination control device is respectively and independently arranged in each shed roof hole one by one;

each intelligent illumination control device comprises an upper illumination control mechanism and a side illumination control mechanism;

the input light of each side illumination control mechanism is taken from the light on the corresponding upper illumination control mechanism;

the light output end of each upper illumination control mechanism is positioned right above the crop planting area right below the corresponding shed top hole; the light output end of each side light control mechanism is positioned above the side of the crop planting area right below the corresponding shed top hole, and the light output end of each side light control mechanism is positioned below the side of the light output end of the corresponding upper light control mechanism;

each upper illumination control mechanism comprises a first illumination sensor and a first address encoder, wherein the first illumination sensor is arranged on the corresponding upper illumination control mechanism and can detect the output illumination quantity of the upper illumination control mechanism;

each side illumination control mechanism comprises a second illumination sensor and a second address encoder, wherein the second illumination sensor is arranged on the corresponding side illumination control mechanism and can detect the input illumination quantity of the side illumination control mechanism, and the second address encoder is bound with the second illumination sensor;

the memory, the control end of each upper illumination control mechanism, the control end of each side illumination control mechanism, each first illumination sensor, each first address encoder, each second illumination sensor and each second address encoder are respectively connected with the main controller.

The geothermal supplementary circulation system based on modern agriculture further comprises a water heater, geothermal heating pipes are buried under the ground of each crop planting area respectively, a first temperature sensor bound with a third address encoder is placed on the ground of each crop planting area respectively, each geothermal heating pipe is provided with a first circulating pump respectively, one end of each geothermal heating pipe is connected to a water outlet of the corresponding first circulating pump through a first heat insulation water pipe respectively, a water inlet of each first circulating pump is connected to a water outlet of the water heater through a second heat insulation water pipe respectively, and the other end of each geothermal heating pipe is connected to a water inlet of the water heater through a third heat insulation water pipe; and the control end of the water heater, the control end of each first circulating pump, each third address encoder and each first temperature sensor are respectively connected with the main controller.

Hot water in the water heater can be circulated to the geothermal heating pipe through the first circulating pump to enable the geothermal heating pipe to generate heat, and therefore the soil temperature of the corresponding crop planting area is improved. Proper soil temperature can promote the growth of crops.

When in use, upper light irradiation data and upper light irradiation data of the upper light irradiation amount and the side light irradiation amount required by crops planted on each crop planting area in each period are stored in a memory in advance; under the control of the main controller, the upper illumination data detected by the first illumination sensor and the side illumination data detected by the second illumination sensor corresponding to each upper illumination control mechanism are detected, the crops on the corresponding crop planting areas are subjected to upper illumination according to the upper illumination data preset in the memory and required by the crops at different time periods, and meanwhile, the crops on the corresponding crop planting areas are subjected to side illumination according to the side illumination data preset in the memory and required by the crops at different time periods. This scheme lets the light that gets into in the big-arch shelter can shine the higher authority of crops in the big-arch shelter, also can shine the side of crops in the big-arch shelter simultaneously to illumination intensity can be controlled.

Preferably, the modern agriculture-based geothermal supplementary circulation system further comprises an energy storage battery for supplying power to each electric device on the modern agriculture-based geothermal supplementary circulation system and a charger for charging the energy storage battery;

the upper illumination control mechanism also comprises a first bracket, an upper convex lens, a solar cell panel, a middle convex lens, a lower concave lens, a first universal rotating device and a circular ring track;

a light through hole is formed in the center of the solar cell panel;

the upper end of the first bracket is fixed on the shed top corresponding to the shed top hole, the first bracket is provided with a first cylinder with a telescopic rod vertically upwards,

the first universal rotating device is fixedly connected to the lower end of the first support, and the inner ring wall of the circular ring track is fixed on a universal rotating head of the first universal rotating device;

a first branch support is arranged on the inner annular wall of the circular track upwards, and a second cylinder with a telescopic rod vertically downwards is arranged on the inner annular wall of the circular track downwards;

the edges of the upper convex lenses are matched, sealed and fixed in the corresponding ceiling holes; the solar cell panel is vertically arranged under the upper convex lens at intervals and is horizontally and fixedly connected to the telescopic rod of the first air cylinder, and the light-facing surface of the solar cell panel is arranged upwards; the convex lenses are vertically and fixedly arranged under the solar cell panel at intervals and are horizontally and fixedly connected to the first branch frame; a second branch frame is fixedly arranged on a telescopic rod of the second cylinder, and a lower concave lens is arranged right below a middle convex lens at an interval from top to bottom and is horizontally and fixedly connected to the second branch frame;

the vertical central line of the convex lens, the vertical central line of the light through hole of the solar cell panel, the vertical central line of the convex lens and the vertical central line of the concave lens can all fall on the same vertical line at the same time;

and the lower focal point of the upper convex lens is located at the upper focal point of the middle convex lens; the side length of the solar cell panel is less than or equal to the diameter of the convex lens; the diameter of the convex lens is smaller than the side length of the solar cell panel; the diameter of the concave lens is larger than or equal to that of the convex lens;

the diameter of a light through hole of the solar cell panel is smaller than that of the convex lens; when the central point in the light through hole of the solar cell panel is positioned at the lower focal point of the upper convex lens, the left end point of the middle convex lens, the left end point of the lower orifice of the light through hole, the central point in the light through hole, the right end point of the upper orifice of the light through hole and the right end point of the upper convex lens are all on the same right oblique straight line, and meanwhile, the right end point of the middle convex lens, the right end point of the lower orifice of the light through hole, the central point in the light through hole, the left end point of the upper orifice of the light through hole and the left end point of the upper convex lens are all on the same left oblique straight line;

a first illumination sensor is fixed at the foremost end of the telescopic rod of the third cylinder; the first illumination sensor can detect light emitted downwards from the concave lens;

the electric energy output end of the solar cell panel is connected to the input end of the charger, and the output end of the charger is connected to the input end of the energy storage battery;

the control end of the first universal rotating device, the control end of the first air cylinder, the control end of the second air cylinder and the control end of the third air cylinder are respectively connected with a main controller.

Preferably, the side illumination control mechanism comprises an annular moving device which can move on the circular ring track along the outer ring wall of the circular ring track, and a fourth cylinder with a telescopic rod facing downwards is fixedly arranged on the annular moving device; a fifth cylinder with a telescopic rod horizontally arranged towards the light transmission area below the lower concave lens is fixedly arranged on a cylinder seat of the fourth cylinder; a first light guide column is fixedly arranged at the front end of the telescopic rod of the fifth cylinder, and a first side convex lens is integrally connected with the upper end surface of the first light guide column in a light guiding manner;

a third branch frame is fixedly arranged at the lower end of a telescopic rod of the fourth cylinder, a second light guide column is fixedly arranged at the upper end of the third branch frame, and the upper end and the lower end of one light guide strip are respectively and integrally connected to the lower end face of the first light guide column and the upper end face of the second light guide column; a second side convex lens is integrally connected on the lower end surface of the second light guide column in a light guide way; the central line of the second side convex lens is obliquely arranged from top to bottom; a third side convex lens is fixedly arranged at the upper end of the third branch frame, the third side convex lens is arranged right in front of the second side convex lens at intervals, and the center line of the second side convex lens and the center line of the third side convex lens are positioned on the same inclined straight line which inclines outwards; the lower focal point of the second side convex lens is superposed with the upper focal point of the third side convex lens;

the lower end of the third branch frame is provided with a second universal rotating device, and a universal rotating head of the second universal rotating device is provided with a reflecting plate with a reflecting surface facing to the area between the concave lens and the crop planting area; the light energy emitted from the convex lens at the third side irradiates on the reflecting surface of the reflector and can be reflected by the reflecting surface of the reflector to the area between the concave lens and the crop planting area; a sixth cylinder with a telescopic rod arranged towards the area between the third side convex lens and the reflector is arranged on the third support, and the second illumination sensor is fixed at the foremost end of the telescopic rod of the sixth cylinder; the first illumination sensor can detect light emitted from the third side convex lens;

the control end of the annular moving device, the control end of the fourth cylinder, the control end of the fifth cylinder, the control end of the sixth cylinder and the control end of the second universal rotating device are respectively connected with a main controller.

Preferably, a transparent cover is arranged on the reflecting surface of the reflector, so that a cavity is formed between the transparent cover and the reflecting surface of the reflector, a plurality of hollow reflecting balls with reflecting coatings coated on the outer surfaces are movably placed in the cavity, a plurality of side cover holes are arranged on the side wall surface of the transparent cover, an air blowing device for blowing air into the cavity is arranged in one side cover hole on the transparent cover below the cavity, and the reflecting balls in the cavity can be blown up by the air blowing device to enable the reflecting balls to jump in the cavity randomly; the control end of the blowing device is connected with the main controller.

Preferably, a first motor with a rotating shaft rotating horizontally is arranged on the lower surface of the solar cell panel, a lamp bracket is fixedly arranged on the rotating shaft of the first motor, and a first lamp with a downward reflecting surface of a lamp shade is arranged on the lamp bracket; the first signal lamp can rotate and stop right below the light through hole of the solar cell panel under the horizontal rotation driving of the first motor rotating shaft; the control end of a signal lamp and the control end of a motor are respectively connected with the main controller.

Preferably, a seventh cylinder with a telescopic rod horizontally arranged towards the left is fixedly arranged at the left end of the upper surface of each solar cell panel, a heat exchange water tank made of metal materials is fixedly connected to the front end of the telescopic rod of each seventh cylinder, and a roller capable of rolling on the upper surface of the corresponding solar cell panel is arranged on the lower surface of each heat exchange water tank;

the heat exchange water tank can move left and right on the upper surface of the solar panel under the control of the telescopic rod of the seventh air cylinder, the left end part of the heat exchange water tank is positioned on the right of the light through hole when the telescopic rod of the seventh air cylinder is contracted to the shortest, and the left end part of the heat exchange water tank is positioned on the right lower part of the right oblique straight line; when the telescopic rod of the seventh air cylinder extends to the longest, the left end part of the heat exchange water tank is positioned on the left of the light through hole, the left end part of the heat exchange water tank is positioned on the left lower side of the left oblique straight line, and the right end part of the heat exchange water tank is positioned on the right lower side of the right oblique straight line;

one end of each heat exchange water tank is respectively provided with a water inlet, the other end of each heat exchange water tank is respectively provided with a water outlet, and two ends of a first heat insulation hose are respectively connected to the water outlet of an independent second circulating pump and the water inlet of the heat exchange water tank; the water inlet of each second circulating pump is connected to one water outlet of the water heater through a fourth heat insulation water pipe; the water outlet of each heat exchange water tank is connected with a water inlet of the water heater through a second heat insulation hose;

and the control end of each seven cylinder and the control end of each second circulating pump are respectively connected with the main controller.

The water heater is internally provided with water, the water in the water heater can be circulated to the heat exchange water tank through the second circulating pump, when sunlight irradiates on the heat exchange water tank, the heat exchange water tank absorbs the sunlight to heat the water 64 in the heat exchange water tank, and the heated water can be circulated into the water heater under the action of the second circulating pump, so that the water temperature in the water heater is increased. The power supply of the water heater can be supplied by an energy storage battery. The power supply of the water heater can also be supplied by the combination of the energy storage battery and the commercial power.

The invention can achieve the following effects:

the invention can control the temperature of the soil in the greenhouse, so that the light entering the greenhouse can irradiate the upper surface of crops in the greenhouse and the side surface of the crops in the greenhouse, and the intensity of the light can be controlled, thus the invention has the advantages of various use flexibility and good reliability.

Drawings

Fig. 1 is a schematic view of the present invention, in which a plurality of crop planting areas are uniformly distributed and divided on the ground in a greenhouse, and the roof of the greenhouse is uniformly provided with roof holes with the same number as the crop planting areas.

FIG. 2 is a schematic view showing the water heater and the heat exchange water tank of the present invention with the left end located at the right of the light passing hole and the left end located at the lower right of the right oblique straight line.

FIG. 3 is a schematic diagram of the water heater and the heat exchange water tank of the present invention with the left end located above the light hole, the left end located above the right oblique straight line, and the right end located below the right oblique straight line.

Fig. 4 is a schematic view of a connection structure in a use state when the solar cell panel is not lifted and the solar energy entering the convex lens is totally irradiated on the convex lens.

Fig. 5 is a schematic view of a connection structure in a use state when the solar cell panel is lifted, and a part of sunlight entering the convex lenses irradiates the convex lenses and another part of sunlight irradiates the solar cell panel.

Fig. 6 is a schematic view of a connection structure in a use state when the solar cell panel is raised, a light is turned to a position below the light through hole, and light emitted from the light is irradiated onto the convex lens under the condition that no sunlight is irradiated onto the convex lens.

FIG. 7 is a schematic view of a connection structure of the reflection plate of the side lighting mechanism of the present invention.

Fig. 8 is a schematic block diagram of a circuit schematic connection structure of the present invention.

Fig. 9 is a schematic view showing that the left end of the heat exchange water tank of the present invention is located to the right of the light-transmitting hole, and the heat exchange water tank blocks a portion of sunlight, and the blocked portion of sunlight does not irradiate the convex lens, so that the blocked portion of sunlight can heat the water in the heat exchange water tank.

Detailed Description

The technical scheme of the invention is further specifically described by the following embodiments and the accompanying drawings.

Example (b): the geothermal supplementary circulation system based on the modern agriculture is shown in figures 1-9 and comprises a main controller and a memory; a plurality of crop planting areas 44 are uniformly distributed and divided on the ground 45 in the greenhouse; shed top holes 3 are oppositely arranged on the shed tops 2 of the greenhouses 1 which are positioned right above each crop planting area one by one, so that a plurality of shed top holes 61 are uniformly distributed on the shed tops of the greenhouses; an intelligent illumination control device is respectively and independently arranged in each shed roof hole one by one;

the edge of the block crop planting area is provided with a passage 43;

the memory 55, the control terminal of each upper illumination control mechanism 56, the control terminal of each side illumination control mechanism 57, each first illumination sensor 18, each first address encoder 19, each second illumination sensor 53, and each second address encoder 33 are respectively connected to the main controller 58.

The modern agriculture-based geothermal supplementary circulation system further comprises an energy storage battery 59 for supplying power to each electric device on the modern agriculture-based geothermal supplementary circulation system and a charger 60 for charging the energy storage battery;

the upper illumination control mechanism further comprises a first support 14, an upper convex lens 4, a solar panel 6, a middle convex lens 8, a lower concave lens 22, a first universal rotating device 48 and a circular ring track 15;

a light through hole 7 is formed in the center of the solar cell panel;

the upper end of the first bracket is fixed on the shed top corresponding to the shed top hole, the first bracket is provided with a first cylinder 13 with a telescopic rod vertically upwards,

a first branch support 47 is arranged on the inner annular wall of the circular track upwards, and a second cylinder 16 with a telescopic rod vertically downwards is arranged on the inner annular wall of the circular track downwards;

the edges of the upper convex lenses are matched, sealed and fixed in the corresponding ceiling holes; the solar cell panel is vertically arranged under the upper convex lens at intervals and is horizontally and fixedly connected to the telescopic rod of the first air cylinder, and the light-facing surface of the solar cell panel is arranged upwards; the convex lenses are vertically and fixedly arranged under the solar cell panel at intervals and are horizontally and fixedly connected to the first branch frame; a second branch frame 20 is fixedly arranged on a telescopic rod of the second cylinder, and a concave lens is arranged right below a convex lens at an interval from top to bottom and is horizontally and fixedly connected to the second branch frame;

a third cylinder 17 is arranged on the second branch frame, a telescopic rod of the third cylinder is horizontally arranged towards the light transmission area below the lower concave lens, and a first illumination sensor is fixed at the foremost end of the telescopic rod of the third cylinder; the first illumination sensor can detect light emitted downwards from the concave lens;

And the control end of the solar cell panel, the control end of the charger and the control end of the energy storage battery are respectively connected with the main controller.

The side illumination control mechanism comprises an annular moving device 49 which can move on the circular ring track along the outer circular wall of the circular ring track, and a fourth cylinder 27 with a telescopic rod vertically downward is fixedly arranged on the annular moving device; a fifth cylinder 25 with a telescopic rod horizontally arranged towards the light transmission area below the lower concave lens is fixedly arranged on the cylinder seat of the fourth cylinder; a first light guide column 24 is fixedly arranged at the front end of the telescopic rod of the fifth cylinder, and a first side convex lens 23 is integrally connected on the upper end surface of the first light guide column in a light guiding manner;

a third branch frame 34 is fixedly arranged at the lower end of the telescopic rod of the fourth cylinder, a second light guide column 29 is fixedly arranged at the upper end of the third branch frame, and the upper end and the lower end of one light guide strip 26 are respectively connected on the lower end surface of the first light guide column and the upper end surface of the second light guide column in a light guide and integrated manner; a second side convex lens 30 is integrally connected on the lower end surface of the second light guide column; the central line of the second side convex lens is obliquely arranged from top to bottom; a third side convex lens 31 is fixedly arranged at the upper end of the third branch frame, the third side convex lens is arranged right in front of the second side convex lens at intervals, and the center line of the second side convex lens and the center line of the third side convex lens are positioned on the same inclined straight line inclined outwards; the lower focal point of the second side convex lens is superposed with the upper focal point of the third side convex lens;

the lower end of the third branch frame is provided with a second universal rotating device 32, and a universal rotating head of the second universal rotating device is provided with a reflecting plate 42 with a reflecting surface 41 facing to the area between the concave lens and the crop planting area; the light energy emitted from the convex lens at the third side irradiates on the reflecting surface of the reflector and can be reflected by the reflecting surface of the reflector to the area between the concave lens and the crop planting area; a sixth cylinder 54 with a telescopic rod arranged towards the area between the third side convex lens and the reflector is arranged on the third bracket, and the second illumination sensor is fixed at the foremost end of the telescopic rod of the sixth cylinder; the first illumination sensor can detect light emitted from the third side convex lens;

A transparent cover 36 is arranged on the reflecting surface of the reflecting plate, so that a cavity 37 is formed between the transparent cover and the reflecting surface of the reflecting plate, a plurality of hollow reflecting balls 38 with reflecting coatings coated on the outer surfaces are movably placed in the cavity, a plurality of side cover holes 39 are arranged on the side wall surface of the transparent cover, an air blowing device 40 for blowing air into the cavity is arranged in one side cover hole on the transparent cover positioned below the cavity, and the air blown by the air blowing device can blow up the reflecting balls positioned in the cavity to enable the reflecting balls to randomly jump in the cavity; the control end of the blowing device is connected with the main controller.

A first motor 9 with a rotating shaft rotating horizontally is arranged on the lower surface of the solar cell panel, a lamp bracket 10 is fixedly arranged on the rotating shaft of the first motor, and a first lamp 11 with a downward arranged reflecting surface of a lampshade 12 is arranged on the lamp bracket; the first signal lamp can rotate and stop right below the light through hole of the solar cell panel under the horizontal rotation driving of the first motor rotating shaft; the control end of a signal lamp and the control end of a motor are respectively connected with the main controller.

The geothermal supplementary circulation system based on modern agriculture further comprises a water heater 71, geothermal heating pipes 62 are respectively embedded under the ground of each crop planting area, a first temperature sensor 77 bound with a third address encoder 76 is respectively placed on the ground of each crop planting area, each geothermal heating pipe is respectively provided with a first circulating pump 73, one end of each geothermal heating pipe is respectively connected to a water outlet of the corresponding first circulating pump through a first heat insulation water pipe 74, a water inlet of each first circulating pump is respectively connected to a water outlet of the water heater through a second heat insulation water pipe 72, and the other end of each geothermal heating pipe is connected to a water inlet of the water heater through a third heat insulation water pipe 70; and the control end of the water heater, the control end of each first circulating pump, each third address encoder and each first temperature sensor are respectively connected with the main controller.

A seventh air cylinder 66 with a telescopic rod horizontally arranged towards the left is fixedly arranged at the left end of the upper surface of each solar cell panel, a heat exchange water tank 65 made of metal materials is fixedly connected at the front end of the telescopic rod of each seventh air cylinder, and a roller 63 capable of rolling on the upper surface of the corresponding solar cell panel is arranged on the lower surface of each heat exchange water tank;

one end of each heat exchange water tank is respectively provided with a water inlet, the other end of each heat exchange water tank is respectively provided with a water outlet, and two ends of a first heat insulation hose 67 are respectively connected to a water outlet of an independent second circulating pump 68 and a water inlet of the heat exchange water tank; the water inlet of each second circulating pump is connected to one water outlet of the water heater through a fourth heat insulation water pipe 69; the water outlet of each heat exchange water tank is connected with a water inlet of the water heater through a second heat insulation hose 75;

When in use, upper light irradiation data and upper light irradiation data of the upper light irradiation amount and the side light irradiation amount required by crops planted on each crop planting area in each period are stored in a memory in advance; under the control of the main controller, the upper illumination data detected by the first illumination sensor and the side illumination data detected by the second illumination sensor corresponding to each upper illumination control mechanism are detected, the crops on the corresponding crop planting areas are subjected to upper illumination according to the upper illumination data preset in the memory and required by the crops at different time periods, and meanwhile, the crops on the corresponding crop planting areas are subjected to side illumination according to the side illumination data preset in the memory and required by the crops at different time periods.

The light that can directly shine on the crop planting area or on the crop planting area is the upper shining light 28. The portion of light emitted from the third-side convex lens that can be detected by the first illumination sensor becomes the upward-illumination detection light 21. The light reflected by the reflector is side illumination light 35. Sunlight 5 is irradiated from a convex lens I. The middle part of the light guide strip is bound on the cylinder seat of the fifth cylinder by a binding belt 46. After the solar cell panel rises, a part of sunlight 50 entering the first convex lens can irradiate the convex lens through the light through hole, the other part of sunlight 51 entering the first convex lens directly irradiates the solar cell panel to enable the solar cell panel to generate electricity, and electricity emitted by the solar cell panel charges the energy storage battery through the charger. The light energy output from the convex lens at the third side passes through the transparent cover, then irradiates the reflector, is reflected by the reflector, then passes through the transparent cover and enters crops on the crop planting area. Each solar cell panel is provided with a solar controller.

This embodiment lets solar cell panel rise when the illumination volume of sunshine is greater than the illumination volume of the present needs of crops, and solar cell panel after the rising just shelters from some sunshine, and the illumination volume of the sunshine that shines on the convex lens will reduce this time to reduce the illumination volume of shining on crops. And the redundant sunlight irradiated on the solar panel is converted into electricity by the solar panel and stored in the energy storage battery for the electric equipment.

The lifting of the solar cell panel can be controlled through the first air cylinder. The lifting of the concave lens can be controlled through the second cylinder, and the lifting of the concave lens can change the size of the illumination area irradiated from the concave lens to the crop planting area. The first illumination sensor can be controlled to extend below the concave lens through the third cylinder to detect the illumination of light emitted from the concave lens. The lifting height of the reflector can be controlled through the fourth cylinder, and the first side convex lens can be controlled to extend into the lower part of the concave lens to collect input light for side light through the fifth cylinder. The second illumination sensor can be controlled to extend into the front of the third convex lens through the sixth air cylinder to detect the illumination of light emitted from the third convex lens. The light energy reflected by the irregular and jumbled reflecting balls is randomly irradiated to the side of crops or the lower parts of leaves, and the light is randomly irradiated to different points of the crops, so that the side surfaces of the crops or the lower parts of the leaves are provided with light, and the parts are not provided with light, and the light and the non-light form illumination contrast, thereby being beneficial to the stimulation of the light to the crops and being beneficial to the growth or the maturity of the crops. The illumination of the upper surface and the side surface of the crop can be controlled, the sunlight is more than the surplus sunlight, the surplus sunlight is converted into electricity to be stored, and the sunlight is fully utilized. When the sunlight is lost, the light 52 generated by electricity converted from the sunlight is used to illuminate the crops. When not having sunshine, also be a lamp power supply with the electricity of storage in energy storage battery, let the light of a lamp carry out light irradiation to crops, this embodiment crops required light does not receive the restriction that sunshine has or not, flexibility and good reliability.

This embodiment is described. The unnecessary sunshine in every crop planting area is converted into electricity through solar cell panel and then is stored in energy storage battery, then the light irradiation is carried out to the point in the usable energy storage battery of every lamp, just so shine the sunshine make full use of on every epirelief lens to whole farm to make the power on the energy storage battery can both be used each other to a lamp on the intelligent illumination controlling means that whole different crop planting areas correspond, just so shine the sunshine on every epirelief lens on the whole farm and have had the interaction each other.

In different blocks of crops planting area, the illumination that different crops need is different at different times, and this embodiment just can carry out make full use of the sunshine that every block of crops planting area corresponds, has improved photovoltaic agricultural's reliability greatly.

This embodiment can control soil temperature in the big-arch shelter, lets the light that gets into in the big-arch shelter can shine the higher authority of crops in the big-arch shelter, also can shine the side of crops in the big-arch shelter simultaneously to illumination intensity can be controlled.

Claims

1. The geothermal supplementary circulation system based on modern agriculture is characterized by comprising a main controller and a memory; a plurality of crop planting areas are uniformly distributed and divided on the ground in the greenhouse; shed top holes are oppositely arranged on the shed tops of the greenhouses right above each crop planting area in a one-to-one mode, so that a plurality of shed top holes are uniformly distributed on the shed tops of the greenhouses; an intelligent illumination control device is respectively and independently arranged in each shed roof hole one by one;

the storage, the control end of each upper illumination control mechanism, the control end of each side illumination control mechanism, each first illumination sensor, each first address encoder, each second illumination sensor and each second address encoder are respectively connected with the main controller;

2. A geothermal supplementary circulation system based on modern agriculture according to claim 1, wherein the geothermal supplementary circulation system based on modern agriculture further comprises an energy storage battery for providing power supply for each electric device on the geothermal supplementary circulation system based on modern agriculture and a charger for charging the energy storage battery;

a light through hole is formed in the center of the solar cell panel;

3. A geothermal supplementary circulation system based on modern agriculture according to claim 2, wherein the side illumination control mechanism comprises an annular moving device which can move on the circular track along the outer circular wall of the circular track, and a four-cylinder with a telescopic rod facing downwards is fixed on the annular moving device; a fifth cylinder with a telescopic rod horizontally arranged towards the light transmission area below the lower concave lens is fixedly arranged on a cylinder seat of the fourth cylinder; a first light guide column is fixedly arranged at the front end of the telescopic rod of the fifth cylinder, and a first side convex lens is integrally connected with the upper end surface of the first light guide column in a light guiding manner;

4. A geothermal supplementary circulation system based on modern agriculture according to claim 2, wherein a first motor with a rotating shaft rotating horizontally is arranged on the lower surface of the solar cell panel, a lamp bracket is fixedly arranged on the rotating shaft of the first motor, and a first lamp with a lamp shade arranged with a reflecting surface facing downwards is arranged on the lamp bracket; the first signal lamp can rotate and stop right below the light through hole of the solar cell panel under the horizontal rotation driving of the first motor rotating shaft; the control end of a signal lamp and the control end of a motor are respectively connected with the main controller.

5. A geothermal supplementary circulation system based on modern agriculture according to claim 2, wherein each of the seven cylinders with the telescopic rod horizontally arranged towards the left is fixedly arranged at the left end of the upper surface of the solar panel, the heat exchange water tank made of metal material is fixedly connected at the front end of the telescopic rod of each of the seven cylinders, and the roller capable of rolling on the upper surface of the corresponding solar panel is arranged on the lower surface of each of the heat exchange water tanks;

6. A method of operating a modern agriculture-based geothermal supplementary circulation system according to claim 1, wherein in use, upper light data and upper light data of the upper light amount and the side light amount required for each period of time for crops planted on each crop planting area are stored in a memory in advance; under the control of the main controller, detecting upper illumination data detected by a first illumination sensor and side illumination data detected by a second illumination sensor corresponding to each upper illumination control mechanism, performing upper illumination on crops on a corresponding crop planting area according to upper illumination data required by crops at different time periods preset in a memory, and performing side illumination on the crops on the corresponding crop planting area according to side illumination data required by the crops at different time periods preset in the memory;

hot water in the water heater can be circulated to the geothermal heating pipe through the first circulating pump to enable the geothermal heating pipe to generate heat, and therefore the soil temperature of the corresponding crop planting area is improved.