CN108966942B - Intelligent vegetable greenhouse and method - Google Patents

Abstract

The invention discloses an intelligent vegetable greenhouse and a method, wherein the intelligent vegetable greenhouse comprises a circular bottom plate, a plurality of arc-shaped supporting columns arranged on the circular bottom plate, a hemispherical light-transmitting awning arranged on each arc-shaped supporting column, a supporting seat arranged on the hemispherical light-transmitting awning, M supporting rods arranged on the supporting seat and extending towards the oblique outer upper part of the semicircular awning, and a first plane mirror arranged on each supporting rod; m is more than or equal to 4, M upright columns are arranged on the ground close to the circular bottom plate, a second plane mirror corresponding to the first plane mirror is arranged on each upright column, a first motor for driving the first plane mirror to rotate is arranged on each supporting rod, a second motor for driving the second plane mirror to rotate is arranged on each upright column, and the circular bottom plate is higher than the bottoms of the upright columns; the invention has the characteristics of high sunlight utilization efficiency and effective electric energy saving.

Description

Intelligent vegetable greenhouse and method

Technical Field

The invention relates to the technical field of vegetable production equipment, in particular to an intelligent vegetable greenhouse and a method, which have high sunlight utilization efficiency and can effectively save electric energy.

Background

The solar altitude angle refers to an included angle between the incident direction of sunlight and the ground plane, and when the solar altitude angle is 90 degrees, the solar radiation intensity is the maximum; when the sun is obliquely directed to the ground, the intensity of the solar radiation is small.

The solar altitude is called the solar altitude (actually, the angle) for short, the solar altitude is the most important factor for determining the amount of solar heat energy obtained on the earth surface, and the solar altitude is constantly changed in one day at the same place. For example, the solar altitude at 12 am is 90 degrees, and changes by 15 degrees every hour, that is, the solar altitude at 14 am and 10 am are both 60 degrees, and the solar altitude at sunrise and sunset is both 0 degree.

In daytime, the vegetable greenhouse mainly depends on sunlight for illumination, needs lamplight for illumination in cloudy days or at night, although there is sunlight in early morning and evening, the solar altitude angle is too small, the solar radiation intensity is low, the vegetables in the middle of the vegetable greenhouse are difficult to irradiate the sunlight, and the requirement of vegetable growth on light can be met by supplementing the lamplight, so that the vegetable greenhouse needs to consume a large amount of electric energy.

Disclosure of Invention

The invention aims to overcome the defect that a vegetable greenhouse in the prior art needs to consume a large amount of electric energy, and provides an intelligent vegetable greenhouse and a method which have high sunlight utilization efficiency and can effectively save electric energy.

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

an intelligent vegetable greenhouse comprises a circular bottom plate, a plurality of arc-shaped support columns arranged on the circular bottom plate, a hemispherical light-transmitting awning arranged on each arc-shaped support column, a support seat arranged on the hemispherical light-transmitting awning, M support rods arranged on the support seat and extending to the upper part of the semicircular awning, and a first plane mirror arranged on each support rod; m is more than or equal to 4, M upright posts are arranged on the ground close to the circular bottom plate, a second plane mirror corresponding to the first plane mirror is arranged on each upright post, a first motor used for driving the first plane mirror to rotate is arranged on each supporting rod, a second motor used for driving the second plane mirror to rotate is arranged on each upright post, the circular bottom plate is higher than the bottoms of the upright posts, the device further comprises a controller and a light intensity sensor, and the controller is electrically connected with the light intensity sensor, the first motors and the second motors respectively.

When the vegetables are in the middle of the semicircular awning, the vegetables are placed in the semicircular awning, the sunlight shines on the second plane mirrors in an oblique mode in the morning or at the evening, the second plane mirrors emit light rays, the reflected light rays enter the first plane mirrors, the first plane mirrors reflect the light rays into the semicircular awning, the reflected light rays enter the semicircular awning from the high position to supplement the light rays for the vegetables in the middle of the semicircular awning, meanwhile, the light rays shines on the vegetables at the edge of the semicircular awning in the oblique mode, dependence of the vegetables on lighting can be effectively reduced, and electric energy is effectively saved.

Preferably, M lifting devices are further arranged on the ground close to the circular bottom plate, each lifting device is provided with a concave lens, each concave lens corresponds to each first plane mirror, each lifting device is electrically connected with the controller, and the lower part of each lifting device is lower than the circular bottom plate.

Each concave lens disperses light, makes the light after dispersing evenly shine on the vegetables at hemisphere printing opacity awning middle part, makes vegetables growth progress the same, brings the facility for production management.

Preferably, the lifting device is an air cylinder, an expansion rod of the air cylinder is connected with the concave lens, and each air cylinder is electrically connected with the controller.

Preferably, the support base is provided with M third motors, the rotating shaft of each third motor is connected with each support rod, and each third motor is electrically connected with the controller. The inclination angle of the supporting rod can be changed through the third motor, so that the stress of the supporting rod is improved, and the service life of the supporting rod is prolonged.

Preferably, each support rod is of a sleeve structure. The individual support rods can be manually stretched or contracted.

Preferably, the hemispherical light-transmitting awning is provided with a plurality of ventilation openings, a circular guide rail is arranged on the ground, the circular bottom plate is connected with the circular guide rail in a sliding mode through a plurality of sliding blocks, the circular guide rail is provided with a fourth motor, a rotating shaft of the fourth motor is provided with a gear, the circular bottom plate is provided with sawteeth matched with the gear, and the fourth motor is electrically connected with the controller.

A method for an intelligent vegetable greenhouse comprises the following steps:

(7-1) detecting the illuminance by an illuminance sensor, setting an illuminance threshold value W in a controller, and setting a corresponding table of the rotation angle of a first plane mirror and the rotation angle of a second plane mirror with the date and the moment respectively in the controller;

(7-2) if the illuminance value detected by the illuminance sensor is greater than W and the current time is less than time T1 am, or the illuminance value detected by the illuminance sensor is greater than W and the current time is greater than time T2 pm;

the controller controls each first motor and each second motor to respectively control the first plane mirror and the second plane mirror on the light side of the hemispherical light-transmitting shade shed to rotate along with the change of time according to the corresponding table;

(7-3) the sunlight is reflected by each first plane mirror and each second plane mirror and irradiates the vegetables in the hemispherical light-transmitting awning from a higher height, so that the vegetables can absorb more sufficient light.

Preferably, M lifting devices are further arranged on the ground close to the circular bottom plate, each lifting device is provided with a concave lens, each concave lens corresponds to each first plane mirror, and each lifting device is electrically connected with the controller; also comprises the following steps:

the inclination angle of each concave lens of hemisphere printing opacity awning to light one side has been adjusted, and each hemisphere printing opacity awning rises to each concave lens of light one side to the controller control, and the light through each first plane mirror reflection gets into each concave lens respectively, and each concave lens disperses light, and the light after dispersing gets into hemisphere printing opacity awning, and the light after dispersing evenly shines on vegetables.

Preferably, the support base is provided with M third motors, the rotating shaft of each third motor is respectively connected with each support rod, and each third motor is electrically connected with the controller; also comprises the following steps:

if the current time is in the interval of [ T3, T4], the controller controls each third motor to drive each support rod to rotate, controls each first motor to drive each first plane mirror to be folded, controls each second motor to drive each second plane mirror to be in a state vertical to the ground, and controls each lifting device to drive each concave lens to descend to the original state.

Preferably, the hemispherical light-transmitting awning is provided with a plurality of ventilation openings, a circular guide rail is arranged on the ground, the circular bottom plate is connected with the circular guide rail in a sliding manner through a plurality of sliding blocks, a fourth motor is arranged on the circular guide rail, a rotating shaft of the fourth motor is provided with a gear, the circular bottom plate is provided with sawteeth matched with the gear, and the fourth motor is electrically connected with the controller; the method is characterized by further comprising the following steps:

the controller is provided with a plurality of keys, and a worker controls the fourth motor to drive the circular bottom plate to rotate along the circular guide rail by operating the keys so as to align each through hole with the wind direction.

Therefore, the invention has the following beneficial effects: the sunlight utilization efficiency is high, and the electric energy is effectively saved; provides a reliable foundation for the healthy growth of vegetables.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present invention;

FIG. 2 is a functional block diagram of the present invention;

fig. 3 is a flowchart of embodiment 1 of the present invention.

In the figure: the device comprises a circular bottom plate 1, an arc-shaped support column 2, a hemispherical light-transmitting awning 3, a support seat 4, a support rod 5, a first plane mirror 6, a second plane mirror 7, a first motor 8, a second motor 9, a controller 10, a lifting device 11, a concave lens 12, a third motor 13, a vent 14, a fourth motor 15 and a light intensity sensor 16.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

Example 1

The embodiment shown in fig. 1 and 2 is an intelligent vegetable greenhouse, which comprises a circular bottom plate 1, 4 arc-shaped supporting columns 2 arranged on the circular bottom plate, a hemispherical light-transmitting shed 3 arranged on each arc-shaped supporting column, a supporting base 4 arranged on the hemispherical light-transmitting shed, 16 supporting rods 5 arranged on the supporting base and extending towards the upper part of the semicircular shed, and a first plane mirror 6 arranged on each supporting rod, wherein 16 upright posts are arranged on the ground close to the circular bottom plate, a second plane mirror 7 corresponding to the first plane mirror is arranged on each upright post, a first motor 8 for driving the first plane mirror to rotate is arranged on each supporting rod, a second motor 9 for driving the second plane mirror to rotate is arranged on each upright post, the height of the circular bottom plate is higher than the height of the bottom of each upright post, a controller 10 and a light intensity sensor 16, the controller is respectively electrically connected with the illuminance sensor, each first motor and each second motor. Each support rod is of a sleeve structure.

As shown in fig. 3, a method of an intelligent vegetable greenhouse comprises the following steps:

step 100, detecting illuminance by an illuminance sensor, setting an illuminance threshold value W in a controller, and setting a corresponding table of a rotation angle of a first plane mirror and a rotation angle of a second plane mirror with date and time respectively in the controller;

step 200, adjusting the light irradiation angle

If the illuminance value detected by the illuminance sensor is greater than W and the current time is less than the T1 am, or the illuminance value detected by the illuminance sensor is greater than W and the current time is greater than the T2 pm; w is 35000lx, T1 is 10 am: 00, T2 is 2:00 PM.

The controller controls each first motor and each second motor to respectively control the first plane mirror and the second plane mirror on the light side of the hemispherical light-transmitting shade shed to rotate along with the change of time according to the corresponding table;

the invention adjusts the light irradiation angle before 10 am and after 2 pm on the day with the illumination energy meeting the requirement, thereby ensuring that the light absorbed by the vegetables is more sufficient, improving the speed of plant photosynthesis and improving the economic benefit of the vegetable greenhouse;

step 300, the adjusted light enters the hemispherical light-transmitting awning

Sunlight is reflected by the first plane mirror and the second plane mirror and irradiates the vegetables in the hemispherical light-transmitting awning from a higher height, so that the vegetables can absorb more sufficient light.

Example 2

Embodiment 2 includes the structure and method of embodiment 1, as shown in fig. 1 and fig. 2, in embodiment 2, 16 lifting devices 11 are further provided on the ground near the circular bottom plate, each lifting device is provided with a concave lens 12, each concave lens corresponds to each first plane mirror, each lifting device is electrically connected with the controller, and the lower part of each lifting device is lower than the circular bottom plate. The lifting device is a cylinder, a telescopic rod of the cylinder is connected with the concave lens, and each cylinder is electrically connected with the controller.

Also comprises the following steps:

the inclination angle of each concave lens of hemisphere printing opacity awning to light one side has been adjusted, and each hemisphere printing opacity awning rises to each concave lens of light one side to the controller control, and the light through each first plane mirror reflection gets into each concave lens respectively, and each concave lens disperses light, and the light after dispersing gets into hemisphere printing opacity awning, and the light after dispersing evenly shines on vegetables.

Example 3

Embodiment 3 includes the structure and method parts of embodiment 1, as shown in fig. 2, 16 third motors 13 are arranged on the support base of embodiment 3, the rotating shafts of the third motors are respectively connected with the support rods, and the third motors are electrically connected with the controller.

If the current time is in the interval of [ T3, T4], the controller controls each third motor to drive each support rod to rotate, controls each first motor to drive each first plane mirror to be folded, controls each second motor to drive each second plane mirror to be in a state vertical to the ground, and controls each lifting device to drive each concave lens to descend to the original state.

T3 is the sunset time of the day, T4 is the sunrise time of the next day, and in the interval of [ T3, T4], the controller controls the first plane mirror, the second plane mirror and the concave lenses to be folded, so that the safety of the first plane mirror, the second plane mirror and the concave lenses at night is guaranteed.

Example 4

Embodiment 3 includes the structure and method parts of embodiment 1, as shown in fig. 1 and fig. 2, 8 ventilation openings 14 are arranged on the hemispherical light-transmitting awning of embodiment 3, a circular guide rail is arranged on the ground, a circular bottom plate is connected with the circular guide rail in a sliding manner through a plurality of sliding blocks, a fourth motor 15 is arranged on the circular guide rail, a gear is arranged on a rotating shaft of the fourth motor, saw teeth matched with the gear are arranged on the circular bottom plate, and the fourth motor is electrically connected with a controller.

Also comprises the following steps:

the controller is provided with a start key and an end key, and a worker controls the fourth motor to drive the circular bottom plate to rotate along the circular guide rail by operating the start key and the end key, so that the through holes are aligned with the wind direction, and the vegetables in the shed are smoothly ventilated.

It should be understood that this example is for illustrative purposes only and is not intended to limit the scope of the present invention. Further, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teaching of the present invention, and such equivalents may fall within the scope of the present invention as defined in the appended claims.

Claims (8)

1. An intelligent vegetable greenhouse is characterized by comprising a circular bottom plate (1), a plurality of arc-shaped supporting columns (2) arranged on the circular bottom plate, a hemispherical light-transmitting awning (3) arranged on each arc-shaped supporting column, a supporting seat (4) arranged on the hemispherical light-transmitting awning, M supporting rods (5) arranged on the supporting seat and extending towards the upper part of the semicircular awning and a first plane mirror (6) arranged on each supporting rod; m is more than or equal to 4, M upright posts are arranged on the ground close to the circular bottom plate, each upright post is provided with a second plane mirror (7) corresponding to the first plane mirror, each supporting rod is provided with a first motor (8) used for driving the first plane mirror to rotate, each upright post is provided with a second motor (9) used for driving the second plane mirror to rotate, the circular bottom plate is higher than the bottoms of the upright posts, and the electric bicycle further comprises a controller (10) and a light intensity sensor (16), wherein the controller is respectively electrically connected with the light intensity sensor, each first motor and each second motor; m lifting devices (11) are further arranged on the ground close to the circular bottom plate, each lifting device is provided with a concave lens (12), each concave lens corresponds to each first plane mirror, each lifting device is electrically connected with the controller, and the lower part of each lifting device is lower than the circular bottom plate; the lifting device is an air cylinder, a telescopic rod of the air cylinder is connected with the concave lens, and each air cylinder is electrically connected with the controller.

2. The intelligent vegetable greenhouse of claim 1, wherein the support base is provided with M third motors (13), the rotating shaft of each third motor is connected with each support rod, and each third motor is electrically connected with the controller.

3. The intelligent vegetable greenhouse of claim 1, wherein each support rod is of a sleeve structure.

4. The intelligent vegetable greenhouse as claimed in claim 1, 2 or 3, wherein the hemispherical transparent awning is provided with a plurality of ventilation openings (14), a circular guide rail is arranged on the ground, the circular bottom plate is slidably connected with the circular guide rail through a plurality of sliding blocks, a fourth motor (15) is arranged on the circular guide rail, a gear is arranged on a rotating shaft of the fourth motor, sawteeth matched with the gear are arranged on the circular bottom plate, and the fourth motor is electrically connected with the controller.

5. The method for the intelligent vegetable greenhouse based on claim 1, which is characterized by comprising the following steps:

(5-1) detecting the illuminance by an illuminance sensor, setting an illuminance threshold value W in a controller, and setting a corresponding table of the rotation angle of a first plane mirror and the rotation angle of a second plane mirror with the date and the moment respectively in the controller;

(5-2) if the illuminance value detected by the illuminance sensor is greater than W and the current time is less than T1 am, or the illuminance value detected by the illuminance sensor is greater than W and the current time is greater than T2 pm;

the controller controls each first motor and each second motor to respectively control the first plane mirror and the second plane mirror on the light side of the hemispherical light-transmitting shade shed to rotate along with the change of time according to the corresponding table;

(5-3) the sunlight is reflected by each first plane mirror and each second plane mirror and irradiates the vegetables in the hemispherical light-transmitting awning from a higher height, and the vegetables absorb more sufficient light.

6. The method of intelligent vegetable greenhouse of claim 5, further comprising the steps of:

the inclination angle of each concave lens of hemisphere printing opacity awning to light one side has been adjusted, and each hemisphere printing opacity awning rises to each concave lens of light one side to the controller control, and the light through each first plane mirror reflection gets into each concave lens respectively, and each concave lens disperses light, and the light after dispersing gets into hemisphere printing opacity awning, and the light after dispersing evenly shines on vegetables.

7. The method of claim 5, wherein the support base is provided with M third motors, a rotating shaft of each third motor is connected with each support rod, and each third motor is electrically connected with the controller; the method is characterized by further comprising the following steps:

if the current time is in the interval of [ T3, T4], the controller controls each third motor to drive each support rod to rotate, controls each first motor to drive each first plane mirror to be folded, controls each second motor to drive each second plane mirror to be in a state vertical to the ground, and controls each lifting device to drive each concave lens to descend to the original state.

8. The method of intelligent vegetable greenhouse as claimed in claim 5, 6 or 7, wherein the semi-spherical transparent awning is provided with a plurality of ventilation openings, the ground is provided with a circular guide rail, the circular bottom plate is slidably connected with the circular guide rail through a plurality of sliding blocks, the circular guide rail is provided with a fourth motor, a rotating shaft of the fourth motor is provided with a gear, the circular bottom plate is provided with saw teeth matched with the gear, and the fourth motor is electrically connected with the controller; the method is characterized by further comprising the following steps:

the controller is provided with a plurality of keys, and a worker controls the fourth motor to drive the circular bottom plate to rotate along the circular guide rail by operating the keys so as to align each through hole with the wind direction.

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