CN107155712A - Wind-light storage complementation intelligent greenhouse - Google Patents

Abstract

The present invention provides a wind-solar-storage complementary intelligent greenhouse, which includes a greenhouse body, a temperature control system and a wind-solar hybrid power generation system, and the wind-solar hybrid power generation system includes a first controller and a A photoelectric conversion mechanism, a wind power conversion mechanism, a storage battery and an electric control switch connected to the controller, the storage battery is connected to the temperature control system through the electric control switch. The wind-solar-storage complementary intelligent greenhouse of the present invention can effectively improve the prediction accuracy of wind power power, and has the advantages of high accuracy, good stability and high efficiency.

Description

Wind-solar-storage complementary intelligent greenhouse

technical field

The invention relates to the field of agricultural equipment, in particular to a wind-solar-storage complementary intelligent greenhouse.

Background technique

my country is a big energy consumer, but its energy structure is overly dependent on fossil energy. Not only are reserves dwindling, but excessive emissions have caused serious environmental pollution and ecological balance problems. With the construction of a large number of greenhouses, this trend is bound to intensify. Compared with other green energy sources, wind energy and solar energy have the characteristics of no mining, abundant resources, renewable, and zero emissions; at the same time, from the perspective of return on investment, wind energy and solar energy have a short return on investment cycle, and there are national policy subsidies, which have the characteristics of Better economic effect.

Most of the existing greenhouses are ordinary light-transmitting films and skeleton structures, which mainly use the natural light and heat in nature, and some will add heating equipment to keep the temperature in the greenhouse at a certain high level or above a certain temperature, so as to provide Some crops that need to keep warm provide a suitable growing environment. However, the existing greenhouses generally have the problems of limited thermal insulation effect, unstable temperature inside the greenhouse, or high energy consumption.

Contents of the invention

In view of the deficiencies in the above-mentioned prior art, the present invention provides a wind-solar-storage complementary intelligent greenhouse, which can effectively improve the prediction accuracy of wind power power, and has the advantages of high accuracy, good stability and high efficiency.

In order to achieve the above object, the present invention provides a wind-solar-storage complementary intelligent greenhouse, which includes a greenhouse body, a temperature control system and a wind-solar hybrid power generation system, the wind-solar hybrid power generation system includes a first controller, and The first controller is connected to a photoelectric conversion mechanism, a wind power conversion mechanism, a battery and an electric control switch, and the battery is connected to the temperature control system through the electric control switch.

Preferably, the wind power conversion mechanism includes a wind power collection device and a wind power conversion device, the wind power collection device is connected to the wind power conversion device, and the wind power conversion device is connected to the first controller.

Preferably, the photoelectric conversion mechanism includes a light energy collection device and a photoelectric conversion device, the light energy collection device is connected to the photoelectric conversion device, and the photoelectric conversion device is connected to the first controller.

Preferably, the light energy collection device uses a solar film, and the top of the greenhouse body is formed by using the solar film.

Preferably, the wind-solar hybrid power generation system further includes a transformer, the storage battery is connected to the transformer through the electric control switch, and the transformer is connected to the power grid.

Preferably, the wind-solar hybrid power generation system further includes an inverter, and the inverter is connected between the battery and the electric control switch.

Preferably, the temperature control system includes a plurality of temperature sensors, a second controller and a temperature control device, the temperature sensors are connected in communication with the second controller, and the second controller is connected to the temperature control device and the electric control switch.

Preferably, the temperature control system further includes a display device connected to the second controller.

Preferably, the display device adopts a touch screen.

Preferably, the temperature control system further includes an alarm device connected to the second controller.

The present invention has the following beneficial effects due to the adoption of the above technical scheme:

The wind-solar hybrid power generation system is used to provide complementary wind power and solar power generation functions for the greenhouse, so that the greenhouse can obtain various forms of environmentally friendly energy, so that the greenhouse can stably obtain electric energy in various external environments. The storage battery is used to store excess electrical energy and provide reserve energy when the external ambient light energy and wind energy cannot meet the power supply requirements of the system. The temperature control system is used to automatically adjust the temperature inside the greenhouse so that the temperature inside the greenhouse remains constant. The top of the greenhouse body is made of solar thin film, and there is no need to set up a fixed structure of a light energy collection device, which saves production costs, reduces the overall structural complexity of the greenhouse, and reduces the total volume of the greenhouse. The electric control switch is controlled by the first controller to control the connection and shutdown of the storage battery with the temperature control system and/or the transformer. The inverter is used to convert the DC power of the battery into AC power. When the battery is connected to the transformer, the transformer converts the received voltage into the grid voltage, realizing the sale of excess power to the grid and increasing the user's income. When the wind-solar hybrid power generation system and the battery cannot meet the power demand of the system, the system can also be directly powered through the grid to prevent the system from stopping due to insufficient power supply. The display device is used to display the temperature information in the greenhouse, and can also be used as a human-computer interaction terminal for system control, so that users can obtain the temperature control of the greenhouse more intuitively and conveniently, and can easily adjust and adjust the temperature in the greenhouse. control. The alarm device is used to provide an alarm when the temperature in the greenhouse exceeds the preset range, which is convenient for users to troubleshoot the temperature control system in time, ensures the environmental safety in the greenhouse, and prevents possible production losses due to temperature out of control.

Description of drawings

Fig. 1 is a schematic structural diagram of a wind-solar-storage complementary intelligent greenhouse according to an embodiment of the present invention.

detailed description

Below, according to accompanying drawing 1, a preferred embodiment of the present invention is given and described in detail, so that the functions and characteristics of the present invention can be better understood.

Please refer to Fig. 1, the present invention provides a wind-solar-storage complementary intelligent greenhouse, including a greenhouse body (not shown in the figure), a temperature control system 2 and a wind-solar hybrid power generation system 1, the wind-solar hybrid power generation system 1 includes a first The controller 11 , and a photoelectric conversion mechanism 12 connected to the first controller 11 , a wind power conversion mechanism 13 , a battery 14 and an electric control switch 16 , and the battery 14 is connected to the temperature control system 2 through the electric control switch 16 .

The wind-solar hybrid power generation system 1 is used to provide complementary wind power generation and solar power generation functions for the greenhouse, so that the greenhouse can obtain various forms of environmentally friendly energy, so that the greenhouse can stably obtain electric energy under various external environments. The temperature control system 2 is used to automatically adjust the temperature inside the greenhouse so that the temperature inside the greenhouse remains constant. The storage battery 14 is used for storing excess electric energy, and provides reserve energy when the light energy and wind energy of the external environment cannot meet the power supply demand of the system.

The wind power conversion mechanism 13 includes a wind power collection device 131 and a wind power conversion device 132 , the wind power collection device 131 is connected to the wind power conversion device 132 , and the wind power conversion device 132 is connected to the first controller 11 .

The photoelectric conversion mechanism 12 includes a light energy collection device 121 and a photoelectric conversion device 122 , the light energy collection device 121 is connected to the photoelectric conversion device 122 , and the photoelectric conversion device 122 is connected to the first controller 11 .

The light energy collection device 121 is made of a solar film, and the top of the greenhouse body is made of a solar film.

The top of the greenhouse body is made of solar thin film, and there is no need to set up a fixed structure of the light energy collection device 121, which saves production costs, reduces the overall structural complexity of the greenhouse, and reduces the total volume of the greenhouse.

The wind-solar hybrid power generation system 1 also includes a transformer 17 , the storage battery 14 is connected to the transformer 17 through an electric control switch 16 , and the transformer 17 is connected to the grid 3 .

The wind-solar hybrid power generation system 1 also includes an inverter 15 connected between the battery 14 and the electric control switch 16 .

The electric control switch 16 is controlled by the first controller 11 to control the connection and disconnection of the storage battery 14 with the temperature control system 2 and/or the transformer 17 . The inverter 15 is used to convert the DC power of the storage battery 14 into AC power. When the storage battery 14 is connected to the transformer 17, the transformer 17 converts the received voltage into the voltage of the grid 3, so as to sell excess electric energy to the grid 3 and increase the user's income.

The temperature control system 2 includes a plurality of temperature sensors 21, a second controller 22 and a temperature control device 23, the temperature sensor 21 is connected to the second controller 22 in communication, and the second controller 22 is connected to the temperature control device 23 and the electric control switch 16. In this embodiment, the temperature sensors 21 are distributed around and in the middle of the greenhouse body. The multiple temperature sensors 21 are wirelessly connected to the second controller 22 through a radio frequency transmitter and a radio frequency receiver, which reduces wiring materials and costs.

The temperature control system 2 also includes a display device 24 and an alarm device 25 , and the display device 24 and the alarm device 25 are respectively connected to the second controller 22 . The display device 24 may use a liquid crystal screen or the display device 24 may use a touch screen.

The display device 24 is used to display the temperature information in the greenhouse, and can also be used as a human-computer interaction terminal for system control, so that users can obtain the temperature control situation of the greenhouse more intuitively and conveniently, and can easily adjust the temperature in the greenhouse and control. The alarm device 25 is used to provide an alarm when the temperature in the greenhouse exceeds the preset range, which is convenient for users to troubleshoot the temperature control system 2 in time, ensures the environmental safety in the greenhouse, and prevents possible production losses due to temperature out of control.

The working process of the wind-solar hybrid power generation system 1 of this embodiment is as follows:

When it is necessary to adjust the temperature, the wind-solar hybrid power generation system 1 first supplies power to the temperature control system 2. If there is surplus electricity, the excess electricity will be stored on the battery 14. When the battery 14 is fully charged, there is still electricity left, and the transformer 17 will The excess electricity is converted to grid 3 voltage and sold to grid 3. When the wind-solar hybrid power generation system 1 cannot meet the power demand of the system, the stored electricity is first supplied to the system through the inverter 15 through the battery 14 as a power source. When the storage capacity of the battery 14 is insufficient, the power of the grid 3 can be directly used.

In addition, the working process of the temperature control system 2 is as follows:

First, a target temperature is preset, and the temperature is collected according to a preset time interval through the temperature sensor 21. Whenever there is a difference between the collected temperature and the target temperature, the temperature control device 23 is activated to adjust the temperature in the greenhouse body until the collected temperature falls into the Within a first preset range, a safe temperature range is additionally set. When the collected temperature is greater than the safe temperature range, the second controller 22 controls the alarm device 25 to give an alarm, reminding the staff to perform emergency control or maintenance. In addition, the second controller 22 controls the display device 24 to display the collected temperature information at different times, so that the staff can conveniently, intuitively and clearly obtain the temperature information in the greenhouse.

The present invention has been described in detail above with reference to the embodiments of the accompanying drawings, and those skilled in the art can make various changes to the present invention according to the above description. Therefore, some details in the embodiments should not be construed as limiting the present invention, and the present invention will take the scope defined by the appended claims as the protection scope of the present invention.

Claims (10)

1. A wind-solar-storage complementary intelligent greenhouse, comprising a greenhouse body, characterized in that it also includes a temperature control system and a wind-solar hybrid power generation system, the wind-solar hybrid power generation system includes a first controller, and the The first controller is connected to a photoelectric conversion mechanism, a wind power conversion mechanism, a battery and an electric control switch, and the battery is connected to the temperature control system through the electric control switch. 2. The wind-solar-storage complementary intelligent greenhouse according to claim 1, wherein the wind power conversion mechanism includes a wind power collection device and a wind power conversion device, the wind power collection device is connected to the wind power conversion device, and the wind power conversion device is connected to the wind power conversion device. The wind power conversion device is connected to the first controller. 3. The wind-solar-storage complementary intelligent greenhouse according to claim 2, wherein the photoelectric conversion mechanism includes a light energy collection device and a photoelectric conversion device, and the light energy collection device is connected to the photoelectric conversion device, The photoelectric conversion device is connected to the first controller. 4. The wind-solar-storage complementary intelligent greenhouse according to claim 3, characterized in that, the light energy collection device is made of a solar film, and the top of the greenhouse body is made of the solar film. 5. The wind-solar-storage hybrid intelligent greenhouse according to any one of claims 1-4, wherein the wind-solar hybrid power generation system further includes a transformer, and the battery is connected to the transformer through the electronically controlled switch, The transformer is connected to the grid. 6. The wind-solar-storage hybrid intelligent greenhouse according to claim 5, wherein the wind-solar hybrid power generation system further comprises an inverter, and the inverter is connected between the storage battery and the electric control switch between. 7. The wind-solar-storage complementary intelligent greenhouse according to claim 5, wherein the temperature control system comprises a plurality of temperature sensors, a second controller and a temperature control device, and the temperature sensor and the first The two controllers are connected in communication, and the second controller is connected to the temperature control device and the electric control switch. 8. The wind-solar-storage complementary intelligent greenhouse according to claim 7, wherein the temperature control system further comprises a display device connected to the second controller. 9. The wind-solar-storage complementary intelligent greenhouse according to claim 8, wherein the display device adopts a touch screen. 10. The wind-solar-storage complementary intelligent greenhouse according to claim 8, wherein the temperature control system further comprises an alarm device connected to the second controller.