NL2029343B1 - System for combining agricultural activities with the generation of solar energy - Google Patents

Abstract

The invention provides a system for combining agricultural activities with the generation of solar energy comprising (a) collapsible solar panel carriers and a means for folding up the solar panel carriers, wherein (b) the panels are either translucent/semi-translucent. be transparent or the system contains an alternation of glass plates and (non-translucent and non-semi-transparent) solar panels. Preferably, the system includes a pivot axis which is preferably at a height of 1.5 to 2.5 meters and preferably from 1.7 to 2.1 metres.

Description

System for combining agricultural activities with the generation of solar energy

The invention relates to a system for combining agricultural activities with the generation of solar energy.

The environment is changing and in particular the average global temperature will rise. The consumption of fossil fuels contributes to both environmental pollution and the rise in temperature. To counteract this as much as possible, more and more energy is being generated in other ways, in particular by using solar panels to generate solar energy. Solar parks with large numbers of solar panels are being built and planned more and more. The disadvantage of solar parks is that the surfaces covered by solar panels are often only suitable for generating solar energy. The land on which the solar parks are built must be relatively cheap, which means that the solar parks must either be placed on otherwise fairly useless land, such as desert areas, or that land previously used for agricultural purposes must be sacrificed. “Relatively useless land” can indeed be useful, for example because it concerns a specific nature reserve with specific flora and fauna or because it is useful for recreational purposes.

Such "useless" land is normally far from inhabited areas, so that maintenance of the solar park and/or transport of the generated solar energy can be costly.

An alternative is to place the solar park relatively close to inhabited areas, but this often means that scarce agricultural land, close to inhabited areas, must be withdrawn from food production. If people want to switch to more production of mainly vegetable products with shorter supply lines to the consumer, this is a negative development.

Installations are known that try to meet these objections. For example, it is known to keep animals, such as chickens, under solar panels. However, the soil under the solar panels becomes unusable over time.

Dual-use solar parks are known as “Agri-Voltaic systems”: “Agri” for “agriculture” and “Voltaic” for generating solar energy. Such an installation is known, for example, from Indian Farming 68(01): 20-23; January 2018; Agri-voltaic system: crop production and photovoltaic based electricity generation from a single land unit by P. Santral, R. K. Singh2, H. M.

Meena, R. N Kum, describing an installation containing rows of angled solar panels mounted on poles and facing the sun at an angle, with crops that require a relatively large amount of water grown between the rows. This concerns agriculture in a semi-arid area and the solar panels are used to collect rainwater. Crops that thrive in dry conditions can be grown under the solar panels.

Another installation is known from, among other things, the Sun-Agri project, in which an installation is installed on poles on which solar panels are installed a few meters above agricultural land. The position of the solar panels in relation to the incident sun can be changed so that the amount of sunlight that falls on the plants can be regulated. The poles are so high that agricultural equipment can drive under them.

This type of high construction makes it possible to reach the plants under the solar panels with tools. The accessibility of the plants is a problem for many current dual-use solar parks. If one chooses to use a construction that is low to the ground, it becomes complicated to reach the plants. Solar panels often need to be made movable or slidable. This ensures that this technique is very labour-intensive to use.

This problem is solved with higher constructions of approx. 2-3 metres. However, these types of systems are much less easy to integrate into the landscape. Due to their height, they are clearly visible to local residents and can therefore generally count on less acceptance from the population. From a licensing point of view, higher constructions therefore bring their own problems, even though they offer many opportunities for mechanization with agricultural equipment.

The aim of this invention is to find a middle ground: the described system contains foldable solar panels. For example, the construction can remain relatively low, which ensures more social acceptance, and it is still easy to reach the plants, because the solar panels can be folded away.

To this end, the system contains a tiltable frame (1), on which solar panels are mounted (2). This frame is mounted on a row of posts (3) with a pivot shaft (4). Several rows of posts with a tiltable frame on top are placed next to each other. This makes it possible to rotate the panels 120-160°. There is a distance of 2.5 to 6 meters and preferably 3.3 to 5 meters between these adjacent rows with a tiltable frame (distance D). Each row of piles has a horizontal axis of rotation at a height of 1.5 to 2.5 metres, preferably 1.7 to 2.1 meters (distance

H1). The tiltable frame with the solar panels rotates on this axis. When the solar panels are folded away, the highest point of the construction will be 3 to 5 meters, preferably 3.4 to 4.2 meters (distance

H2).

Because the agri-PV system is intended as a crop-support facility, part of the light will have to reach the plants under solar panels. There are two options to ensure that the light can reach the plants:

- Translucent/semi-transparent solar panels are used. These transmit a portion of light (eg 20-50%, see system 1 in fig. 6). -Standard solar panels are used that let little or no light through and they are alternated with (translucent/transparent) glass plates. Possible combinations are that 1 glass plate is placed per 2 solar panels or 1 glass plate per 3 solar panels. (see system 2 in fig. 7).

Translucent/semi-transparent solar panels are currently only used in small numbers, so these panels are often (small) special productions that are more expensive than normal solar panels that let little or no light through. To allow the light to pass through, there are also fewer solar cells in such panels, so that they can generate less power than standard panels that do not have to let through any or little light. As a result, these panels have a higher investment price per Wp and a longer payback period. By alternating standard solar panels with glass plates, a system is created that lets through sufficient light for plant growth and can also achieve a higher power yield. Internal crop and power research by the patent applicant has already shown that this system enables both a higher power yield and a larger harvest than systems that work with translucent solar panels {higher average weight of the harvested crop}. This innovation is therefore very beneficial for the total power yield, affordability and crop yield.

It is also important for agricultural activities under solar panels that the plants receive sufficient water. This can be guaranteed by using the system in combination with a watering system (5} with an (above or underground) water reservoir for water storage (e.g. misting, spraying or drip hoses). (e.g. by means of drainage or a water gutter} and then use this for watering the crops under the solar panels).

It is also possible to integrate a light sensor into the system. In this way, the system could record the position of the sun and track it throughout the day. This allows the folding to be used to achieve a higher power output. One could also choose to use the inverter as a 'sensor'. In this case, the inverter is used to determine at which angle during which time of the day the power output is maximum.

This variable is then used to determine the angle. By using the light intensity or maximum power output, the system can thus be set to follow the sun throughout the day (see system 3 in fig. 4 and fig. 5).

In addition, agricultural sensors (6) can be integrated into the system, which also gives a good picture of the growing conditions of the plants under solar panels. This data could then be used for automation (smart farming). Examples are measuring the humidity, soil moisture (including measurements at different depths of several soil layers}, temperature, etc. This data can then be used to know, for example, when water needs to be administered to the plants under the solar panels. if the temperature is too high, the panels can also be tilted to allow fresh light.

These and further aspects of the invention are described and illustrated below with reference to the drawing: in the drawing:

Figure 1 shows the tiltable frame with solar panels that is attached to a pivot on poles.

Figure 2 shows the structure before it is tilted or folded up.

Figure 3 shows the structure after it has been tilted or folded up.

Figures 4 and 5 show an exemplary embodiment of the invention, in which a light sensor has been integrated, so that the system can follow the position of the sun.

Figure 6 shows an exemplary embodiment of the invention, in which translucent/semi-transparent solar panels are used

Figure 7 shows an exemplary embodiment of the invention, in which solar panels are alternated with glass plates (in this case 1 glass plate per 3 solar panels).

Figure 8 shows an exemplary embodiment of the invention, in which a watering system is integrated. This system supplies plants below the system with water.

Figure 9 shows an exemplary embodiment of the invention, in which a solar park has been built with the system by placing several rows of the system next to each other.

It will be clear that many variations are possible within the scope of the invention and that the invention is not limited to the examples given above.

Claims (17)

Conclusions: CLAIMS 1. System for combining agricultural activities with solar energy generation comprising (a) a tiltable solar panel frame and means for tilting the tiltable solar panel frame about a horizontal axis of rotation, wherein (b) the panels either translucent/semi-transparent or the system contains an alternation of glass plates and (translucent and non-semi-transparent) solar panels. A system according to claim 1, characterized in that the system comprises a single type of translucent/semi-transparent solar panels. 3. System as claimed in claim 1, characterized in that the system contains an alternation of solar panels and (translucent) glass plates. A system according to claim 3, characterized in that the system contains 1 glass plate per n solar panels, where n is 1 or more. The system of claim 4, wherein n is 2 or 3. A system according to any one of the preceding claims, characterized in that the distance between two rows of solar panels on a carrier varies from 2.5 to 6 meters A system according to claim 6, wherein the distance between two rows of solar panels is 3.3 to 5 metres. A system according to any one of the preceding claims, characterized in that the system is provided with means for tilting the panels over an angle between 120-160°. 9. A system according to any one of the preceding claims, characterized in that the system comprises a pivot axis, the pivot axis being positioned at a height of 1.5 to 2.5 metres. The system of claim 9, wherein the axis of rotation is positioned at a height of 1.7 to 2.1 metres. 11. A system according to any one of the preceding claims, wherein the highest point of the system, when folded up, is between 3 and 5 metres. The system of claim 11, wherein the highest point of the system is between 3.4 and 4.2 metres. 13. A system according to any one of the preceding claims, wherein the system contains a water collector or is coupled to a water collector for collecting rainwater. A system according to any one of the preceding claims, characterized in that the system contains or is coupled to a watering system for the plants under the system. A system according to claim 14, characterized in that the watering system is a sprinkling system, misting system or drip system. 16. System as claimed in any of the foregoing claims, characterized in that the system is provided with means for rotating the solar panels during the day with the position of the sun, wherein the means contain a light sensor. A system according to any one of the preceding claims, characterized in that the system contains agricultural sensors,