NL8401351A - METHOD FOR IMPROVING PLANT GROWTH BY INTERRUPTED EXPOSURE. - Google Patents

Description

* 'i

Method for improving plant growth by interrupted lighting *

The invention relates to a method for improving plant growth in greenhouses and climate chambers by subjecting them to interrupted lighting.

In this description, "greenhouses and climate cabinets" will be understood to mean all fences within which conditions suitable for growing plants, in particular temperature, humidity and lighting conditions, are wholly or partly reproduced artificially.

The use of greenhouses and climate chambers makes it possible to grow plants outside their normal growing season, for example in winter, while the usual growing season generally extends over spring and summer.

To achieve this, it is of course necessary to reproduce within the greenhouses or climate chambers the best conditions suitable for ensuring sufficient development of the plant, in particular the most suitable conditions of temperature, humidity and lighting. The conditions to be used will of course be very different depending on the purpose of growing crops for an average climate such as wheat or tropical or subtropical climates such as cotton and soy.

While the provision of suitable conditions does not present insurmountable difficulties in terms of temperature and humidity, this is not the case with the illumination in greenhouses and climate chambers, especially when it is intended to create the illumination conditions required for the cultivation of tropical or subtropical plants. In fact, the lighting system must then meet Many very pre- 8401351 ► ί? - 2 - Cure conditions: - The plants must be provided with an illumination, which if necessary (ie depending on the crop) can achieve very high values, sometimes exceeding 5,000 lux at the location where the plant, - the lighting must be distributed very uniformly over the cultivation zone, - the lighting system must be placed at a sufficient height above the cultivation zone, so that the plant growth is not disturbed or the treatment required for cultivation , and - finally, in the case of greenhouses, the lighting system must as little as possible prevent the entry of sunlight into the greenhouse from the outside.

For this purpose, it is common to use a set of fluorescent tubes attached to the top of the greenhouse or climate cabinet, the tubes being parallel to each other, side by side and in the same horizontal plane, very close together, so that they together a rectangular source of light 20, the vertical projection of which on the lower part of the greenhouse or climate cabinet represents the area to be illuminated.

For example, to illuminate a ground area of 6 x 6 m, 180 fluorescent tubes, each of 215 watts, are placed at 0.9 m above the zone on which the plant will be placed. The main disadvantage of this system is that, despite the use of a large number of tubes, it is difficult to obtain an exposure (light flux), which reaches 40,000 lux at the plant level, which is completely unsuitable when the intention is tropical or subtropical cultivate plants. Another drawback of this system 30 is that it requires a large number of fluorescent tubes, and thus involves both an important investment and a high energy consumption. The high energy consumption leads to the release of a lot of heat within the greenhouse or the climate cabinet at 8401351.-3- 4 * and it is therefore necessary to provide a more extensive system for controlling the temperature in order to keep it at the desired value. Finally, in the case of a greenhouse 5, in such a system, sunlight is practically completely excluded and, consequently, the light from outside is not used at all.

Replacement of the tubes with more powerful lamps, such as, for example, discharge lamps, the wattage of which can each be 1000 or even 2000 watts, is also not entirely sufficient, because then problems arise of lack of uniformity of the illumination and even in this case it is hardly possible to obtain more than 50,000 lux at the plant level. The drawbacks noted above with regard to the energy consumption and the scattering of this energy in the form of heat within the greenhouse or the fence are of course also present when lamps are used instead of fluorescent tubes. As a result of these inadequacies of illumination in greenhouses or climatic cabinets, it has been found that plants cultivated under such conditions have an appearance generally different from that cultivated in the open field, under optimal conditions with respect to these plants. Those cultivated in a greenhouse or climate cabinet are very often faded, more fragile and less green than those cultivated in the open field. These differences are particularly annoying when the intention is to experiment in a greenhouse or climate cabinet with pesticide products intended for agricultural use and which will therefore usually be used for open field treatment. It is very particularly essential for such tests that the experiments in a greenhouse be as similar as possible to those in the open field.

It is now an object of the invention to overcome the drawbacks of the known methods.

S4Q135? 9 f - 4 -

Another object of the invention is to maximize photosynthesis phenomena in the plants.

Another object of the invention is to maximize the ability of the plants to assimilate carbon dioxide from the atmosphere and produce oxygen.

Another object of the invention is to obtain plants under greenhouse conditions, the growth of which comes as close as possible to that of the open field, with regard to height or size, strength, branching, bud formation and flower formation.

Another object of the invention is to obtain plants with a high chlorophyll content.

Another object of the invention is to provide a method for cultivating plants under greenhouse conditions, using as simple a device as possible and a minimum of energy.

Another object of the invention is to provide a method of cultivating plants in which the light energy falling on the leaves is distributed as homogeneously as possible, whatever the inclination of the leaves and whatever the location of the leaves. leaves on the plant (inside or outside the canopy).

Another object of the invention is to avoid invisible radiation as much as possible, in particular ultraviolet rays. In addition to the dangers to which the people caring for the plants are exposed to such radiation, these radiations often cause deterioration of agrochemicals applied to the plants, thereby nullifying the beneficial effect of these products and the tests, if these are in play.

Other objects and advantages will become apparent from the following description.

It has now been found that these objects can be achieved by the method of the invention.

8401351 #a - 5 -

The method is therefore a method for improving plant growth in greenhouses or climate cabinets, in which - the plants are arranged over a substantially flat and horizontal area, 5 - the plants are illuminated by means of a movable source of light located above the plants and is held in a plane that is substantially horizontal and parallel to the surface on which the plants are arranged, - the light source comprises substantially radiations with wave lengths between 380-800, preferably 450-750 nanometers, - the light source above the plants with a uniform movement, so that an interrupted exposure at plant level is created.

There are many embodiments of the method according to the invention.

According to an advantageous embodiment, the plants are arranged over an area of substantially rectangular shape and the light source also has a rectangular shape, one of the dimensions of which is substantially equal to one of the sides of the zone of a substantially rectangular shape, which must be exposed turn into.

Likewise, the light source moves in a direction parallel to one of the sides of the rectangular area to be exposed (the light source having a dimension corresponding to the other side of the area to be exposed).

In practice, the elongated light source during its course gradually illuminates all points of the substantially rectangular horizontal area where the plants are arranged,

Preferably, the light source runs in a steady, constant speed motion, either in one direction or the other. There may be a back and forth motion in play.

3401351 V ï - 6 -

In the case where the area to be exposed, which is of a rectangular shape, actually consists of a series of rectangles, which can form a closed circuit, the light source can pass along each of these rectangles and also follow a closed circuit itself. In such a situation, the light source always moves in the same direction above it for a particular rectangle to be exposed.

As mentioned above, the elongated light source generally consists of several lamps. These lamps are advantageously arranged within a reflective housing with a substantially rectangular cross section.

Figure 1 schematically illustrates an embodiment of the method in which an elongated light source, formed by a reflective housing (1), incorporates four discharge lamps (2)

15 of 1000 watts each, which are drawn in solid lines within the house, run in the direction shown by the arrows above the counter (3) of a substantially rectangular shape on which the plants to be cultivated are arranged (not shown in Figure 1 ). The elongated light source is moved from one end position A with a regular reciprocating movement

to the opposite end position B, then from B again to A, and so on.

For the sake of simplicity, Fig. 1 does not show the electrical connections which carry the electrical current to the lamps 25, nor the mechanical means which reciprocate the light source. In practice, it is advantageously possible to provide for this purpose two guide rails, which are located above the long sides of the bench (3) and to attach running wheels to both longitudinal ends of the housing (2), so that this housing over these guide rails. 30 sen in the direction shown.

Figure 2 shows yet another embodiment of the invention, wherein the reflective housing (1) located above 8401351-7 - the counter (3) is moved in the directions shown by the arrows, and contains ten discharge lamps of 1000 each watts, denoted as the broken line. The light source consisting of the lamps and the housing runs with a regular movement from 5 A to B and then from B to A with a reciprocating movement. It is of course possible to use a larger or smaller number of lamps than shown in Figures 1 and 2 and the invention should not be limited to the devices shown in these Figures.

As will be apparent from the embodiments illustrated by these figures, the method according to the invention makes it possible to "strip" the entire rectangular horizontal region, indicated above, in a regular manner, thereby giving the intended amount of light. 15 in a very uniform manner.

The distance separating the plane in which the light source runs from that of the rectangular horizontal area on which the crops are placed can be determined depending on the power of the light source and the desired illumination current at plant level. For example, for a distance of 1.6 m between these planes, the light source shown in figure 1 gives 50,000 lux to the plant underneath it vertically at each transition, while that of figure 2, more specifically intended for a climate chamber, gives almost 100,000 lux per transition.

In the case of a greenhouse, it will be clear that such a system provides only very little shielding of the outside light, so that it can be used advantageously alongside.

The running speed of the light source can be chosen within a wide range, although it has been found that whichever plants are grown, the best results are obtained at speeds of 2-8, preferably 4 meters per minute.

840135f

V

- 8 -

The transition cycle duration of the light source can also vary within wide limits, but it is nevertheless advantageous to carry out a transition of the light source across the plant per period from 45 seconds to 3 minutes, preferably one transition per period from 1- 2 minutes.

The invention is now illustrated in a non-limiting manner with the following examples.

Example 1 10

A light source (4 x 1000 watts) as shown in Figure 1 is used for a greenhouse test. The reflector or lampshade (1), which serves as a lamp holder, is provided with rollers at both ends (not shown) so that it may run in the direction of the arrows, on horizontal rails (not shown) which 1.6 m above the long sides of the counter (3), the length of which is 6 m. This light source only gives radiation in the visible area.

Seeds of wheat, mustard and soy are sown in seed trays on this counter, and are kept in the usual state of temperature and humidity. The lamps are switched on. The light source moves back and forth across the counter at a speed of 4 m per minute from 7 a.m. to 9 p.m. It is switched off for the remainder of the time. After 35 days under these conditions, it is found that the plants produced have an appearance that is completely comparable to that of the same plants obtained in the open field.

30 Example 2

Example 1 is repeated, but now one cultivates 64 0 1 3 5 f -r? 9 - 9 - beans in pots under exposure from the start of sowing the seeds.

Half of the bean plants are subjected to intermittent illumination (movable light source) as in Example 1. The other half are subjected to illumination which is identical from the viewpoint of the light source, but not interrupted (solid light source).

After 15 days, 15 leaves are collected from each of the two bean pupations and chlorophylls A and B are extracted by means of a water / acetone mixture and these chlorophylls are then determined spectrophotometrically.

It appears that the plants under fixed lighting contain 0.67 mg of chlorophyll per gram of bean leaf, while plants under mobile lighting contain 0.89 mg per gram, i.e. about 43% more.

Example 3

Example 1 is repeated with different types of plants by carrying out a comparison test with plants subjected to a fixed exposure by the same lamps.

15 days after the start of the experiment, the following observations were made regarding beans and soy plants: 25 Beans

The average height of the plants obtained under movable lighting decreases by 35% compared to the height of the plants obtained under fixed lighting. The plants obtained under movable illumination are therefore shorter, but stronger, more strikingly green and equal to those obtained in the open field. The plants obtained under fixed illumination, on the other hand, have spoiled, that is to say they are extremely high and thin and furthermore have a great tendency to fall because the stem is insufficiently strong to remain upright.

Soy 5 The average height of the plants obtained under mobile lighting decreases by 25% compared to the plants obtained under fixed lighting. However, the plants obtained under mobile illumination are more vigorous, and have an appearance or behavior, as well as a color equal to that of 10 plants obtained in the open field.

Giéfst (Echlnocloa crus galli)

Germination or shoot formation is obtained four days after sowing under movable lamps and eight days after sowing under fixed lamps.

401351

Claims (10)

Method for improving plant growth in greenhouses or climate chambers, characterized in that 5 - the plants are arranged over a substantially flat and horizontal area, - the plants are illuminated by means of a pivotable light source located above the plants and held in a plane which is substantially horizontal and parallel to the surface on which the plants are arranged, - the light source mainly contains radiations of wavelengths between 380-800, preferably 450-750 nanometers, - the light source the plants run in a uniform motion to create interrupted exposure at plant level 15. Method according to claim 1, characterized in that the plants are arranged in an area of substantially rectangular shape and the light source is also in the shape of a rectangle, the one dimension of which is substantially equal to one of the sides of the zone of almost rectangular shape, which must be exposed. 3. A method according to any one of claims 1 or 2, characterized in that the light source is moved in a direction parallel to one of the sides of the rectangular zone to be illuminated, the light source having a dimension equal to the other side of the area to be illuminated. A method according to any one of claims 1 to 3, characterized in that the elongated light source during its course gradually illuminates all points of the substantially rectangular horizontal area on which the plants are arranged. A method according to any one of claims 1-4, characterized in that the light source runs at a constant speed. 6. Method according to any one of claims 1-5, 8401351 ^ V-12-7f, characterized in that the light source makes a reciprocating movement. A method according to any one of claims 1 to 5, characterized in that the zone to be illuminated consists of a series of 5 rectangular zones. Method according to claim 7, characterized in that the light source follows a closed circuit. 9. A method according to any one of claims 1-8, characterized in that the light source passes over the plants once every 45 seconds to 3 minutes. Method according to claim 9, characterized in that the light source passes over the plants once every 1-2 minutes. 8 4 0 1 3 5 t