DE2044821A1 - Process for growing physiologically and morphologically valuable plants in greenhouses - Google Patents

Description

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Badische Anilin- & Soda-Fabrik AG

Our reference: OZ 26 979 Sws / IG 6700 Ludwigshafen, 7-9-1970

Process for growing physiologically and morphologically valuable plants in greenhouses

Known growing methods for plants in conventionally built greenhouses are in no way practical. These greenhouses in the interior of which certain values of temperature, humidity and brightness are artificially set, and the are separated from the natural outside climate, have the disadvantage, especially for biological studies, that the plants are inadequate to provide light, air and moisture. In addition, the temperature peaks in the summer months have to go through costly shading can be reduced.

In the winter months, artificial light is used to extend the day. To do this, lamps are placed in the greenhouses hung, which has a very negative effect, since the lighting and thus the temperature is extremely high under the lamps, while it is greatly reduced immediately next to it.

All of these factors contribute to the fact that the plants develop unstably and differently. So it is not yet possible to grow plants of high physiological and morphological quality all year round. Especially when testing these plants for plant protection purposes can give a clear and perfectly reproducible physiological result cannot be guaranteed during the examination.

It has now been found that these disadvantages can be avoided if practical conditions are created by the plants in a greenhouse whose side walls are used for interior ventilation shifts vertically and its atmosphere is created by distributing water at the air inlets created in this way moisturizes.

The inventive method is explained by way of example by means of the accompanying drawings A to D, where A is a

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Section through a greenhouse, B a view (1) and a top view (2) on a support board * C a section of a filled support board during irrigation and D an oblique view of tables with supporting boards.

Every building under a greenhouse has a translucent roof with stable, vertically movable side walls (A 1) and used to understand the growing of plants, regardless of the size of the building or its base area.

The vertical displacement of the side walls is to be understood in such a way that one or more side walls, preferably more than one side wall, are displaced vertically somewhat or in full height, ie, P that is raised or lowered ; preferably the side wall is raised.

This creates openings through which the air is constantly and evenly and without being obstructed by any glass parts, as is the case with known greenhouses, into the greenhouse flows (A 2).

When moving at least two walls, it is can be about neighboring walls as well as directly or diagonally opposite walls, a passage is possible, which largely corresponds to the wind movement in the free atmosphere »This makes it possible for the pots to move are constantly in this air flow (A 3) and thus largely are exposed to natural wind movements. The displacement of the side walls can be controlled manually or automatically, i.e. the opening and closing of the ventilation can, for example, be motorized by means of rack and pinion gears or with the aid of pneumatic air cylinders can be carried out manually, semi-automatically or fully automatically. Sine additional roof ventilation can easily be included in this ventilation system.

The fully automatic ventilation and temperature control can be done with the help of suitable instruments such as wind direction meter, Wind pressure gauge and temperature thermostat take place. This makes it possible to keep a rhythm that is largely natural Corresponds to day and night conditions.

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be combined with other known ventilation methods, for example Ventilation by means of openings or fans (A 6 or 10) in the roof or in any gable ends of the greenhouse.

By the above-described vertical displacement of an or several side walls create one or more openings in the Greenhouse through which the greenhouse is ventilated. It is advantageous to move the side walls vertically in this way far, that at the height at which the plants are in the greenhouse, air movement or air circulation occurs. The plants are hit by moving air, so that the action the wind on plants in the wild is mimicked in the greenhouse. This creates conditions in the greenhouse which largely correspond to those in the wild.

In this greenhouse, ventilation conditions are achieved, such as they are given in a vegetation hall or in the open air, whereby the character of a greenhouse is still preserved because the side walls can be firmly closed and the greenhouse is therefore fully suitable for winter.

According to the invention, the through these openings into the greenhouse Incoming air is humidified. This is done by distributing Water at these openings (A 2).

The water can be distributed, for example, by atomizing the water (A 4). This is in the inflowing Air creates a veil of fine water droplets, whereby the air is humidified. Furthermore, you can attach net or grids in front of the side walls, through the .man the openings closes and over which water is allowed to trickle. When the air flows through these nets, it is humidified. The networks have the added benefit of animal intrusion are larger than the mesh size of the net to prevent entering the greenhouse. In this way, for example, the penetration from birds or mice in the greenhouse. the Mesh size of the nets is chosen in such a way that undesirable air resistance when flowing through the air is avoided but otherwise

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on the other hand, the water is sufficiently evenly distributed and the penetration unwanted animals is prevented.

In addition, you can humidify the atmosphere of the greenhouse in the usual way, for example by sprinkling pipes over the Plants or through nozzles flowing out of water on ventilation fans ^ whereby the blown air is humidified.

Since the brightness for the growth of the plants is known to play a decisive role, the plants have to with insufficient natural brightness can be artificially illuminated »It is known, to make this artificial lighting by lamps installed inside the greenhouse. That kind of lighting has the disadvantage that the brightness is distributed unevenly and that the temperature distribution in the greenhouse is through the heat development of the lamps is adversely affected. The latter effect causes the plants to ginger very strongly. they are therefore cannot be compared with physiologically valuable plants and can be used, for example, as test plants in crop protection experiments produce irregular results.

It is therefore advantageous to illuminate the greenhouse with the plants in it when there is insufficient light * in particular So in winter or at dusk, by means of a lighting system located outside the greenhouse Even © causes brightness distribution in the greenhouse * whereby the brightness varies in individual areas of the greenhouse can be regulated differently according to the type of plants growing there and influencing the temperature in the greenhouse Avoided »Using multiple lighting fixtures at different points becomes an undesirable one In addition, the interior of the Greenhouse free of lamps ^ so that the incidence of daylight is not disabled »

In the summer months of the burning effect of sunlight may be at too high temperatures by a reduced Dachberleselung with water w © @ rd n _s which additionally lowering the temperature reaches a few degrees wirdo

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The water of the roof sprinkler and that of the side sprinkler can can be collected in an outer channel (A 5) and e.g. via a pile system into a collecting basin, where it can again be circulated to the nozzles with a pump.

It is used to grow high-quality plants in large quantities advantageous, the earth necessary for this machine half or fully automatically pick up, chop up, sieve, fertilize and mix and the so prepared soil also mechanically Filling evenly into pots semi or fully automatically, these with different plant seeds individually or in a mixture in To sow single or separate crops, to cover with soil and to press down, this work in a confined space with a suitable sowing machine can be carried out. This not only saves manual labor, but it becomes one Uniformity of the preconditions for growing the plants which makes it much easier to grow even plants in large quantities.

The pots intended for the cultivation of the plants, filled with soil and sown or planted, are advantageously placed in support boards (B and C), which have a recess for each pot (B 1 a) and a laterally attached hole (B 1 b and C 2) have as water overflow. ¹

The pots can be operated manually or, as described above, semi-automatically or fully automatically filled with soil and sown or planted. They are done manually or automatically placed by the sowing machine in the support boards, which, like the pots, can be made of any material. Essential The only thing is that the pots and the support boards are made of a material of sufficient mechanical strength that can withstand the action is sufficiently resistant to moisture. Both the pots and the supporting boards can after the cultivation of the Plants can be reused, only the supporting boards are advantageous If the supporting boards or the pots are reused, reused, it is advantageous to use them manually or with Using an automatic feed to lead through a washing system, for example an ultra-washing system (washing with ultra-

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sound), and can therefore be cleaned gently and quickly. A suitable material for pots and support boards is, for example a moisture-insensitive plastic, e.g. Polyethylene, Polyamide or polystyrene copolymers. Shouldn't the pots can be reused, they can be made from paraffinic cardboard There are peat or similar material, which after use rots together with earth in the open field. The above Soil stored in this way for a period of several years if possible can then be used again directly or after damping are »As a growing vessel for plants, apart from round pots (C ^), which are mentioned here as an example, of course other vessels of any shape, e.g. angular, square or oval, can also be used. Accordingly, the L · Deepening of the support boards adapted to the respective shape of the vessel «The support boards have one for each pot (C 4) Well, the diameter of the well is slightly larger than the pot (C). When sprinkling the pots (C 9) in In the greenhouse, water can collect in the recesses in the support boards, so that each pot is surrounded by a water supply (C 7) which is connected to the earth (C β) through a hole in the bottom of the pot (C 5).

At the bottom of the wells, stools (C 3) are expediently attached, which on the one hand prevent the pots from being fully on the floor, but on the other hand allow the sprinkling water (C 7) to be absorbed with the fertilizer. W by the side of the recess mounted Hole (B lb and C 2) is limited this water supply, because excess water flows off through this hole. Therefore, if the water output of these nozzles is not uniform when the pots in the greenhouse are sprinkled using nozzles (C 8), the differences that occur from one pot to the other are compensated for by the respective overflow in the individual recesses of the support boards. In this way, even watering of the pots is achieved regardless of the water output from the sprinkler nozzles. This method also has the advantage that the time intervals between the individual sprinkling of the pots can be extended because each pot has a water supply.

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This allows you to alternate between rain and drought in the field are largely transferred to the plants in the greenhouse in an excellent manner.

Another advantage is that in the recess of the support boards Before setting the pots, the appropriate fertilizer (C 7) can be filled in automatically for each crop. A top dressing is then no longer necessary, as the addition of water also means fertilizer, e.g. slow-acting nitrogen fertilizer or plastic-coated fertilizer as a nutrient solution (C 7), den Plants are fed from below through the bottom hole (C 5) for a longer period of time.

The support boards in the greenhouse with a forklift truck are advantageous (Forklift), because this makes it easier and more flexible to adapt to all transport problems in the greenhouse Transport is guaranteed.

There is a corresponding device on the fork & apler, which makes it possible to take several support boards with the pots from the sowing machine and then individually to prefabricated ones Set down tables as described below. The forklift can also be used to remove the containers and used for further transports.

The support boards with the pots in them can be set up in the greenhouse in the usual way on tables. It is advantageous to place the supporting boards on racks (A 7, 8 and D). These racks have parallel horizontal bars (Holne) (A 8 and D 1) on which the support boards (D 2) are placed. This ensures that the supporting boards are largely free in the greenhouse (D). The ventilation below the supporting boards is therefore not hindered (A j5). In addition, the floor of the greenhouse can be cleaned more easily and the maneuverability of the forklift is not restricted when transporting the supporting boards. The excess water that runs off when the pots are sprinkled can flow out of the greenhouse unhindered through a system of canals. On the other hand, an under-table heater can be attached to the frames (A 7 and D 3) (A 9 and D 4),

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The method according to the invention can be regulated fully automatically and thereby the growth conditions in the greenhouse in terms of light, air, moisture and transport regulate much easier and cheaper.

The following examples show that the used according to the invention Plants both in their size and in their resistance to a herbicide to the plants in the field correspond.

example 1

The plants Triticum aastivum, Zea mays, Avena fatua, Beta vulgaris and Gossypium hirsutum became simultaneously

I in the field
II according to the invention
III in a well-known greenhouse

used.

When awake for 14 days, the result was as follows ί The plants from I and II were in habit and height almost equal ^ while the plants from III are considerably larger and were not natural in habit.

The table below shows the height of the plants in cm (average values of 50 plants each).

Tabel

plants I. II III Triticum aestivum 9.2 9.1 "11.3 Zea mays 5.7 5.8 8.6 Avena fatua 7.0 6.9 10.4 Beta vulgaris 2 * 3 2.5 5.7 Gossypium hirsutum 8.0 8.3 12.1

2098Ί2 / 0090

Example 2

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The plants Zea mays, Alopecurus myosuroides, Apera spica venti, Stellaria media, Chenopodium album, Amaranthus retroflexus and Cyperus rotundus were simultaneously

I outdoors _a .

II according to the invention III in a known greenhouse

used.

After 10 days the plants were given a uniform dose of a known herbicide treated evenly. After 5 weeks it was found that the sensitivity of the plants from III was significantly greater than that of the plants from I and II.

The table below gives the result of the damage to the plants in percent again (average values of 50 plants each).

Tabel

plants

II

III

Zea mays

Alopecurus myosuroides Apera spica venti
Stellaria media
Chenopodium album
Amaranthus retroflexus Cyperus rotundus

70 75 70 74 50 40

0 20th 72 100 80 100 70 ' 95 11 100 53 85 45 8o

0 = no damage 100 = complete destruction

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Claims (8)

- ίο - o.z. 26 979 Claims Process for growing physiologically and morphologically valuable plants in greenhouses, characterized in that the plants are grown in a greenhouse, the side walls of which are displaced vertically for interior ventilation and the atmosphere of which is moistened by distributing water at the air inlet openings thus created. 2. The method according to claim 1, characterized in that the greenhouse is illuminated with insufficient brightness by means of a lighting system located outside the greenhouse. 3 »Method according to claim 1, characterized in that the openings created by the vertical displacement of the side walls are closed by nets. 4. The method according to claim 1, characterized in that the soil necessary for growing the plants is picked up semi-automatically or fully automatically, crushed, sieved, fertilized, mixed and the soil prepared in this way is filled into pots by semi-automatic or fully automatic sowing machines with plant seeds sown, covered with soil and pressed down. 5. The method according to claim 1, characterized in that the pots filled with soil and sown or planted are placed manually, semiautomatically or fully automatically, in supporting boards which have a recess for each pot and a hole on the side for each recess. 6. The method according to claim 1, characterized in that the support boards are transported in the greenhouse by means of a forklift. 7. The method according to claim 1, characterized in that the supporting boards in the greenhouse are placed on racks with spars. 8. The method according to claim 1, characterized in that the support boards, pots or growing vessels after use 209812/0090 " ⁿ " - Il - O.ζ. 26 979 brought to a washing facility manually, semi-automatically or fully automatically and preferably by washing with assistance Ultrasound cleans. · Badische Anilin- & Soda-Fabrik AG Sk; Sign. 209812/0090