SE424399B - Process for growing plants - Google Patents

Abstract

The invention relates to a process for growing plants that have a stem. In the process according to the invention each plant is fixed at its upper end, while its lower end, with its root system 25,27, is in a dark or light-deprived space 17. The plants develop aerial roots 29,31 there, because they are sprayed with a nutrient solution in the dark space. As the plants grow, their lower leaves are removed. The parts thus laid bare 28,30 are pushed down to the dark or light-deprived space, whereupon aerial roots develop on them too. This procedure is repeated as the plants grow, keeping the part of the plants with leaves within a certain height. <IMAGE>

Description

There are also other methods for keeping the fruit-bearing part of the plant at a suitable picking height, which, however, need not be discussed further here.

A plant with a long stem needs to absorb relatively more energy in order to distribute the plant nutrients absorbed in the root system to the genetic and vegetative part of the plant, which means that it is not economical to let the plant grow as long as possible, especially as the older parts of the trunk eventually become senile and woody. Therefore, and due to the fact that the vegetation decreases during the light-poor part of the year, all the plants are torn out of the greenhouse once a year, usually during the winter, and after disinfection of the greenhouse, a new culture is planted. It is realized that this annual regeneration of the plant population is not only laborious and time-consuming but also expensive, as in large greenhouses it is a question of a non-contemptible number of plants that must be replaced each time.

The invention aims to create the opportunity to have, if not perpetually, at least very long-lived plants in the greenhouse, which can bear fruit year after year without the yield decreasing, so that one escapes the troublesome and expensive annual rejuvenation of the plant population.

To this end, a method of the kind indicated in the introduction is proposed, which according to the invention has obtained the features according to claim 1.

In addition to the plant being long-lived when applied in this way, it can be kept constantly at a height that allows convenient picking of the fruits. As it grows, it is lowered so that the growth is, so to speak, transferred to the lower end of the plant, where the plant can be gradually cut, so that its total length is kept within certain limits, without this adversely affecting the growth of the plant or fruiting.

In the method of growing plants proposed according to the invention, another aspect also comes into the picture, at least in the case of tomato plants. It has been shown that some plants are what are called "super-plants", which give a significantly higher yield than other plants. Such "super-plants" occur only to a few percent in each plant population in a greenhouse, but of course you want many of them, because they give the cultivation increased profitability.The method according to the invention creates an opportunity for this, because in the long run one can sort out "normal" plants and leave the "superplants", so that you eventually get a cultivation with "eternal" plants which for the most part consist of abundantly yielding "superplant".

To clarify the invention, an exemplary embodiment will be described in the following with reference to the accompanying drawings, in which FIG. 1 is a perspective view of an arrangement for growing tomato plants by applying the method according to the invention, while FIG. 2 is a side view of this arrangement, showing a plurality of plants in different stages of cultivation.

In FIG. 1 shows a cultivation bench consisting of an elongate tunnel with horizontal top wall 10, a vertical side wall 11, which extends from the top wall down to a gutter-shaped trough 12, which is located below the top wall, and a vertical side wall 13, which ends at a distance above the trough, so that an opening along the cultivation bench is formed between the lower horizontal edge 14 of this side wall and an upper limiting edge 15 of the trough. The cultivation bench can be supported by uprights 16, extending which are preferably arranged unilaterally, as shown, so that the opening between the edges 14 and 15 is completely free of uprights. The top wall 10 and the two side walls 11 and 13 can be made of sheet metal or of rigid opaque plastic, which latter material is also a suitable material for the trough, but it is also conceivable to let the top wall and side walls be formed of a thick opaque plastic foil. which is laid over a framework, which is supported by the uprights 16. The top wall and the side walls delimit a dark or light-poor space 17, which is accessible from above through a number of circular holes 18, which are distributed at regular intervals along the top wall 10. Optionally For example, the opening between the edges 14 and 15 can be closed with a fold-up door or with an opaque plastic foil, which can be pivoted, pulled or rolled up from its opening covering position. The dark or light-poor space should be closed at the ends of the cultivation bench.

Inside the space 17, a pipeline 19 extends substantially horizontally at some distance below the top wall 10.

This pipeline is provided with branched nozzles 20, there being a nozzle between each pair of adjacent holes 18. Nutrient solution of suitable composition is pumped under pressure to the line 19 and thus to the nozzles 20, which are connected. -........ <.. e-_f ~ f. Arranged to each direct a shower 21l of nutrient solution in each direction in the longitudinal direction of the pipeline and the cultivation bench, as marked in the drawings. The nutrient solution is collected in the gutter 12 and allowed to flow to a storage tank to be recirculated to the nozzles.

Above the cultivation bench, a fixed clamped line 22 runs in the middle over the holes 18 in the top wall 10 at a distance above this wall which can be, for example, about three meters. Plants 23, which have been pulled up to a suitable size by conventional cultivation, preferably soil-free cultivation, are suspended in hanging ropes 24, which are attached to the tensioning rope 22, in that the plants are clamped or wound on these hanging ropes. When the plants come from the point of application, they have a root ball 25 of some moisture-absorbing material, in which the plant has been allowed to grow up during the application of nutrient solution to the moisture-absorbing material.

The plants hang with this root ball inside the space 17. The root ball is inserted into the space from above through the holes 18, which must be large enough to let through the root ball.

Referring to FIG. 2, it can be assumed that the plant on the far left is a plant that has been inserted into the cultivation bench quite recently. This plant has been designated 23A and it apparently has its root ball 25 approximately at the level of the line 19. It receives its nutrition from the nutrient solution showers 21 and it is kept growing in this way, the nutrient solution being adapted to give optimal growth and fruiting of the plant.

Eventually the plant grows up to the tension line 22, as shown with respect to the plant 23B closest to the right of the plant 23A, and it is observed that the plant has developed its root system in the dark or light-poor space, so that aerial roots 2? sticker ut1u'n fi khxqen25. Now remove the leaves on the stem 26 over the lower part of the plant immediately above the top wall 10, for example over a portion 28, and lower the plant from the rope 22, so that the root ball 25 will hang further down in the space 17, where also the exfoliated party 28 is now located. The next plant 23C is in this position. As the plant grows at the top, this portion 28 in the dark or light-poor space 17 will develop aerial roots 29 above the plant's existing root neck, so that a new root neck is created on the plant adjacent to the underside of the top wall 10, as shown with respect to the next plant in the row. , plant 23D. Now the previously described immersion procedure is repeated and a new exfoliated portion 30 is introduced into the space 17, the plant 23E, where it eventually emits aerial roots 31, the plant 23F. Again, the plant is now immersed after the previous defoliation, so that the plant will hang like the plant 23G in FIG. 2, and now the root ball 25 is completely close to the gutter 12, so that the aerial roots 27 projecting from it may even dip into the nutrient solution contained in the gutter. At this stage of the plant, the lower part of the root system is cut, so that the plant has the appearance shown with respect to the plant 23H on the far right in FIG. 2. The cutting of the lower part of the root system can optionally take place with a machine, which is advanced along the cultivation bench and with a rotating knife or the like cuts off the root system just below the lower edge 14 on the side wall 13.

In the manner described, one then continues to peel off the lower part of the plant from time to time just above the top wall 10 and then to lower the plant as it grows, and the root system from time to time, when it has become too long, is cut off at the bottom. . The plant can thus be kept growing in the space bounded at the bottom by the top wall 10 and upwards by the horizontal tensioning line 22, and in this space one can easily access to pick the fruits from the fruit-bearing lower parts of the plant.

In the description above, tomato plants have been mentioned as suitable plants for applying the cultivation method according to the invention, but other plants can also be grown in the same way. Plants with liana-like growth methods, such as cucumbers, melons and pumpkins, can thus be advantageously grown as described, but application to additional plants should be close at hand to those skilled in the art.

The cultivation bench described here is only an exemplary design, and this constructive detail in the context can of course be the subject of development in various respects. The supply of the nutrient solution as a mist in the dark or light-poor space can take place in other ways than with nozzles or with the use of nozzles which are arranged and placed in a different way than that shown here. However, the arrangement shown is advantageous in that the nutrient solution supplied to them

Claims (2)

10 15 20 7807512- * 4 the aerial roots located at the top can flow from these down to lower aerial roots, so that the plant is given the opportunity for an abundant uptake of nutrients well distributed over the root system. PATENT REQUIREMENTS A method of growing a plant (23) with a stem, which is supported by hanging it in an anchor (22, 24) at the upper end of the plant, wherein nutrient solution is supplied to the root system (25, 27) of the plant at the lower end of the stem, and the plant, as it grows, is defoliated over a portion (28, 30) at the bottom and lowered from the anchorage (22, 24), characterized in that the root system (25, 27) is enclosed in a dark or light-poor outlet. space (17), in which a mist (21) of nutrient solution is maintained, and that the stem is exfoliated above the dark and light-poor space (17) and immersed with the exfoliated portion in the space at regular intervals as the plant grows. A method according to claim 1, characterized in that the nutrient solution is sprayed out into the dark or light-poor space (17) in the upper part thereof, where the root system (25, 27) and then the exfoliated portion (28, 30) and from this later developed aerial roots (29, 30) are initially located.