NO138744B - PROCEDURE FOR GROWING PLANTS WHICH INDIVIDUALLY GROW IN A SEPARATE CULTIVATION BED AND APPARATUS FOR PRACTICING THE PROCEDURE - Google Patents

Description

This invention relates to a method for growing plants that grow individually in a separate cultivation bed which may consist of soil or cultivation blocks, and with a volume sufficient to hold the plant, as well as an apparatus comprising a cultivation trough with a conveyor belt for carrying out the method.

It is common knowledge to grow plants in oblong plant boxes which are supplied with water and nutrient salts to a suitable constant level. At the same time, the boxes can be placed in a stair-like stand, so that a plant can freely grow in height. With this known system, which is generally referred to as "water culture", an improvement is achieved compared to ordinary cultivation, namely a constant humidity in the bed. The disadvantage of the system is i.a. that there is no possibility of increasing the plant spacing in line with the plants' growth, which is why the system requires a large cultivation area per production unit.

To remedy this deficiency, it is known to place the beds in a holder that allows the individual plants to come at a distance from each other in line with their needs.

Furthermore, it is known to place flowerpots in a holding device to simultaneously accommodate and move the pots in step with the growth of the plants and thus the need for more space.

However, these known principles for increasing the plant distance in step with the plants' growth do not allow for the simultaneous use of a per se known channel system for the supply of water and fertilizer solution, just as the known cultivation systems do not provide any significant labor savings or energy savings thanks to the increased productivity and thus reduction of the required cultivation area. This is achieved according to the invention when a plant is sown in each bed, which beds can stand close together during the germination of the seeds, after which the beds before or after sowing are placed on one or more conveyor belts, each of which is led forward into a cultivation trough where cultivation regulating media is supplied to the plants and drained from the bottom of the channel, which band feeds the beds in the channel at a distance suitable for the stage of development, with the distance being increased both between the individual beds on the band and between adjacent channels in the direction of the bands' feed in line with the plants' space requirements.

Hereby it is primarily achieved that the supply of cultivation-regulating media, which continuously takes place in the gutters, means that the plants can be dosed very precisely depending on the immediate growth conditions, and the excess part of the cultivation-regulating media can be drained from the gutter under the bed and root mass . This ensures that the residual amount of harmful substances in the plants can be reduced to an unknown level. At the same time, the quality of plant material is increased, as they are of very uniform quality. In addition, an optimal utilization of the cultivation area is achieved, as during the growth of the plants at any stage of development, the individual plant is allocated the most suitable space, which is achieved when the distance between the beds is increased in the gutters and between the gutters.

By using the gutter forms and methods referred to in claims 2 and 5 to increase the plant distance, labour- and space-saving cultivation methods are achieved.

The means referred to in claim 6 for carrying out the method, namely a trough with channels partly for the supply of water and nutrients as well as possibly hot or cold water for regulating the root temperature and partly with drainage for the return of excess liquid and with conveyor belts for feeding the plants in the gutter, as this can suitably be provided with a lid to limit evaporation from the beds, and which ensures that no condensation forms on the underside of the leaves, protects the roots from light and prevents algae formation, as referred to in claim 7, is particularly suitable for this form of cultivation.

The conveyor belt referred to in claims 8 and 9 is particularly suitable where there is to be a certain liquid reservoir in the beds, and finally the means referred to in claims 10 to 13 for increasing the distance between the beds have proven particularly suitable.

The invention will be described in more detail in the following with reference I to the drawings, where: Fig. 1 shows a cultivation system seen from above with equal and parallel channels, fig. 2 shows the same cultivation system after the first harvest! fig. 3 shows a system where equal channels are arranged in a fan shape, fig. 4 shows a system where the number of gutters is reduced in line with the growth of the plants, fig. 5 shows a continuous gutter with loops that increase the distance between the plants, fig. 6 shows a sectional view of a channel with a belt, fig. 7 shows another embodiment of a belt seen in section, fig. 8 shows the same band seen from the side, fig. 9 shows a further form of the band in its contracted position, fig. 10 shows the same in an extended position, fig. 11 shows the same band seen in section XI-XI in fig. 10, fig. 12 shows a further embodiment of a band in its contracted position, fig. 13 shows the same band in an extended position, fig. 14 shows an embodiment of a carrier in its retracted position seen from above, fig. 15 shows the same carrier in its folded position, fig. 16 shows another embodiment of a driver in the rotated position seen from above, and fig. 17 shows the same carrier in the interior position.

With reference to fig. 1, the method can be explained in connection with a cultivation system for e.g. salad consisting of a number of parallel channels 11 which are arranged e.g. in a greenhouse. The starting point for production is, in this case, a number of cultivation blocks that are placed on a conveyor belt 1-4, which blocks are watered at 1. The next step is the sowing of a seed in each block at 2, after which the blocks are brought to germination at 3. The blocks are placed with a certain smaller mutual distance, which in the case of salad production is approx. 2 cm, on conveyor belt 4, where they stay approx. 10-14 days. At 5, the blocks 21 are transferred to the next phase 6 of the system, as they are placed on belts 20 in channels, as will be seen from fig. 6. The distance between the blocks can now be doubled in relation to the conveyor belt 4 and a corresponding distance is kept between the channels 11. In the channel, the necessary cultivation-regulating media such as water, nutrient salts etc. are added, which will be explained later during the description of the channels.

After a suitable time at the seedling stage in the gutters at phase 6, in the case of lettuce, corresponding to approx. 10-14 days, the plants are sorted and moved, e.g. via a conveyor belt 9 out onto the next set of gutters in phase 7, where the mutual plant distance is quadrupled compared to phase 6. The distance between the gutters is normally equivalent to the distance in phase 6.

When the plants have grown the same number of days as firewood

the previous phases, the distance between the channels is increased by shifting laterally to phase 8. This position is shown in fig. 2. Here

the cultivation phase ends, as the plants are ready to be harvested for the salad after the same number of days as in the preceding phases, and the plants are then taken out of the gutters by means of the conveyor belt to a transverse conveyor belt 10 for packing etc.

This cultivation method takes place continuously, as new plants are brought to sprout on the conveyor belt 1-4 as soon as the previous batch has been transferred onto the channels at phase 6. When the channels are thus positioned as shown in fig. 2, small plants from this phase 6 are transferred via the conveyor belt 9 to the next gutter system at phase 7. When the gutters at phase 8 are harvested as first mentioned, the gutters are pushed together and phase 7 transitions to phase 8 as shown in fig. 1.

A gutter system where the plants can remain in the gutter on the belt and thus do not need to be transferred to other gutters is shown in fig. 3. The channels 11 are arranged in a fan shape, so that two such systems can be placed in a greenhouse, starting at each end at the small plant phase 6. The channels are stationary, while the belt can be equipped with devices, which increase the distance between the plants in pace with their growth. "At the same time, their displacement in the gutter means that the distance to the adjacent plants in the neighboring gutter is increased.

Another gutter system shown in fig. 4, consists of

a number of gutter pieces 11•which accommodate the small plants at phase 6. By transferring the plants to the next cultivation phase 7, the number of gutters is reduced so that a simple distance to the neighboring gutter is thereby achieved. At the same time, the chute at phase 7 can be differently dimensioned or provided with the possibility of supplying media, which is required at this phase. And thus the system can be expanded, possibly until it ends with a single channel, after which the plants have grown sufficiently.

Furthermore, a cultivation system can be used where the channel 11 is unbroken, and the cultivation therefore takes place in a channel, as in the case of the fan shape in fig. 3. The gutter can be curved so that in some phases 6, 7 and 8 a suitable distance is kept from the plant in the parallel gutter parts. Conveyor belts with built-in means for increasing the plant distance through the gutter can also be used here.

In order to utilize this method with the greatest possible advantage, a chute with a conveyor belt can be used, as shown in fig. 6. The chute 11 is constructed as a U-shaped chute with a bottom 13 and sides 12. Instead of a U-shaped chute, other forms of chute can of course be used, such as a chute formed by a pipe that is slit on along the pipe, which slot corresponds to the opening of the U-channel above. Channels 14, 15, 17 are placed at the bottom of the chute which run in the longitudinal direction of the chute. Furthermore, there are controls 18,19 for a conveyor belt 20 which can be displaced through the chute. Between this band 20 and the bottom of the gutter 13, a channel 25 is formed. As can be seen from the figure, there is a clamp placed in the band 20 which serves to hold a growing block 21 with a plant 22. Above, the gutter is closed with a pair of yielding lips 2 3 which enclose the plant's leaf, but at the same time allow displacement of the band with the plant in the gutter.

The belt can be designed so that nutrient liquid can collect in the middle of the belt. This promotes root formation in the middle and the side edges of the tape are kept clear at the start of the growth period. This further ensures that the plants' roots approach each other and quickly form a continuous longitudinal wick.

As an example of the use of the channel for supplying culture-regulating media, it can be mentioned that behind the channel 25, water and nutrient liquid can be put under pressure. This liquid sprays through some outlet holes 16 into the cultivation blocks 21 in such an amount that the plants are continuously supplied with liquid. This direct supply through outlet holes further ensures that fresh oxygen-containing nutrient liquid can be dosed evenly along the entire length of the chute so that lack of oxygen is avoided. As shown, the belt 20 is provided with high side walls which are bent towards the inside of the chute at the top. This ensures that a liquid reservoir 24 is formed in the band so that the plants' roots can take up water and nutrients in this reservoir. The bent edge at the top further ensures that the roots do not grow significantly out of the tape. At the same time, the root mass on the side holds the plant in the gutter. Surplus liquid runs over the belt into the chute's bottom channel 25, from where it is drained to a collection tank, as the chute has a certain fall towards the collection point, from where it is led to renewed use after analyzes etc., which ensures that the right amount of nutrients is always supplied. In the opposite channel 14, CO2 can be added which can slowly seep up around the leaves, whereby an economical dosage is ensured.

As the plants need a specific root temperature, temperature-regulating media, such as hot water, can be added to the lower channels 17 in the bottom of the gutter 13.

Additional channels can be arranged in the gutter for the supply of hot or cold air, systemic poisons against plant diseases, algae control agents, growth retarders, flower-inducing agents, root formers, etc.

Where smaller blocks 21 are used, the band 20 can be raised in the chute and slide in a higher-lying guide 19. This also provides the possibility of returning the band via the underlying guide 18.

The channel's closed form with yielding lips 23 ensures that the channels have a high air humidity which prevents the closing of the outlet. the holes 16 with crystallized nutrient salts. This reduces the formation of condensation on the leaves and thus reduces fungal and disease attacks on the leaves. The light is further excluded from the inside of the gutter, whereby root growth is ensured and algae formation is prevented, as mentioned before. This further ensures the roots' oxygen and nutrient needs.

A slightly different band construction can be used as shown in fig. 7 and 8 and which consists of a flat central part 26 which is provided on the side with longitudinal thickenings 2 7 which secure the liquid reservoir 24. These thickenings can be further hollowed out and this creates channels which, among other things, can be used for the flow of culture-regulating media to ensure the right growth

In order to ensure the necessary distance increases between the plants in a simple way, it can be used as shown in fig. 9-11 showed tape. A number of angled driver sections 28 are held together by a piece of wire 29, so that the sections with the beds can be pushed together, as shown in fig. 9, in the seedling stage. By pulling on the band, the distance is increased until the band is taut, as shown in fig. 10. In this position, the plant is fully cultivated.

A band construction which allows for a stepless variation of the plant distances depending on the -tract is shown in fig. 12 and 13. Here, the sections 28 are connected by means of springs 30 which hold the sections close together when unloaded, as shown in fig. 12. When pulling, the springs are tensioned and the distance can be adjusted depending on the pulling force.

The beds can be moved forward by means of a driving device shown in fig. 14 and 15. Wire pieces 32 connect a number of wire winders 31, which are arranged so that the wire 32 is rolled up when there is no tension in the wire 32, as shown in fig. 14. An arm 33 is attached to each reel 31, as when pulling the thread

IN

in the direction of the arrows, whereby the winders are turned, swing out as shown in fig. 15 and moves the individual beds 21 or possibly pots forward in the direction to the left in the drawing, whereby the distance between the individual beds is increased corresponding to the unrolled amount of thread.

Finally, a spring-loaded carrier arm 35 can be used which is shown in fig. 16 and 17. It is rotatably attached to a holding piece 34 which is in turn attached to a pulling wire 3 2 which may possibly be springy and thus yielding. The arm 35 is held resiliently against a stop 36 in the extended position of the arm, as shown in fig. 16. When returning in the direction of the arrow, towards the right in fig. 16, the arm is turned in at the passage of the block 21 for in a forward stroke to the left in fig. 16 to swing out and take the plant 21 with it. By increasing the wire length between the individual holders 34, the distance between adjacent beds 21 on the belt is increased accordingly.

As an example of the increase in production that can be achieved with this cultivation system, it can be mentioned that a salad production that normally yields approx. 150/m 2 cultivation area per year under Danish conditions, can be increased to approx. 400-500 pcs./m 2 cultivation area per year, since by comparison it can be stated that a normal production is approx.

150 - 200 pieces/m 2 cultivation area per year.

The production time, i.e. the time from sowing to harvesting, can still be reduced by approx. one week compared to normal cultivation methods.

By automating transport and sales from one phase to the next, as well as an automatic control system for supplying the cultivation-regulating media in the gutter and in the greenhouse, labor can be reduced by up to 90% compared to the known cultivation methods.

In addition, there is a very uniform quality, which is ensured by the completely uniform growth conditions that the plants receive at each stage of development. Finally, as previously mentioned, plants can be produced with this system where the harmful content of residual amounts in the plants is reduced, as with this system you can dose precisely depending on the immediate growing conditions. As an example, it can be mentioned that the nitrate content in lettuce can be limited to 400-600 p.p.m. against the currently normal nitrate content of 6000-12000 p.p.m.

Furthermore, the need for spraying against diseases is reduced, as the conditions for disease attacks are reduced. All in all, this cultivation system achieves an increase in function, quality improvement, affordability at the same time that improved products can be produced with regard to nutrition.

Claims (13)

1. Method for growing plants (22) that grow individually in a separate growing bed (21) which can consist of soil or growing blocks and with a space that is sufficient to hold the plant (22) and which can be given different mutual distances , characterized in that a plant (22) is sown (2) in each bed (21), which beds can stand close together during the germination of the seeds (3), after which the beds are placed before or after sowing on one or more conveyor belts (20) which each is advanced into a cultivation trough (11), where cultivation-regulating media is supplied to the plants and drained from the bottom of the trough, which band (20) advances the beds into the trough (11) with a mutual distance suitable for the stage of development, as the distance is increased both between the individual beds (21) on the belt (20) as between adjacent gutters (11) in the belt's forward direction in line with the plants' space requirements. 2. Method according to claim 1, characterized in that all channels (11) are equal and arranged parallel to each other in the same plane, and where the distance between the channels is created by parallel-parallel displacement of these. 3. Method according to claim 1, characterized in that all channels (11) are equal and arranged in a fan shape in the same plane with essentially the same mutual angle and close together at the end of the channel where the beds are placed on the conveyor belt. 4. Method according to claim 1, characterized in that all channels (11) are equal and arranged parallel to each other in the same plane, and where the distance between the channels is obtained by reducing the number of channels, as the beds from two or more bands (20) are collected in a subsequent gutter. 5. Method according to claim 1, characterized in that the channel (11) is continuous and curved, so that the distance between the individual loop pieces is increased. 6. Apparatus for carrying out the method and comprising a chute and conveyor belt according to claims 1-5, characterized in that the chute (20) is substantially U-shaped and where the bottom (13) and sides (12) are provided with a number of continuous channels (14, 15, 17) which, where the channel is used for the supply of cultivation regulating media, are provided with outlet holes (16) towards the inside of the channel, and where a control is arranged in the sides (18,19) for a continuous conveyor belt (20) which supports the beds (21), the space (25) between the belt (20) and the bottom (13) forming a drainage channel for the excess liquid. 7. Apparatus according to claim 6, characterized in that the chute (11) is closed at the top with a resilient lid (23) which allows the plants (22) to pass through and move in the chute. 8. Apparatus according to claims 6 and 7, characterized in that the belt (20) consists of a flat bottom with upturned sides, which ends at the top by being bent towards the inside of the chute to form a liquid reservoir (24) for the beds (21) on the chute. 9. Apparatus according to claims 6 and 7, characterized in that the band consists of a flat intermediate piece (26) to support the beds (21), and where there is a longitudinal thickening (27) on both side edges which forms sides in the liquid reservoir ( 24). 10. Apparatus according to claims 6 and 7, characterized in that the belt consists of driver sections (28) which are connected to each other with a wire length (29) that corresponds to the final distance between the sections (28), as a bed (21) is placed on each section. 11. Apparatus according to claim 10, characterized in that the driver sections (28) are connected to each other by means of a spring (30) which, in its unaffected position, holds the sections (28) together and in the event of tension, the distance between the sections increases depending on the tension. 12. Apparatus according to claims 6 and 7, characterized in that plant carriers consisting of spring-actuated wire winders (31) with carrier arms (33), which, depending on the pull of a connecting wire (32), unroll wire and turn the arms (33) out to carry the beds (21) and thereby increasing the distance between them, is arranged in the channel (11). 13. Apparatus according to claim 12, characterized in that the carriers are made up of a wire (32) attached at intervals, they are kept thicker (34), each of which is provided with a rotatable carrier arm (35), which is spring-loaded against a stop ( 36) and against the spring force can be turned in when passing the beds (21).