NL9420014A - Growth system for plants. - Google Patents

Description

Short designation: Growth system for plants.

The application relates to a plant growth system, which is placed in a channel or trough without the use of organic growth medium, but fed with a nutrient solution, and where the channel or trough includes means for draining excess nutrient solution and such as set out in detail in the heading of claim 1.

For many years it has been known to cultivate plants in so-called water culture or hydro systems where the plants grow in an inorganic growing medium, for example rock wool or similar material, or where the plants grow entirely without any growing medium, since only a container for the roots of the plants is used. In such aquaculture systems, the roots of the plants are continuously fed with a nutrient solution, which is normally recycled and usually controlled in terms of food and oxygen content, and is cleaned of impurities and root secretions, if any.

In known systems of the type defined in the preamble of claim 1, the channel or trough is arranged with a slight downward slope and the nutrient solution is supplied at one end of the trough and discharged at the other end, ie the bottom end, from which end it is returned to a purification plant in which the content of nutritious salts etc. in the nutrient solution is controlled and in which the oxygen content is controlled, after which the solution is reused. Such systems suffer from the drawback that the plants placed at the inlet obtain the best growing conditions and the plants placed at the outlet obtain poor conditions, inter alia because the oxygen content decreases during the passage of the nutrient solution through the trough, and because optimum composition of the nutrient solution is only present at the inlet. Moreover, in such systems it is difficult to ensure that all roots are immersed in the nutrient solution. In some systems, a dispensing of nutrient liquid is distributed along the length of the channel or trough. Root secretions, so-called root exudates, from the first plants in the flow direction will be directed to the plants further down the flow direction. Root exudation is a general term for root exudates including vitamins, minerals, salts, hormones, by-products from photosynthesis in the leaves, etc. Root exudations provide growth conditions for microorganisms and pathogenic agents and organisms etc. and therefore they must be removed continuously.

ADVANTAGES OF THE INVENTION

With the growth system according to the invention, a uniform growth is obtained if the system is formed as defined in claim 1. With this configuration, all plants have equal growth conditions as they all receive a fresh and consequently optimal nutrient solution, regardless of their position in the channel or trough. An even distribution of the solution is obtained in order to provide the roots of the plant with an equal amount of moisture and thus they are likewise supplied with water, oxygen and nutrients to ensure optimal use of the growth system. The evenly distributed flow of liquid across the roots at each growth medium block, where the fresh nutrient solution containing water, oxygen and nutrients is poured over the roots, which are thus continuously moistened, ensures that all root bleeds are quickly removed and via the drainage groove are transported through the return fluid to the purification and regeneration plant and are only conveyed to the next plant to a very small extent. Moreover, the design according to the invention implies that no stagnant liquid is present in the trough or the channel, which stagnant liquid can poison plants that have roots immersed in stagnant food liquid.

When the growth system according to the invention is formed as defined in the characterizing part of claim 2, not only an even distribution of the nutrient liquid is obtained, but also the property that the roots of the plants are placed at a distance from the trough or channel support stop any entry of cold from a cold support.

By forming the growth system according to the invention as defined in the characterizing part of claim 3, an effective discharge is obtained, which has a uniform action independent of the fact that the trough or channel is not placed in a sufficiently horizontal position in the transverse direction .

By forming the growth system according to the invention as defined in the characterizing part of claim 4, an optimal and uniform distribution of the nutrient solution is obtained.

By forming the growth system according to the invention as defined in the characterizing part of claim 5, a distribution of the nutrient solution is obtained in a simple, but quite effective manner without the use of other dispersant and then a pair of longitudinal ribs, which simultaneously contribute to ensuring that the plants are appropriately placed in the growth system.

The growing system according to the invention is preferably developed for use in connection with growing up plants where each plant is placed in an independent small block of inorganic growth medium, for example a block of rock wool or the like, or where each plant is placed in a pot or similar container with inorganic growth medium. If inorganic growth medium square blocks are used, they are arranged in the manner defined in claim 6 or 7. The placement depends, among other things, on the plant concerned. This arrangement of the growth system implies that a safe and effective removal of the nutrient solution and the root secretions is obtained regardless of the type of crop grown in the system and avoiding activity of anaerobic bacteria in the root zone. If the defined shaping is used, it is possible to provide air and fresh nutrient solution at the bottom of the growing medium block and this provides the possibility of increased oxygen intake and reduced unwanted bacteriological activity in the root zone.

By forming the growth system according to the invention as defined in the characterizing part of claim 8, an optimal distribution of the nutrient solution is obtained during the growth of the plants and during the establishment and development of the roots.

Claims 9 and 10 define further favorable embodiments of the growth system according to the invention by which configurations the distribution of the nutrient solution can be further improved and made more uniform and by which a growth system is obtained, which system can be produced effectively and thus also in a competitive manner in terms of price without affecting the quality in terms of the characteristic features of the system.

THE DRAWING

The invention will be explained below with reference to the drawings, in which

Figure 1 is a cross-sectional view of the growth system of the invention with the cover partially broken away to reveal the interior of the growth system,

Figure 2 is a planar sectional view taken along line II-II of Figure 1,

Figure 3 is a sectional view similar to that of Figure 2, however, in conjunction with another application of the growth system, and

Figure 4 is a flat cross-sectional view, similar to that of Figures 2 and 3, however in an improved embodiment.

DESCRIPTION OF THE IMPLEMENTATION EXAMPLES

Figure 1 shows a part of an elongated growth trough or growth channel 1 with cover 2. A plant growth system comprises a number, usually a large number, of such growth troughs, in which the plants are continuously supplied with a nutrient solution and in which excess food solution is continuously discharged by means of the discharge grooves 3 and the discharge pipe 12.

The nutrient solution circulates and is treated in a known manner in a cleaning installation, where the nutrient solution is regenerated in oxygen content, pH, and food content, and where root bleeds are removed to ensure that the growth troughs are always provided with a fresh optimal nutrient solution.

The growth troughs are placed on a support 13 in such a way that a slight downward slope of the size 0.4-2% is achieved. The downward slope is indicated by the arrow 16 towards the discharge pipe 12, for example a downward slope of 0.4%. The growing troughs are often from 6 to 12 m long.

Each growth trough 1 is usually made of plastic by molding or extrusion, so that the trough 1 is produced in great lengths which, as required, are cut and equipped with suitable end pieces. The growing trough comprises a platform 4, which has been moved slightly upwards above the support 13, so that all cold from the support 13 cannot be led directly to the roots of the plants. By means of the platform 4 it is possible to place heating pipes or the like in channels or areas 17 in order to obtain a thermal improvement of the growing conditions. A pipe 7 is arranged in the center of the platform 4, for example in the form of an integral pipe, as shown in the drawing, but of course an independent pipe can equally well be arranged. The pipe 7 is provided for the supply of nutrient solution. The nutrient solution is passed from the pipe 7 through holes or supply pipes 8, for example as shown by an upper cover, so that the liquid is appropriately distributed during the supply. At each side the platform 4 comprises a longitudinal rib 9, so that a longitudinal area for the distribution of the nutrient solution appears on top of the platform. The ribs 9 are relatively low, so that excess nutrient solution is able to leave the region between the ribs, either by flowing over the ribs or leaving the region at either end. Excess nutrient solution will be passed to the drain pipe 12 through the drain grooves 3 on each side. The feed pipes are as high as possible with respect to the cover 2, so that the fresh nutrient solution is always sprayed or guided on the roots, even if a relatively compact root mat has been established. Each plant 10, i.e. supply pipe 8, is supplied with liquid on the order of 4-10 liters per hour.

Growing medium blocks 5 are placed in the area between the ribs 9, for example mineral wool blocks, one block for each plant 10.

Figure 2, which is a cross-sectional view of Figure 1, shows how a growth medium block 5, for example a rectangular growth block, is placed and arranged under an opening 6 in the cover for each growth medium block. Figure 2 shows how the growth medium block 5 is placed between the ribs 9. The figure shows that the block is slightly smaller than the distance between the ribs, so that the nutrient solution can move easily and is evenly distributed. There is nothing to prevent the block 5 from filling in the area between the ribs. After a short growth period, the roots 14 grow through the block 5, as shown in the drawing.

Figure 3 shows a cross-sectional view, similar to that of figure 2, but in figure 3 the growth block is rotated approximately 90 ° relative to its position in figure 2, the growth block resting on the ribs 9. An area or space appears below the growth medium block, which contributes to increasing the possibility of the supply of oxygen and air to the root zone of the plant 10. Root exudations from roots 15 under the growth block 5 * can now also be removed. The growth block is turned to position 5 if the root mat starts to form outside the block.

Although water distribution ribs 9 are provided in Figures 2 and 3 to raise the growth block above the surface of the platform 4 ', it is of course possible to use other types of spacers, for example plastic objects, which are placed under the blocks and shaped in such a way that the flow of the nutrient liquid is still undisturbed and space is provided for the roots.

Although the invention has been set forth in connection with plants growing in a growth medium block 5, there is nothing to prevent the use of other types of plant holders, pots or the like.

Figure 4 shows a planar sectional view, similar to that of Figures 2 and 3, however in an improved embodiment, where two sets of longitudinal ribs 9 and 9 'are provided. The inner set of ribs 9 is higher than the outer set of ribs 9 according to Figure 4. This provides the possibility of an even more accurate and even distribution of water. For example, it is possible to adjust the distance between the ribs and the heights of the ribs in such a way that the longitudinal vessel created between the inner pair of ribs 9 can contain the same liquid as the two longitudinal ones. barrels on each side between ribs 9 and 9 * together. If, in addition to this, the tap grooves 3 on each side are dimensioned to such an extent that they have sufficient space to drain the nutrient liquid, even if the root mat is well developed, it is possible to have an optimal distribution of water and a rapid change of water even with a slight downward slope of the trough or channel.

The current application shows how a feed pipe 8 for the nutrient solution is arranged downstream behind each growth medium block 5, which feed pipe waters the roots of the respective block as well as part of the root mat of the subsequent block in the flow direction, since a number of tests have proven that the best possible distribution of the nutrient solution over the root mat is achieved in this way. In addition to this, the water distribution ribs 9, 9 improve the distribution of the nutrient solution. However, in order to secure the first block of the row, an additional feed pipe 8 is provided in the flow direction for the first growth medium block, so that this block is watered from both sides.

Claims (10)

1. Growing system for plants (10) in growing medium blocks (5, 5 *), which are placed in long channels or troughs (1) with a small downward slope (16), which are provided with a nutrient solution and where the channel or the trough comprises means (3, 12) for discharging excess nutrient solution, the system comprising means (7, 8) for supplying and distributing fresh nutrient solution in a number of locations distributed along the length of the channel or trough, characterized - that the water supply means (7, 8) are interposed between the growth medium blocks and downstream, preferably behind each growth medium block (5), - that the water supply means comprise substantially vertical pipes with outflow above or at the top of the root mat, which is formed in conjunction with the growth of the plant, and - that there are means (9, 9 ') for even distribution of the nutrient solution to the roots of all the plants in the cana al or the trough. Growth system according to claim 1, characterized in that the growth medium blocks (5) are placed on a longitudinally extending platform (4) in the channel or trough (1), which platform also includes the means (8) for water supply as well as the means (9, 9 ') for water distribution. Growth system according to claim 1 or 2, characterized in that a longitudinal groove (3) is provided on each side of the platform in connection with a discharge pipe (12), and in that the channel or trough (1) is arranged with a downward slope (16) to the discharge pipe for the nutrient solution used, preferably a downward slope of 0.4-2%. Growth system according to any one of the preceding claims 1-3, characterized in that the platform (4) comprises a nutrient solution pipe (7) as well as a number of feed pipes (8) distributed along the length of the channel or trough. Growth system according to any of the preceding claims 1-3, characterized in that the water distribution means consist of at least one longitudinal rib (9, 9 ') on each side of the platform (4) and placed on the platform. Growth system according to any of the preceding claims 1-5, characterized in that it further comprises means for placing each growth medium block (5) a little above the platform (4) in the channel or trough (1) in which they are moved up. Growth system according to claim 6, characterized in that the means for raising each growth medium block (5) are constituted by the means (9, 9 ") for water distribution. Growth system according to claim 5, characterized in that the longitudinal ribs are not all of the same height above the platform (4). Growth system according to any of the preceding claims 1-8, characterized in that each plant is placed in its block of growing medium (5) and that each block is of such size and arrangement that it rests on the water distribution ribs (9). Growth system according to any of claims 1-9, characterized in that the platform (4) has a substantially flat surface covering at least one longitudinal cavity (17), preferably a longitudinal cavity on each side of the pipe (7) for the supply of fresh nutrient solution.