NL1034032C2 - Hydroponic cultivation system for greenhouse plants, e.g. snack cucumbers, comprises open cultivation channels and sea mineral nutrient composition for adding to water - Google Patents

Abstract

The system comprises an open cultivation channel (12), a through-flow system for supplying and discharging water via a water conduit (8) associated with this channel, and a sea mineral nutrient composition for adding to the water. A cultivation system for growing greenhouse plants comprises at least one open cultivation channel which contains plants and includes a water conduit, a through-flow system for supplying and discharging water via this conduit, and a nutrient composition at least partially comprising sea minerals and added to the water continuously and/or periodically. Independent claims are also included for the following: (1) Nutrient composition used in this system; and (2) Method for cultivating plants using this system, comprising measuring the level of nutrients present in at least one cultivation channel, determining the desired level of nutrients and/or the desired nutrient addition times, and adding the determined amount of nutrients at the desired times.

Description

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Cultivation system, composition and method for growing crops In (glass) horticulture 5

The present invention relates to a cultivation system for growing crops without the use of soil, such as is carried out in (glass) horticulture. The device is suitable for growing all crops, in particular for crops grown on wire, such as cucumbers and tomatoes, and more particularly the small cucumbers (so-called "snack cucumbers").

Cultivation systems are known which use a trough in which the crops are placed and in which a substrate is used instead of soil. By using gutters with substrate material, the water, with any fertilizers dissolved therein, is preferably used in a recirculating system. The fertilizers, or nutrients, therefore do not end up in the surface water. A disadvantage of such systems is that a substrate is required through which nutrients are passed for absorption by the plant. The gutters with substrate material can become contaminated and contain, among other things, germs. This can be harmful to the crop. In addition, the substrate material functions as a kind of filter and / or buffer, so that it cannot be guaranteed that all nutrients will reach the right plant in the right amount at the right time. It can also hinder the development of a sufficiently thick root package of the plant. In addition, the costs of using substrate material form a non-negligible part of the total cultivation costs. In addition, the use of such mats, including drainage with possibly 1034032 t 2, still impacts the nutrients present in the substrate on the environment. One of the problems occurring with the use of substrate material is that the nutrients do not reach the plant roots to a sufficient extent and are not sufficiently absorbed by the plant. The plant is also not sufficiently stimulated to produce sufficient root mass. In addition, there is currently an increasing need to distinguish for products obtained from cultivation on the basis of things such as taste, ingredients, shelf life and the like. Sustainability is also an increasingly important point of interest in horticulture, and greenhouse horticulture in particular.

The present invention has for its object to provide an improved device, system and method for growing crops, in particular crops grown on wire, such as cucumbers and tomatoes, in order to improve the cultivation process, in particular in greenhouse horticulture.

The present invention provides a cultivation system for growing horticultural crops, comprising: at least one open cultivation gutter with plants therein of a crop to be grown, the open cultivation gutter provided with a water channel; - a flow-through system for supplying and discharging water through the water channel; and - a composition of nutrients that is continuously and / or periodically added to the water, at least comprising a part of sea minerals.

By making use of a system of (open) troughs, that is preferably without substrate material, nutrients can be spread over the plants of the crop in a relatively limited amount of water. Such an alternative to the use of substrates is the cultivation in "open" gutters according to the "nutrient film technique" 3 (NFT). For this purpose, the cultivation gutter is provided with a water channel in which no substrate material, or other solid material, is provided. This ensures that the root package of the crop is stimulated in, among other things, growth, so that a thicker root package can be obtained. Thanks to such a more open system, nutrients added to the water can be better absorbed by the plant. This requires a good flow-through system for the flow of water with any nutrients. An additional advantage is that, if desired, separate drippers can be dispensed with for adding nutrients to the plant. Nutrients fulfill relevant functions in the biochemical substance balance of a plant, such as catalyst activity and for enzymes and vitamins, for example. A lack of these elements can negatively influence the quality, growth and yield of the plant. Nutrients are provided by adding a composition to the water including a mix of nutrients, such as minerals. The composition consists of a mixture of fertilizers of both inorganic and / or organic origin in combination with a trace element mixture. Such trace elements include components such as iron, zinc, copper, molybdenum, boron and cobalt. By combining these components in the composition according to the present invention, a balanced plant nutrition can be administered. By administering the balanced diet, it can be achieved that the absorption of water by the plant is further restricted. This is realized because the plant is previously saturated by taking in the desired nutrients in the right amount. This limits the use of water, as well as any associated water treatments and use of energy. This ensures that the plants can be grown in an open gutter, via the NFT principle. The administration of the nutrients can be continuous or pulsed. The flow-through system provides a substantially constant, or at least periodic, flow of water with the nutrients administered through the gutter. Due to the water flow, problems with regard to disease and possibly ineffective water roots can be avoided. This is achieved because there is a more or less constant movement of the water with a sufficient intake of oxygen therein. The troughs here preferably have a limited length in the range of 2-20 meters and most preferably in the range 10 of 10-14 meters. The slope used at the gutters is preferably in the range of 1-5% and more preferably in the range of 2-3%. This ensures that a relatively thin layer of water, or the water film, flows through the gutter with sufficient speed. Use is preferably made of a circulating flow-through system with which the water is transported through the gutters to, for example, a collecting basin. From this collecting basin, this water is reused, possibly provided with further nutrients and / or oxygen, and again passed through the gutters. The cycle time of pumping the water is preferably in the order of magnitude of, for example, 1-15 minutes. The circulation system transports the water, with any nutrients and / or oxygen, to the highest point of the gutters, after which the water will flow through these gutters due to gravity. The water is drained further at the ends of the gutters and flows back to the basin. In an advantageous embodiment, only one pump is needed here and the rest of the flow can take place as a result of gravity. An additional advantage of the use of gutters according to the present invention is that by refraining from substrate material, the, possibly even relatively large, root mass can after the harvest possibly be used for, among other things, animal feed or as biomass, for example for energy extraction. . This contributes to a more sustainable production in greenhouse horticulture.

In addition, this avoids costs related to the disposal of the organic material. Also, the substrate mats do not have to be replaced when the cultivation is changed. This leads to simple and more efficient business operations. If substrate material is dispensed with, the troughs are also easier to disinfect, such as, for example, against cucumber union virus, Pythium, Fusarium.

In an advantageous preferred embodiment according to the invention, the composition comprises a part of sea minerals in the range of 0.1-10% by weight.

The composition is provided with a desired amount of nutrients by the sea minerals. For crops grown on wire, the composition preferably includes the stated components:

Components Order Size 15 Chlorine, Sodium O (104ppm)

Magnesium O (103ppm)

Sulfur, Calcium, Potassium O (102 ppm)

Bromine, Carbon 0 (101 ppm)

Oxygen, Strontium, Boron, 0 (10 ° ppm) Silicon, Fluorine

Nitrogen, Argon, Lithium, 0 (10-1 ppm)

Rubidium

Phosphorus, Jew, Barium, Indium, 0 (10-2 ppm)

Aluminum, Iron, Zinc, Molybdenum

Selenium, Copper, Arcenicum, O (10-3 ppm)

Tin, Lead, Uranium, Vanadium,

Manganese, Titanium

Thorium, Cobalt, Nickel, O (10-4 ppm) 30 Gallium, Cesium, Antimony,

Cerium, Yttrium, Neon,

Krypton, Lanthanum, Silver,

Bismuth, Cadmium 6

Tungsten, Germanium, Xenon, 0 (10-5 ppm)

Chromium, Berylium, Scandium,

Mercury, Niobium, Thallium

Helium, Gold O (10-6 ppm) 5 Praseodymium, Gadolinium, 0 (10-1 ppm)

Dysprosium, Erbium,

Ytterbium, Samarium

Holmium, Europium, Thulium, 0 (10-8 ppm)

Lutetium, 10 Radium, Protactinium, Radon <0 (10-9 ppm)

Other components are preferably Indium, Hydrogen, Zirconium, Technetium, Ruthenium, Rhodium, Palladium,

Tellurium, Neodymium, Promethium, Terbium, Hafnium, Tantalum, Rhenium, Osmium, Iridium, Platinum, Polonium, Astate, Francium, Actinium, Neptunium, Plutonium and Americium.

Only eight minerals are generally used in the known nutrients. In the case of, for example, a tomato as a crop, however, more minerals, about 56, are desired. By using a composition according to the present invention, in which the nutrients, such as minerals, are included, the plant will need to absorb less water in order to meet the nutrient needs. This will not only limit the absorption of water, but also the evaporation of water from the plant can remain limited. This will then lead to a lower use of water including any required water treatments. This will contribute to a more sustainable and environmentally friendly production of, for example, tomatoes. The specific composition as stated in the table can, if desired, be tailored to the respective application. For example, an optimum composition for tomato cultivation may consist of different mutual relationships between the components than for cucumbers, for example. In addition, it is possible to consciously allow or add certain types of bacteria to the circulated water to further stimulate root growth. A further advantage of the present invention 7 is that crop protection can be achieved in a simple manner by, for example, adding a small amount of crop protection agent, such as, for example, Previcur, to the water, so that it can be absorbed by the plant. The system ensures that such a crop protection agent can quickly reach the roots of the crop and therefore less large quantities of crop protection agent are required. This has advantages in the field of, among other things, the sustainability and efficiency of operational management. In addition, limited use of these protective equipment will also benefit general public health.

In an advantageous preferred embodiment according to the invention, the plants of a crop to be grown are cucumber plants and / or tomato plants.

In particular, crops grown on wire, such as cucumbers and tomatoes, are difficult to grow because, among other things, only the fruits of this plant have to be harvested, such as the aforementioned cucumbers and tomatoes. For comparison, in the case of lettuce plants, the entire leaf of the plant can be grown. Such a plant, such as lettuce, can therefore be grown much more often, for example 13 times a year compared to, for example, cucumbers that can be harvested, for example, 4 times a year. By using the cultivation system according to the invention, with the composition and the construction with the cultivation troughs, a relatively fast uptake of the nutrients by the plant via the root mass is achieved. Hereby the root mass can become larger and subsequently a product, such as cucumbers, can be harvested faster. For example, a new product can already be harvested after 10 days. Small cucumbers, or so-called snack cucumbers, are particularly suitable as crops for growing in a cultivation system according to the invention. For example, 35 three plants per m2 are used to achieve sufficient product quality.

8

In an advantageous preferred embodiment according to the present invention, the cultivation system is provided with a support structure that is adjustable both in the longitudinal and transverse direction of the at least one cultivation trough.

The construction is not only adjustable in height, but also in the width direction of the gutter, for example by means of a screw-spindle construction. This ensures that the gutter can also be positioned in the desired direction in the width direction in order to provide the correct amount of water at all desired positions in the gutter 10. The possibility of adjusting the height of the support also ensures that in the longitudinal direction of the gutter no dry places can arise where no water is supplied to the roots of the crop. This is especially relevant due to the absence of substrate material, whereby the sensitivity of the system to dry places is increased, because no suction or sponge effect is obtained due to the absence of the substrate material. A more balanced distribution of the water also results in a more even distribution of, for example, the nutrients and / or oxygen over the gutter. In an advantageous embodiment, the gutters are hereby supported by means of a supporting leg construction. Preferably, a kind of U-shaped profile is made that is supported by preferably two legs that are adjustable in height. In principle, any number of legs is possible. In the case of two supporting legs, it is possible not only to adjust the channel to the correct height in the longitudinal direction of the channel, but also to the width of the channel. The preferably U-shaped profile for supporting the gutters hereby encloses the gutter, so that it cannot move in the width direction of the gutter. Of course, other constructions for holding the gutter on the supports are also possible. In an alternative preferred embodiment, the gutters are suspended. Hanging the gutters has the advantage that the floor surface under the gutters remains free. This has advantages in terms of cleaning, among other things. This also makes it easier to adjust the entire height adjustment of the gutters to, for example, the wishes of the user. The construction is not only adjustable in height, but also in the width direction of the gutter. This ensures that the gutter can also be suspended in width direction in the desired manner to provide the correct amount of water at all desired positions in the gutter. The hanging construction can for instance be provided with steel cables.

In a further preferred embodiment according to the present invention, the system is provided with a flow meter.

By measuring the amount of water, and optionally the concentrations of certain substances therein, the amount of water and / or the desired substances therein can optionally be controlled. An operating system is used for this purpose. This control system can, among other things, control the pump speed. Preferably, the control unit or control system also controls the dosage of the additional nutrients. A sensor is used for measuring a quantity of nutrient (s). An additional advantage of using a device with a monitored flow according to the invention is that by using a small amount of water the system can be emptied relatively easily, quickly and possibly at low costs in order to switch to another crop and / or a different feeding pattern, etc. By using a small amount of water in combination with the open system, a faster uptake of the nutrients by the crop is achieved. This will in particular promote root growth and then preferably lead to a larger root-leaf ratio. The limited use of water, and any nutrients and / or pesticides therein, also contributes to a more sustainable production in greenhouse horticulture.

10

In an advantageous preferred embodiment according to the present invention, a storage basin is placed higher than the at least one cultivation gutter.

By placing a storage basin or basin at height, the return water is brought to the higher height by means of a pump to the basin. The potential energy added to the water in this way can be used by the system to provide the entire system with sufficient water and any nutrients, for example in the event of a power failure. This has the additional advantage that it is possible to dispense with additional pumps and aggregates to cope with such calamities.

The invention further relates to a composition for use in a cultivation system mentioned above and / or a method therefor. These offer the same effects and benefits as those mentioned in the cultivation system.

Further advantages, features and details of the invention are elucidated on the basis of a preferred embodiment, wherein reference is made to the appended drawing, in which: figure 1 shows a schematic overview of the system according to the present invention; Figure 2 shows a side view of a gutter construction from figure 1; figures 3A and 3B show a view of a supporting construction of the gutter of figure 2; figure 4 shows a perspective view of a suspension 30 of a gutter construction from figure 1; and - Figure 5 shows an overview of a cultivation gutter with separate channels.

A system 2 (Figure 1) for growing crops, such as cucumbers, comprises a storage basin 4 for the water 35 that is transported by means of a pump 6 through supply lines 8 to the access points 10 of the troughs 12. System 2 can be used in horticultural greenhouses, wherein several troughs 12 are provided over 11 the entire surface of the greenhouse. By designing the supply points 10 such that a substantially equal pressure prevails over the entire supply line 8, a uniform flow of water through the 5 channels can be realized. By placing the gutters under a slope, in the embodiment shown, the water will flow to drain line 14. In drain line 14, a filter device 16 is placed for purifying the water. The return flow 14 returns the water back to basin 10. 4. Basin 4 can be filled or refilled by supply line 18 when opening valve 20. An amount of nutrient or nutrients can be supplied to the water through supply line 22 and supply system 24 to the supply line 8.

If desired, pesticides can be supplied via the same or a similar system. The supply of nutrients through device 24 is controlled by control unit 26. The control unit is further operatively coupled to pump 6 and to the valve 20. Herewith the process 2 can be controlled by control unit 26. By means of sensors 28, among other things, the amount of water and the amount of nutrients present therein are measured and passed on to the control unit 26. For this purpose, the sensors 28 are coupled via connections 30 to control unit 26. This control unit 26 is connected via connections 32 to pump 6, device 24 and valve 20 for controlling thereof.

The system 2 is placed in a horticultural greenhouse with an area of 3300 m2 and has a total water volume of 8 30 m3. The length of the gutters 12 in which the cucumber plants are placed, in a density of 3 plants per 1 m2, is around 12 m. The corresponding slope for the flow of water in the gutters is approximately 0.3 m. This is due to corresponds to 4.5%. In system 2, the water displaced by pump 6 is returned to basin 4 within 2-3 minutes. The flow rate of the culture water through the gutter 12 is approximately 0.5 1 / minute per gutter. In the system only 6-10 m3, and 12 preferably 8 m3 of water is needed in the entire system. The system can save 10-15% on water and fertilizers.

The gutters 12 (Figure 2) are supported by legs 40. The legs 40 provide sufficient support for the gutters 12 with the plants placed therein and water flowing through with added substances.

In the embodiment shown, the legs 40 (Figure 3A) are provided with two uprights 42. From the uprights 42, an arm 44 can be adjusted to height. The arms 44 support carrier 46. Gutter 12 is supported by carrier 46. On the side of carrier 46 there are 2 auxiliary posts 48. Gutter 12 can be clamped between uprights 48. The width of carrier 46 and auxiliary supports 48 can be adjusted to the type of gutter that is used. The two arms 44 of the two legs 42 are individually height-adjustable. The uprights 42 rest on a base or bottom plate 50 and are inserted into the further base by means of pins 52 (Figure 3B).

If desired, the troughs 12 can also be suspended by means of a suspension system 60 (figure 4). The suspension system 60 consists of a steel cable 62 suspended from a support cable 64 which is tensioned between 2 uprights 66. The uprights 66 support the roof construction 68 of the greenhouse. The steel cable 62 diverges at the lower end into four connecting cables 70. These connecting cables 70 hold trough 12 in a number of places. If desired, the troughs 12 can also be placed in a direction parallel to the carriers 68, for instance in order to optimize the amount of sunlight for the plant and / or to limit the nuisance of uprights 66. The overall height adjustment of the gutters 12 can be influenced by adjusting member 72. The individual connecting cables 70 can be adjusted in length by adjusting members 74. The desired position of gutter 12 can be achieved by means of the various adjustments.

13

In an alternative preferred embodiment, the gutter is provided in another form 76, in which the plant is supplied on one side with gutter 76, via supply channel 78, with supply of water plus nutrients, and on the other side, via discharge channel 80, if desired can dispose of substances. For this purpose, trough 12 consists of two flow channels 78, 80. In a possible embodiment, the supply channel 78 could be placed substantially horizontally and the discharge channel 80 could be slightly sloping to achieve a desired flow. The channels 78, 80 are separated by a dyke 82 on which the plants 84 are placed. Hereby the root mass of the plant 84 is distributed over the supply channel 78 and the discharge channel 80.

The root package is therefore split into a supply part 86 and a discharge part 88 ("split-root method"). This could possibly extend the life of the plant.

The present invention is by no means limited to the preferred embodiments described above. The rights sought are defined by the following claims, within the scope of which many modifications are conceivable. For example, it is possible to provide the basin 4 from two separate basins. The second basin can hereby be placed at a higher height than the first basin in order to thereby add potential energy to the water. By providing this additional pump and associated additional flow, more oxygen can also be absorbed into the water. It is also possible, for example, to combine the system with a ventilation system that ensures such a pressure in the climate of the greenhouse that heat and CO2 can rise less rapidly from the gutters. As a result, cultivation could suffice with less energy. In addition to the so-called wire-grown crops, such as cucumbers and tomatoes, it is also possible to use system 2 in floriculture, such as for example for gerberas. Optionally, it is possible to choose the temperature of the water somewhat higher than the temperature of the environment, for example 22 ° C for the water 14 and 18 ° C for the environment. This allows energy costs to be reduced. Furthermore, it is possible to provide the system with an ozone disinfectant. This allows a better purified water to be achieved in the process. Alternatively, membrane filtration or, for example, chlorine additives are possible. These methods can also be applied in combination. It is also possible to carry out a measurement, for example of the amount of nutrients, per gutter 12. This also makes it possible to control the flow of water per gutter. It is also possible to control the supply of nutrients per gutter or group of gutters separately by providing a separate supply of these substances.

1034032

Claims (12)

A cultivation system for growing horticultural crops, comprising: 5. at least one open cultivation gutter with plants therein of a crop to be grown, the open cultivation gutter provided with a water channel; - a flow-through system for supplying and discharging water through the water channel; and 10. a nutrient composition that is continuously and / or periodically added to the water, at least comprising a portion of sea minerals. Cultivation system according to claim 1, wherein the part of 15 sea minerals is in the range of 0.1 to 10% by weight. 3. Cultivation system according to claim 1 or 2, wherein the plants of a crop to be grown are cucumber plants and / or tomato plants. 4. Cultivation system according to claim 1, 2 or 3, wherein the at least one cultivation gutter is provided with a support structure that is adjustable both in the longitudinal and transverse direction of the cultivation gutters. 5. Cultivation system as claimed in claim 4, wherein the adjustable supporting structure comprises at least one height-adjustable upright. 30 The cultivation system of claim 4, wherein the adjustable support structure comprises at least one height-adjustable suspension. 7. Cultivation system according to one or more of claims 1-6, wherein the cultivation system is provided with a flow meter. f034032 8. Cultivation system according to one or more of claims 1-7, wherein the cultivation system is provided with a sensor for measuring an amount of nutrient (s). 9. Cultivation system according to one or more of claims 1-8, wherein the cultivation system comprises a storage basin that is placed higher than the at least one cultivation gutter. 10. Cultivation system according to one or more of the claims ΙΟ-ΙΟ 9, wherein the at least one cultivation gutter is provided with a separate supply channel and separate discharge channel. Composition for use in a cultivation system according to one or more of claims 1-10. 15 12. Method for growing crops in a cultivation system according to one or more of the claims 1-10, comprising the steps of: - measuring nutrients in at least one cultivation gutter with plants arranged therein of a crop to be grown, providing the cultivation gutter of a water channel; - determining the desired amounts of nutrients and / or desired times of supply of nutrients for the plants by a composition with nutrients, wherein the composition comprises a part of sea minerals; and - supplying the determined quantities at desired times. f034032