NL9401378A - Device and method for cultivating a plant, and cultivation system - Google Patents

Abstract

Device for cultivating a plant. In order to make optimum use of a greenhouse, and to optimally exploit excess irrigation liquid from a plant, it is proposed to cultivate plants at different levels. At a first, high level, a plant is cultivated from which excess liquid can be transferred to a second plant located at a lower level. In this case, the plant at the highest level will generally reach the largest size when growing.

Description

Device and method for the cultivation of a crop as well as a cultivation system

The present invention relates to a plant for growing a crop.

In the prior art all kinds of constructions are known, consisting of plate-shaped parts, which are placed on the bottom of a greenhouse. Culture blocks are placed on it, for example.

In pepper cultivation, for example, adjacent rows are washed from the bottom of a greenhouse in cultivation blocks (substrates) to a considerable height.

Water is used for irrigation to which all kinds of substances have been added. Due to the possible germs present in it, the excess water released must not be used for the same crop. This means that excess water is drained, cleaned and possibly disinfected.

It is necessary to work with excess water to avoid accumulation of salt.

The object of the present invention is to use the space in greenhouses more effectively. As a result, heating costs and other costs per product can be reduced.

This object is achieved in a plant for growing crops in that it comprises at least a first elongated receptacle for receiving a first series of plants and an adjacent second elongated receptacle for receiving a second series of plants, wherein in use condition an essential height difference exists between the first and second uptake and wherein discharge means are present to direct liquid, such as water, from the first uptake into the second uptake.

The invention is based on the insight that the surplus water is supplied to another crop, which is less susceptible to diseases that may arise from the supply of excess water from the first crop. For example, the irrigation water is used more efficiently.

In addition, a particularly large number of crops can be grown in a relatively small space. This makes optimal use of the cash volume.

Because the first recording is higher than the second recording, it is possible in a particularly simple manner to place a climate treatment device, such as a hose, through which fluid flows when the device according to the inventor is placed under the first recording. The temperature of the roots of crops can be particularly important for crop development. For this reason, it has been proposed in the prior art to place hoses in the bottom and then, after inserting, for example, a sheet of foil, to heat culture blocks placed on the bottom. However, it has been found that the efficiency of heating in this manner is very low. On the other hand, the temperature of the crop is of the utmost importance. By controlling the root temperature, it is possible to keep the leaf temperature of the crop optimal. No carbon dioxide uptake takes place below 18 ° C, while above 25 ° C the first sealing takes place in the blades, as a result of which a reduced CO2 yield takes place.

With the aid of the hose described above, both cooling and heating are very efficiently possible. In summer, a temperature of, for example, about 30 ° C is maintained in greenhouses, it being important that the roots are colder than 24 ° C.

With the climate control described above, both vegetative and generative growth can be controlled.

By providing the crops present in the second shot with the excess water from crops from the first shot, this water is allowed to evaporate. In addition, these second crops make a further contribution to the atmosphere, thereby promoting the growth of the first crops. The space in the greenhouse is also optimally used.

Although it is possible to apply only a second accommodation to each elevated part, optimum use of space is obtained if such a second accommodation is provided on both sides.

It has been found that potted plants in particular are not very sensitive to possible germs in water from growing crops, such as peppers, aubergines and tomatoes. Therefore, potted plants are preferably placed in the second shots. This also ensures easy supply and removal from these second recordings. The second pictures are preferably gutter-shaped to contain the water. This water can be permanently present in a layer. Transport systems can optionally be present to move the crop from the first and / or the second shootings at the time of harvesting or other treatment. The crop in the second shot contributes to the Climate, such as humidity, in the Greenhouse. The first admission is arranged for the inclusion of KweeKbloKKen. These are planters with a substrate with a length of about 1 meter and filled with rock wool. These first shots are provided with a drain to direct water to the second shot.

As indicated above, in the first shot, preferably a crop is grown that grows high, such as peppers and tomatoes. A space of relatively small height is then created between adjacent rows of first pictures for accommodating, for example, potted plants placed in the second pictures. In this way, the space in the Greenhouse is optimally filled.

The invention also relates to a high growing crop culture system, such as peppers and tomatoes, comprising spaced rows of crops, the crops being V-shaped in at least two upward directions from the growing medium and the end point of one crop row extending in a first direction coincides with the end point of the adjacent row extending in the second direction. In the prior art, two rows of bahhen crop were placed side by side.

In connection with the accessibility of the first crop and the optimum discharge of the excess water to the second crop, according to the invention it is preferable to use only one row of bahhen. However, the efficiency of the filling of the space above the containers with the high-growing crop is considerably limited.

This drawback is eliminated in that a suspension system is provided to provide a crop string which extends in a third direction between the first and second directions. With a single row of bins and the use of a third wire, it is possible to grow more crop per unit length. This is especially true for a single row of bins. Thereby, as indicated above, it is possible to cultivate in the space bounded between the V-shaped upwardly extending crops of adjacent rows of crops in the first shoots and washed in the second shoots.

The third direction described above is substantially vertical.

The invention will be explained in more detail below with reference to an illustrative embodiment shown in the drawing. Show:

Fig. 1 is a perspective view, in section, near the bottom of a greenhouse through a device according to the invention; and Fig. 2 schematically shows the arrangement of the different crops in a greenhouse.

In Fig. I, 1 indicates a gutter profile. This consists of a raised part 2 or first picture and a lower part 3 or second picture. The second recording 3 is bounded laterally by raised edges 4.

In the first recording 2, cultivation blocks 9 are placed in, for example, peppers 5 which are cultivated in a single row. In second shots 3 pot plants 6 are present. A supply tube 14 provides the supply of fluid for irrigating first crop 5. This takes place via a supply hose 13 at the end of which means known in the prior art for dosing, such as drippers, are present. It is necessary to provide an excess of moisture in the culture block 9 to prevent salinization of the soil. The excess is discharged via openings 15 and flows via wall 7 of gutter profile 1 in second shot 3. There, a pond is maintained artificially, so that potted plants 6 can always absorb moisture.

Within the space bounded between the raised part that forms the first accommodation 2 and the bottom 17 of the greenhouse, a space or opening 12 is present, within which a hose 8 is laid. This hose can be designed in such a way that it serves as cooling in the summer and heating in the winter. This is to optimize the root temperature of the crop contained in the cultivation box 19. It can be seen from Fig. 1 that a series of cultivation trays are arranged one behind the other.

Adjacent to the gutter profile there are tubes 16, which on the one hand can be arranged for transporting a medium carrying heat or cold and on the other hand are designed for carrying trolleys necessary for work in the greenhouse.

The greenhouse in question is schematically shown in Fig. 2. From this it appears that from the first crop 5 arranged in cultivation tray 9 tension wires 10 extend to suspensions 11. Contrary to the prior art, three tension wires 10 extend from a cultivation box 9, one of which is approximately vertical. Therefore, it is possible to realize a planting density that approximates the planting density in a cultivation in which two series of boxes are arranged side by side with a single series of cultivation boxes on the first recording 2. In contrast to such constructions, the crop is particularly easy to reach in this embodiment. In the space bounded between the tension wires 10 and the attached crop of adjacent first crops 5 of adjacent cultivation blocks 9, there is space for the growth of pot plants 6 and passage for reaching the plants. In this way, the space of the greenhouse is optimally utilized while there is still enough space for peppers or tomatoes to develop in such a way that a maximum yield is obtained.

Testing the cultivation method described above has shown that it is possible to cultivate approximately 100,000 pot plants per hectare without much effort. Hardly any additional costs are necessary for this, while the climate in the greenhouse is significantly improved. Growing a crop in a pot plant twice a year is one of the possibilities.

It will be clear that this will intensify and improve the use of a greenhouse.

It should be understood that the invention has been described above with reference to a preferred embodiment.

For example, it is possible to place pot plants in the first shot instead of growing blocks. It is also possible to apply culture blocks in the second exposure and it is even possible that the crop will have the largest final dimensions from the second exposure.

In addition, it is to be understood that the device according to the invention, and more particularly the trough-shaped parts thereof, can be designed in any manner known in the art. It is thus possible, if it is desired not to leave the potted plants constantly in the water, to make the boundaries of the gutter, such as near wall 7, somewhat deepened, with a support surface for the potted plants or breeding blocks in between. The water can then stand in this floor without it being in direct contact with the soil of the crop concerned.

These and related embodiments are considered to be within the scope of the present application as set forth in the claims.

Claims (13)

The device of claim 1, wherein the first receptacle comprises a raised portion which defines an elongated opening (12) in the operative condition with the bottom for receiving air conditioners. Device according to claim 2, wherein a hose (8) is arranged in the elongated opening, through which a temperature-influencing fluid is passed. Device as claimed in any of the foregoing claims, wherein second elongated receptacles are arranged on either side of the first elongated receptacle. The device according to any of the preceding claims, wherein the first recording is adapted to receive culture blocks. Device as claimed in any of the foregoing claims, wherein the second recording is adapted for receiving potted plants. Device according to any of the preceding claims, wherein the first intake is adapted to receive high-growing crops, such as peppers and tomatoes. A culture system for high-growing crops, such as peppers and tomatoes, comprising spaced rows of crops, the crops being V-shaped in at least two upward directions from the growing medium and the end point of the one crop row extending in a first direction coincides with the end point of the adjacent row extending in the second direction, characterized in that a suspension system is provided for providing a crop string extending in a third direction lying between the first and second directions . Cultivation system according to claim 8, wherein the third direction is substantially vertical. Cultivation system according to claim 8 or 9, wherein in the space bounded by the crop extending from a point in the first direction and a second adjacent crop extending from a point in the first direction and a second adjacent crop extending in at least one further crop is applied in the second direction. Cultivation system according to claim 10, wherein a further crop is arranged in the space on either side of the crop. A method for growing at least two different crops, comprising providing a liquid (such as water) to the first crop, draining excess liquid from the first crop and feeding excess liquid to the second crop. A method according to claim 12, wherein the first and second crops are arranged in the same space. A method according to claim 12 or 13, wherein the first crop is arranged at a higher level than the second crop.