NL2025815B1 - Growing device, growing system and growing method for growing potatoes and/or vegetables - Google Patents

Abstract

The present invention relates to a cultivation device for growing potatoes, comprising at least two mutually connected containers located one above the other with a bottom, at least one side wall extending upwards from the bottom and with an upper edge, designed for receiving seed compost and potato plants. In this case, at least one spacer is provided which connects two containers located one above the other and creates a vertical distance between the top edge of a container and the bottom of a container located directly above it. The invention further relates to a cultivation system and a cultivation method in which such a cultivation device is used.

Description

Brief description: Growing device, growing system and growing method for growing potatoes and/or vegetables Description According to a first aspect, the present invention relates to a growing device for growing potatoes, comprising at least two superimposed, mutually connected containers with a bottom at least one side wall with an upper edge extending upwards from the bottom, adapted to receive seed compost and potato plants. In use, the containers are filled with seed compost and potato plants with potatoes grow in the containers. Such a cultivation device is also suitable for growing vegetable crops. In particular, this document describes an apparatus, system and method for potato cultivation, however, the apparatus, system and method are suitable for vegetable crops, with possible adjustments for specific application, which also falls within the scope of protection claimed by this document. This also applies to mixed cultivation, i.e. the cultivation of different crops in different containers of the same cultivation device.

Potatoes are traditionally grown in an open field. With machines that drive across the field, potatoes are planted and the potatoes grown are harvested. This requires a relatively large area and heavy machinery to work the soil and to plant and harvest the potatoes, which has environmentally polluting aspects. Another disadvantage is that periodically the soil cannot be used for potato cultivation, because of the growth of the number of nematodes during cultivation. That population has to disappear from the ground before potatoes can be grown on it again.

It is also known to grow potatoes in stacked containers with soil. The bins have a tapered horizontal cross section from top to bottom. The bottom of a container is designed to rest on a circumferential edge of an identical container located below, so that the containers can be stacked on top of each other. A lower container rests with the bottom on a surface. This is also known as a floor system.

Because potato plants grow towards the light, (new) potatoes can also develop under the bottom of a higher container, while the potato plant itself only needs a relatively small space near the side wall of the container. By means of such a multi-tier system it is possible to use a multiple of that surface on a particular ground surface, which multiple corresponds to the number of trays stacked on top of each other, for growing potatoes. A drawback of growing potatoes in such a tiered system is that there is nevertheless relatively little space for the plants to grow, so that the yield of the lower tray(s) is lower than that of a tray stacked higher. It has also been found in practice that the potatoes in the middle of a lower container grow less quickly than potatoes closer to the outside of the same container and than potatoes in the middle of a highest container. This results in a relatively ununiform distribution of the size of potatoes grown with the known tier system. The object of the present invention is to provide a growing device for growing potatoes, with which the above-mentioned problems of the known tier system are at least partly solved. This object is achieved in that at least one spacer is provided which connects two containers located one above the other and creates a vertical distance between the top edge of a container and the bottom of a container directly above it. The spacer thus provides space between the seed compost in a lower tray and the bottom of the tray immediately above it. As a result, potatoes, in particular in a central part of the holder, receive (more) light than with the known cultivating device, the yield can be increased and potatoes can grow better in the central part than with the known cultivating device. The spacers can have any desired shape. A relatively small horizontal cross-section is preferred, because relatively little light is thereby blocked. For example, rods, tubes or beams are very suitable. The spacers preferably provide a vertical distance in the range of 10 to 500 cm, further preferably from 12 to 250 cm and still further preferably from 15 to 100 cm, up to 75 cm or up to 50 cm between the top edge of a bearing container and the bottom of a container immediately above it. The mutual distance can be related to the cultivation surface of the trays.

The at least one spacer may be a central spacer extending through a central point of each of the containers. Alternatively, two, three or more spacers can extend between two containers located one above the other, whereby a more stable device can be realized. In the latter case, the spacers may extend vertically or at an angle slightly (for example between 1 and 15 degrees, or between 3 and 10 degrees) from the vertically deviating angle with respect to each other, for example converging when viewed from below.

The containers may have a round or a rectangular, such as square, shape. Round containers are less fragile and thus less susceptible to damage than rectangular or square containers. Rectangular containers are more economical than round ones, e.g. in using a site where they can be placed in their large-scale application. And also in case the cultivation devices have to be stored (temporarily) in a small space, as discussed further in this document.

It is preferred here that the at least one spacer is detachable from at least one of the holders. This provides the option of modularly assembling the cultivating devices or of temporarily disconnecting containers from a cultivation system, for instance to relatively easily process (seed soil in) a container, to be able to change the number of tiers as desired, or to create a container and/or or spacer to be replaced.

The greater the number of containers located one above the other and connected to each other, for instance 3, 4, 5 or more, the greater the total cultivation surface and thus the cultivation capacity per unit soil surface.

In a preferred embodiment, with containers located one above the other, a higher container has a smaller horizontal cross-sectional area than a lower container, at least at corresponding heights of the containers. As a result, sunlight can reach an even larger part of the seed compost in the lower container, which promotes a more uniform size of the potatoes grown with the cultivation device. It is also preferred that the containers have a converging side wall when viewed from top to bottom. In this way, a relatively large surface of seed compost is coupled to a relatively small bottom, which removes light from a container located lower. However, in an alternative embodiment in which at least part of the holders have a corresponding size, this has the advantage that the total cultivation area of the cultivation device is larger than in the converging embodiment. At least seen in relative growing area with respect to a vertical projection of the device, the latter corresponding to the projection surface of the largest container.

A container preferably has a horizontal cross-section with a surface area between 0.1 and 10 m2, further preferably between 0.15 and 5.0 m2. and still further preferably between 0.20 and 2.5m? or between 0.3 and 1.5 m? It is further preferred that the side wall of a container extends upwards at least 10 cm from the bottom. That is to say, the vertical distance between an upper edge of the side wall and the bottom of the container is preferably at least 10 cm. Further preferably said vertical distance is at least 13 cm and still further preferably at least 16 cm. This provides the possibility of receiving sufficient cultivation soil in a container to allow potatoes to grow in the soil.

It is preferred that the cultivating device is provided with at least one pipe connectable to a water supply, which pipe is designed for watering the seed compost in the containers. In this way it is possible, in the case of several cultivating devices, to feed the various cultivating devices with a targeted amount of water. Thus, the need for watering may depend on the position of a cultivator in a plurality of cultivators. In a preferred embodiment, the device is provided with means, such as sensors or flow meters, which register whether the water supply functions as desired, for instance there is no (local) blockage in the water supply. The connectable pipes can comprise pipe parts with a quick coupling. Quick couplings for water pipes are well known and are not explained in more detail here. A supply for manure or other substances which can be transported by means of water in the pipe can be provided on the water pipe.

It is advantageous if the at least one conduit is provided in or on the at least one spacer. When assembling a cultivating device, both a spacer and a pipe are then provided in one operation. Alternatively, the at least one conduit is a self-contained part. This can make the pipe easier to access for maintenance, such as clearing any blockages.

In order to prevent dehydration due to exposure to an excess of direct sunlight or to excessive wetting due to precipitation of gate soil in an (upper) container, or to protect all containers against dehydration or excessive wetting, a sun and or rainwater barriers are provided, preferably in the form of a roof, which may be provided with drainage means for the discharge of excess rainwater or other precipitation. The drainage means can be connected to a water reservoir, so that the water can still be led to the growing devices at a later time. The water reservoir may comprise a filter system for desanding or otherwise filtering the discharged water. The containers themselves are preferably provided with drainage means in order to be able to remove an excess of moisture from the containers. The used water that is collected in the reservoir and still contains usable minerals and fertilizers can later be mixed with clean water, which can then be fed back to the topsoil via the water distributors. When the sunblind comprises a solar panel, a site on which a plurality of devices is provided can also be used for energy production in addition to potato cultivation.

In a preferred embodiment, the cultivating device is mobile, or at least displaceable. That is to say that the cultivation device is provided with displacing elements, such as for instance wheels, so that the cultivation device can be displaced without further transport means. In the known cultivating device, a stack of containers has to be moved by means of a transport means, such as a fork-lift truck.

According to a second aspect, the present invention relates to a cultivation system for growing potatoes, comprising a field and a plurality of cultivation devices.

Such a system is known and comprises a site with a plurality of the known cultivating devices, which are placed side by side on the site. With this, a site area can be used efficiently for potato cultivation, as has already been explained above. Besides the drawback mentioned above with regard to the cultivation devices, growing potatoes with such a system is also quite labour-intensive.

The object of the present invention is therefore to provide such a cultivation system, with which potatoes can be grown in a less labour-intensive manner. According to the second aspect, this is achieved by the present invention, in that the field is provided with a guiding device and the cultivating devices are provided with a guiding member, and are designed mobile to be moved over the field via the guiding device. It is thus possible to set up a guide in such a way that the cultivation devices can be moved relatively simply and in a targeted manner over the site via the guide system. In a mobile device, the lower holder can be provided with, for instance, wheels. It is also possible that the lower holder is placed on a mobile platform during a cultivation cycle. Alternatively, the cultivation device can be provided with one or more wheels at the top, on a hook or the top holder, for instance when a mobile device is suspended from a rail.

In a preferred embodiment of the present invention, the guiding device comprises a rail system, such as a monorail. A rail system is a simple solution for guiding mobile containers. The rail system can be designed as a ribbon, optionally with branches. Alternatively, the rail system can be grid-shaped, providing a very flexible transport system and allowing an arbitrary order of cultivators to be changed.

In an alternative preferred embodiment, the guidance device comprises a virtual guidance system, such as guidance software, and the guidance means comprises a virtual guidance device, such as a receiver for receiving instructions from the guidance software. Radio control is possible. Such a guide allows a more flexible routing than a more rigid guide, such as for instance a rail system. This gives greater freedom of movement. For example, to distribute the different cultivation systems differently over the site during the growth of the potato plants. This may be desirable in order to avoid that some cultivation installations are located in a relatively favorable location, while other cultivation systems are in a less favorable location.

When a cultivation system comprises a covering of at least a part of the site, this provides the possibility in (extreme) harmful weather conditions to collect the containers under the covering in order to protect the potato cultivation against damage. The covering may comprise a simple roof, but may optionally also comprise walls. The canopy can also cover the processing station.

Alternatively, a movable roof can be used, which is movable between a storage state and a use state. A storage condition here means that the roof is in a compact condition,

in which it covers only a small part of the site (and possibly does not cover the site at all. A state of use refers to a state in which the site is covered at least to a significant extent. For example, whether or not collapsible , sliding roofs, but also to elements which in a vertical position can serve as a windbreak and in a vertical position form a lean-to roof.This can have a separate supporting structure.Alternatively, a cultivation installation can comprise its own roof.

Preferably, the cultivation system comprises a processing station, which is designed to empty containers, fill containers with seed earth and/or seed potatoes and/or harvest potatoes, or otherwise take care of filling the containers. The containers can be transported to and from the processing station via the guide, where a desired processing can be performed. Several processing stations may be provided, each for performing one or more operations. For instance, one station can be provided where the containers are emptied after a number of cultivation cycles, while at another processing station the containers are refilled with new seed compost. This provides sufficient space to keep the old and new seed soil separate. Alternatively, there is only one operation station, where all operations can be performed.

According to a third aspect, the present invention relates to a cultivation method for growing potatoes, the method comprising: a) Providing a plurality of cultivation devices; b) Filling the cultivation establishments with seed compost; c) The planting of seed potatoes in the cultivation establishments; and d) After sufficient growth of potatoes, the lifting of potatoes from the cultivation establishments.

Such a method is known. Known breeding devices are used, which have already been discussed in the introduction with regard to the first aspect of the invention. The object of the present invention is to provide a cultivation method with which a higher yield per unit area of land can be achieved and/or is less harmful to the environment than with the known method. This object is achieved in that in step a} devices according to the first aspect of the present invention are provided. The advantages correspond to the advantages discussed above with respect to the first aspect of the present invention.

It is preferred here that the method further comprises the steps of: e) Moving a cultivation device to a processing station via a guide system; f The processing station performs one or more of steps b), c) and d); and g) Removing the cultivation device from the processing station.

With such a method, the cultivating devices are transported to a stationary and well-equipped processing station, which processing station can be designed for performing operations as efficiently as possible. A further advantage of this is that new seed soil can be brought to one location and does not have to be moved to the different stations. Likewise, used seed compost can be removed from the containers at one location and collected there for later disposal. A processing station can also be set up efficiently and ergonomically for other operations.

It is preferred that the method further comprises the step of optimizing the growth location of the growing device in the field by the guidance system, for example by handling a shunting system.

When a plurality of cultivators are serially led to the processing station to be successively processed by the processing system, efficient processing can be realized by repetitive operations.

The present invention will be explained in more detail below with reference to the accompanying drawing of preferred embodiments of the present invention. Shown are: Figure 1a is a perspective front view of a breeding device according to the present invention; Figure 1b is a perspective rear view of the cultivation device of figure 1a; Figure 2a shows a perspective front view of the device according to figures 1a and 1b, but without holders; Figure 2b is a perspective rear view of the device of figure 2a;

Figure 3 is a perspective top view of a container for use in a breeding device according to the present invention; Figure 4 is a perspective front view of a mobile cultivation device according to the present invention; Figure 5 is a front perspective view of an alternative mobile cultivation device according to the present invention; Figure 6 is a front perspective view of a hanging mobile cultivating device according to the present invention; and Figure 7 is a front perspective view of a breeding system according to the present invention.

Turning now to Figures 1a and 1b, there is shown a front perspective view and a rear perspective view, respectively, of a cultivating device 1 according to the present invention. The cultivation device comprises a platform 2 on legs 3, with which the cultivation device 1 is placed on a base. An upright 4 is attached near an edge of the plateau 3, which upright also functions and can be described as a spacer. In this embodiment, three carriers 5 are attached to the upright 4 at a vertical distance of 35 cm from each other, which carriers 5 each carry a holder 6a-c. The carriers 5 are provided on the side with which they are attached to the upright 4 with a drainage gutter 7, in which excess moisture is collected from a container 6 which is carried on the relevant carrier 5 . The excess water is drained via the drainage gutters 7 to the water reservoir 9, where the "contaminated" water is stored. water can be supplied to an upper empty carrier 11 . Water pipes 15 are branched off from the water inlet 14, of which only water pipes 15a and 15b are visible here, via which water pipes 15 can be supplied with water in water distributors, not shown in figures 1a, 1b.

Above the upper holder 6c, the substantially horizontally extending empty carrier 11 is attached to the upright 4 . The empty carrier 11 does not carry a container, but does have a water distributor 8 (not visible in figures 1a, 1b) for watering the upper container 6c. Above the empty carrier 11 is a roof panel 12 as a precipitation barrier, which protects the containers 6 below against rainwater.

Figures 2a and 2b show a front perspective view and a rear perspective view, respectively, of a frame device 21 for use in the present invention, as part of a cultivation device 1 of figure 1. The same reference numerals are used for the same parts as in figures 1a, 1b. These parts are not introduced again to avoid unnecessary repetition. Figure 2a shows a drain line 13, via which any water is fed from the drain channel 7 of the lower carrier 5a and drain holes of other carriers 5 coupled thereto to the water reservoir 9 . The water reservoir 9 can be provided with means for cleaning or otherwise making the water suitable, for instance by adding nutrients, for recirculation via a supply line (not visible in figure 2a). Figure 2a also shows the water distributor 8 of empty container 11 and the connection by means of water pipes 15a, 15b of the respective water distributors 8 to the water inlet 14.

Figure 3 shows an empty container 6 for use in the cultivation device

1. The holder 6 is a rigid, in this example metal, container with a bottom 22 of 60 cm X 40 cm and a side wall 23 of 16 cm high. Two handles 24 are provided on the short sides of the side wall 23. The bottom 22 is provided with perforations 25 on one long side.

Figure 4 shows a perspective front view of a mobile cultivating device 31 according to the present invention. Mobile cultivation device 31 is comparable to cultivation device 1, with the difference that the legs have been replaced by wheels 33 which are attached to platform 32. Similar parts are provided with the same reference numerals as in figures 1 and 2.

Figure 5 shows a front perspective view of an alternative mobile cultivation device 41 according to the present invention. Alternative mobile cultivation device 41 is comparable to cultivation device 1, with the difference that the legs have been replaced by wheel assemblies 43 fixed to platform 42 and movable on a pair of rails 44 . Similar parts bear the same reference numerals as in figures 1 and 2.

Figure 6 shows a front perspective view of a hanging mobile cultivator 51 according to the present invention. Mobile cultivation device 51 is somewhat comparable to cultivation device 1. An important difference, however, is that there is no platform and that the upright 54 hangs and is provided at the top end with a hook 52 and guide rollers 53 (only one of which is visible here), with which the cultivation device 51 is suspended from a guide rail 84 supported by a mast 63. On the underside, the upright 54 is provided with guide wheels 65 (only one of which is visible here) which supports laterally against a guide strip 66. The upright 54 does not carry a roof panel. Instead, a static solar panel 82 is provided on the mast 63. A horizontal water pipe 87 extends between the solar panel 62 and the upright 54, with a branch 68 to the upright 54 as a central water supply. Here it is additionally, but can also be alternatively provided for the supply line 60 from water reservoir 59. Figure 7 shows a perspective front view of a cultivation system 100 according to the present invention. Cultivation system 100 is located on site 101. On site 101 is an assembly of masts 63, guide rails 64 and guide strips 66. A central water pipe system 67 extends near the guide rails. Growing devices 51 are suspended from the guide rails 64. Some of the cultivation facilities 51 are located under solar panels

62. Other cultivating devices 51 are located in a processing station 102. The processing station 102 is equipped with various facilities, such as a conveying device 103 for supplying and discharging products and materials to and from the processing station 102, respectively, for processing topsoil, seed potatoes and cultivated potatoes. This is discussed later in this document. A device may also be provided at the processing station for removing and replacing the containers, whether or not automated.

In the following paragraphs, the operation of the cultivators of Figures 1 to 6 will be discussed, mainly with reference to the cultivator 1 of Figures 1a, 1b, 2a and 2b. The operating principle of the other cultivating devices 31, 41, 51 hardly differs therefrom, with the exception of mobility. Next, a preferred method according to the present invention will be discussed with reference mainly to Fig. 7. The cultivation method of the other respective mobile cultivation devices 31, 41 differs therein only in that they are automated to a lesser extent.

According to the present invention, in this exemplary embodiment, and as shown in figures 1 and 2, a frame device 21 and a holder 6 are provided for growing potatoes. The containers 6 are filled with topsoil and seed potatoes and placed on a carrier 5 of the frame device. In a static cultivation device as shown in figures 1 and 2, the material is brought to the frame device 21 . In mobile cultivators, the frames can be brought to a central location, such as processing station 102, and after placing the containers 6, they can be moved to a location on the site 101.

After placing the filled containers 6, the potatoes are given time to grow. The roof panel 12 protects the upper container 6c from rainwater. The lower containers 6a, 6b are protected against rainwater by a higher container 8b and 6c‚ respectively.

Water entering the water inlet 14, for example from the reservoir 9, is led to the empty carrier 11, in which a water distributor 8 is provided. Water entering the water inlet (14) is equally distributed among the connected water supply pipes 15a, 15b, 15c, each of which conducts the water to the respective water distributors 8a, 8b and 8c. The underlying containers 6 are watered via the water distributors 8 .

The water is absorbed into the soil of container 6c. The holder 6c is positioned slightly inclined, with the perforations 25 on the edge positioned towards the upright 4 at the lowest point. The perforations 25 are located above a drainage gutter 7, which collects the excess water. The excess water is discharged via the drainage gutters 7 to the water reservoir 9, where the "contaminated" water is stored. From the water reservoir 9, water can be fed upwards into the upright via supply line 10. The "contaminated" water that still contains usable minerals and fertilizers can later be mixed with clean water, which is then administered again via the water distributors 8. The water distributors each have their own water supply pipe.

In this way the potatoes are grown in the cultivation device 1. Of course, a nutrient or the like can be added if desired. Via the watering system or directly on the topsoil. In the case of mobile cultivating devices, the mutual location of the cultivating devices can optionally be changed, for instance by placing centrally positioned cultivating devices more to the outside and vice versa, so that it is prevented that the same cultivating devices are always exposed to wind and others are always protected against wind by surrounding cultivating devices.

When the potatoes have grown sufficiently, the grown potatoes can be removed from the containers 6 . This can be done by manually excavating, or alternatively by emptying the container 6 with soil and all, whereby potatoes are collected by a grid and the earth falls through the grid.

In addition, and this is an important advantage of a cultivator of the type according to the present invention, once in a certain number of cycles, or after the lapse of a certain time, the soil in the containers 6 can be refreshed to remove harmful nematodes from the containers. 6, 56 to delete.

The containers 6, 56 can then be immediately used again for a new crop, while when growing potatoes in the open ground, the soil must regularly be left fallow to allow the nematodes to die out.

To avoid having to carry material to all cultivators during a cycle, mobile cultivators 31, 41, 51 can be used.

The mobile cultivating devices 31, 41, 51 can be moved manually or automatically to a central processing location.

For example to a processing station 102. In mobile cultivation devices 31, 41, 51 the cultivation devices 31, 41, 51 are distributed over a site.

In the exemplary embodiment of Fig. 7, a highly automated growing system 100 is shown.

It is apparent to those skilled in the art that the automated and/or mechanized steps may alternatively be performed manually, individually or in combination.

Figure 7 shows a cultivation system 100 in which a framework of guide rails 64 suspended from masts 63 is provided.

Growing devices 51 are suspended from the guide rails 64.

In this exemplary embodiment, a limited number of articulated rails 64 and cultivation devices 51 are provided.

A central water supply system 67 is provided to supply the individual cultivators 51 with water.

It should be clear that the number can be expanded without any problems.

While the cultivating devices 51 in this exemplary embodiment can only be moved back and forth over a guide rail, it is equally possible to use a system in which the guide rails 64 are connected to each other such that a continuous rail system is formed.

Six of the cultivation devices 51 from figure 7 are suspended under roof panels in the form of solar panels 62. These solar panels 62 can generate electricity for, for example, moving the cultivation devices 51 over the rails. Because the solar panels 62 protect the cultivation devices 51 against rain, the cultivation devices 51 are not themselves provided with a roof panel.

Six cultivating devices 51 from figure 7 are suspended from a piece of guide rail 84 in a processing station 102 covered by a roof 104. The containers have been removed from three cultivation devices, for example by means of automated or robotized removal and replacement of containers. the supply of seed potatoes and fresh topsoil, the removal of cultivated and grubbed potatoes and (provisionally) depleted or nematode-infected topsoil, or other materials. In this way, operations can be performed centrally. The transport system will not be described in more detail here, since in the context of the present invention only the central supply and discharge are important, and not a specific way in which it is designed.

It is also possible to design the processing station in such a way that it is suitable for the temporary accommodation, for example to protect against a storm or during severe frost, of all filled cultivation installations 51. A separate protective space or building can alternatively be constructed for this purpose. provided.

Growing devices 51 usually hang shielded under a solar panel 62 from the guide rail 64. If a processing operation is to be carried out on the topsoil or potatoes in a container 56, the relevant breeding device 51 is moved over the guide rail 64 to the processing space.

Usually this will be done for all growers 51 in a line.

In the processing station, the containers 56 are filled as required with soil and seed potatoes, a treatment is performed on the containers 56, for instance spraying with growth-promoting agents, lifting the potatoes from a container 56 or completely emptying a container 56. in a "visit" to the processing station 102, several operations are performed in succession. It is also possible that filled containers 56 are replaced by other containers 56, so that the original containers 56 can be processed while the newly installed containers 56 are moved again to the location where the potatoes can grow.

The present invention has been described above with reference to some preferred embodiments. However, it will be clear that within the scope of protection, which is defined by the following claims, many variants or extensions, which are obvious or not to those skilled in the art, are conceivable.

For example, it is possible to move the mobile devices in the field by means of wireless communication, without the need for physical guiding means.

LIST OF REFERENCE NUMBERS 1 cultivation device 2 platform 3 legs 4 upright 5,5', 5b, bc support 6, 6a, 6b, 6c holder 7,7a, 7b, 7c drainage gutter 8, 8a, 8b, 8c water distributor 9 water reservoir 10 supply line water reservoir 11 empty carrier 12 roof panel 13 drainage pipe 14 water inlet 15, 15a, 15b, 15c water pipe 21 frame device 22 bottom 23 side wall 24 handle 25 perforations 31 mobile cultivation device 33 wheel 41 alternative mobile cultivation device 43 wheel assembly 44 rail 51 hanging mobile cultivation device 52 hook 53 guide roller

54 column 55 carrier 56, 56a-c holder 57a, 57b, 57¢ drainage gutter 59 water reservoir 60 supply line 61 empty carrier 62 solar panel 63 mast 84 guide rail 65 guide wheel 66 guide strip 67 central water pipe 68 branch central water pipe 100 cultivation system 101 terrain 102 processing station 103 transport device 104 roof

106 central water supply

Claims (17)

CONCLUSIONS Growing device (1, 31, 41, 51) for growing potatoes and/or vegetables, comprising at least two mutually connected containers (8, 8a, 6b, 6c, 56a, 56b, 56c) with a bottom (22), at least one side wall (23) extending upwards from the bottom (22) with an upper edge, adapted to receive seed compost and potato plants, wherein at least one spacer (4, 54) is provided which two above interconnects containers (6a, 6b, 6c) together and creates a vertical distance between the top edge of a container (6a, 6b) and the bottom of a container (6b, 6¢) directly above it. Growing device {1, 31, 41, 51) according to claim 1, wherein the at least one spacer (4, 64) is detachable from at least one of the holders (6, 56). A growing device (1, 31, 41, 51) according to claim 1 or 2, wherein the plurality of superimposed and interconnected containers (6a, 6b, 6c, 56a, 56b, 560), three, four, five or more amounts to. Cultivation device (1, 31, 41, 51) according to one or more of the preceding claims, wherein in the case of containers (8a, 6b, Bc, 56a, 56b, 56¢) located above each other, a higher container (6b) is provided. 6¢, 56b, 56c) has a smaller horizontal cross-sectional area than a lower container (6a, 6b, 56a, 56b). Cultivation device (1, 31, 41, 51) according to one or more of the preceding claims, wherein the cultivation device is provided with at least one supply line (10, 60) which can be connected to a water supply (9, 59), which at least one supply line (10, 60) is designed for watering the seed compost in the containers (6, 56). Growing device (1, 31, 41, 51) according to claim 5, wherein the at least one supply line (10, 60) is provided in or on the at least one spacer (4, 54). Cultivation device (1, 31, 41, 51) according to one or more of the preceding claims, wherein a sun or precipitation shield is provided above the highest container (6c, 56c), preferably in the form of a roof panel (12 , 62). Growing device (1, 31, 41, 51) according to claim 7, wherein the precipitation barrier comprises a solar panel (62). 9. Cultivation device (31, 41, 51) according to one or more of the preceding claims, wherein the cultivation device (31, 41, 51) transporting means (33; 43, 44; 53, 64) is mobile, or at least displaceable. Growing system (100) for growing potatoes, comprising a field (101) with a guiding device (52, 53, 63, 64), a plurality of growing devices (51) according to claim 9, which growing devices (51) are provided with a guide member (53), and are adapted to be moved over the terrain via the guide device (52, 53, 63, 64). Growing system (100) according to claim 10, wherein the guiding device comprises a rail system (64), such as a monorail. The breeding system (100) of claim 10, wherein the guidance device comprises a virtual guidance system, such as guidance software, and the guidance means comprises a virtual guidance device, such as a receiver for receiving instructions from the guidance software. Growing system (100) according to one or more of the claims 10-12, wherein the system comprises a covering (104) of at least a part of the site (101). Growing system (100) according to one or more of the claims 10-13, wherein the system comprises a processing station, which is arranged to empty containers (56), fill containers (56) with seed soil and/or seed potatoes and/or to dig up potatoes, or to take care of the filling of the containers (56) in some other way. A cultivation method for growing potatoes, the method comprising: a) Providing a plurality of cultivation devices (1, 31, 41, 51) according to one or more of claims 1 to 9; b) Filling the cultivation devices (1, 31, 41, 51) with seed compost; c) Planting seed potatoes in the breeding establishments (1, 31, 41, 51); and d) After sufficient growth of potatoes, the harvesting of potatoes from the cultivation facilities (1, 31, 41, 51). A cultivation method according to claim 15, wherein the method further comprises the steps of: e) moving a cultivation device (31, 41, 51) to a processing station (102) via a guiding system; and fy Performing one or more of steps b), c) and d); g) Removing the cultivator from the processing station (102). A cultivation method according to claim 15 or 16, wherein a plurality of cultivation devices (41, 51) are led in series to the processing station to sequentially undergo one or more processing by the processing system.