SE535207C2 - Cultivation - Google Patents

Abstract

The present invention concerns a cultivation system (1) comprised of an endless cultivation track (2) that contains at least one V-shaped loop (6), at least one source of light (7), at least one device (9) for irrigating the cultivation trays (10) and at least one control system (8). The invention is unique because its cultivation track (2) contains supports (4) which are equipped with at least two spacers (14) which allow an airflow around the lower areas of the cultivation trays (10) and that the cultivation track (2) may be enclosed in a transportable unit (3) such as for example a container.

Description

535 207 the covering plate of the dark zone and also in the space under the plate. This causes problems with cleaning and also maintenance, as it is difficult due to access reasons to keep areas above and below the covering plate clean. Furthermore, the cleaning step causes a downtime that is unfavorable for the growth of the plants in the cultivation system.

The serpentine-shaped cultivation path forms in a side view a number of substantially V-shaped loops and the artificial light is arranged to illuminate the plants advanced inside the respective V-shaped loops mainly from above. Because the serpentine loops are V-shaped and the artificial light is arranged to illuminate the interior of the diverging paths in its V-loop from above, an optimal replacement of the artificial lighting is achieved.

In order to streamline and remove the cultivation trays from the cultivation path, as well as to carry out an efficient irrigation of the cultivated plants, a device and a method for the use of the device have been developed. The construction, which is described in the Swedish patent SE527520, entails a more efficient loading and unloading of the cultivation trays to and from the cultivation track. Furthermore, more efficient irrigation of plants grown in the cultivation trays is made possible.

However, the device has proved difficult to integrate into a replaceable cultivation system in accordance with the present invention. More specifically, time-consuming work needs to be carried out both with a sufficient irrigation of the cultivated as well as loading and unloading of the cultivation trays in the cultivation path.

The known type of cultivation path with associated irrigation device has been found to work excellently in the cultivation of plants which are not replanted during the cultivation. On the other hand, it has been found that when growing plants that are replanted, such as forest plants, the roots strive to grow out through the bottom of the respective containers in the growing boards and grow together with each other.

The overgrowth of the plants means that time-consuming work must be carried out to separate the plants. Furthermore, the root system can be deformed by the root system growing out of the container.

The deformed root system leads to a clear deterioration in the quality of the plants and the future trees.

Although the above cultivation path with associated handling and irrigation device very well fulfills its set purposes, it is not arranged to be able to be moved in a simple way from one place to another. When moving the dangerous cultivation path, extensive buildings must be erected or be available to accommodate the cultivation system. 535 207 Furthermore, extensive disassembly and assembly work is required to move the cultivation system from one place to another. These problems are especially great when growing in extreme climates such as the Arctic and Antarctic. Furthermore, the problem exists, for example, when the cultivation system is moved to youth areas, nature reserves and / or national parks where cultivation of, for example, endangered plants and the like can take place. In jungles and national parks, buildings are difficult or unsuitable (forbidden) to build. At present there is no portable equipment which can be used for temporary cultivation in these areas.

An additional problem with non-toxic cultivation systems is that none of these systems are portable and specially adapted to be able to create an environment that is different from the surrounding environment.

The need to separate the cultivation path from what is cultivated is great in your areas. For example, in research and experimental cultivation, there is a need to be able to control environmental conditions to a large extent. For example, great precision and accuracy are required in controlling environmental conditions when culturing somatic embryos. Today, there is no fast and usable cultivation path developed for this purpose.

An additional problem with dangerous cultivation systems exists in connection with space travel and possible future colonizations of the moon, Mars and other planets with any associated moons. NASA, for example, sees this as a major problem and is actively looking for effective solutions on how cultivation can take place outside the Earth's atmosphere. However, there are no solutions to this problem. One of the problems is to create an environment where plants can be grown both for food or to generate oxygen. It is obvious that there are major problems with cultivating in space or on other planets. One problem is to create a controlled environment (air, water, light, heat, etc.) where the plant themes can grow. Another problem is that the plants must be kept in place if there is no natural and / or artificial gravity and that irrigation must also take place in a way that meets the plants' needs in such an environment. Yet another problem is to create protection against harmful cosmic radiation that is normally hindered by the Earth's atmosphere and magnetic field. It is obvious that there is a need for equipment with which plants can be efficiently propelled in places other than on earth and in the earth's atmosphere.

An additional problem is the customers' ever-increasing demands and desire to gain knowledge of the origin of vegetables. This is the case, for example, in some Arab countries where only plants grown in a certain specific way can be approved to be eaten as food. 535 207 fi 'Furthermore, there is an increasing demand for locally grown food products that are grown locally in an environmentally friendly way. There is an increasing demand for demand for locally grown vegetables such as lettuce in the vicinity of, for example, a shopping center or the like.

An even further problem is to create a flexible cultivation system that can be quickly changed and adapted to be used to propel plants and the like which require different types of plant conditions. Such an example consists of situations where forest plants and vegetables and the like can be grown with the same cultivation system. The different types of plants require different types of conditions regarding light, climate and the like in order for optimal growth to take place.

With reference to the above-mentioned problems, it is obvious that there is a need for a substantially improved cultivation system with associated containment.

Brief description of the inventive object An object of the present invention is to provide a considerable improvement of the above-mentioned disadvantages. This is achieved by means of a device in accordance with the characterized parts of the claims. Another object of the present invention is to enable a fast and easy movement of the cultivation system from one place to another. A further purpose is to enable a controlled cultivation environment which can be controlled in an efficient manner. Furthermore, an object of the present invention is to create a system with which the cultivation system can possibly be used in space. A further object of the present invention is to provide a cultivation path with a substantially improved dark zone than existing constructions of cultivation paths with dark zones. An even further object of the present invention is to provide a cultivation system with a substantially improved possibility of recycling water. One of the objects of the present invention is to create a cultivation system which is quickly used in the cultivation of plants which require different types of plant conditions such as forest plants and vegetables. Detailed Description of the Invention The invention will be described in more detail in the following with reference to the accompanying schematic drawings which in exemplary view show the presently preferred embodiments of the invention.

Figure 1 shows the present cultivation system which is enclosed in a releasable container or the like.

Figure 2 shows a preferred embodiment of a supporting member with the cultivation boards.

Figure 3 shows a variant of load carrier and a system for recycling water.

Figures 4A - 4C show a cultivation path which is provided with a dark zone, preferably constituting one third of the length of the path.

With reference to the fi gures, a cultivation system 1 is shown in accordance with the present invention. The cultivation system 1 comprises a cultivation path 2 which is preferably enclosed in a dry-expandable unit 3 such as, for example, a container, a building that can be replaced or another purpose-suitable unit. In Figure 2, details of the enclosing unit are not illustrated so that the enclosed cultivation path 2 can be illustrated. The movable unit, however, comprises walls, ceilings and floors with which the cultivation path 2 is enclosed. In alternative embodiments, the cultivation path 2 does not have to be enclosed in a displaceable unit but can be located in the open air. Alternatively, the cultivation path may be completely or partially enclosed by a non-dry removable unit.

The cultivation path 2 in accordance with the present invention can consist of a further developed variant of the previously known type of cultivation path described in the Swedish patent specification SE467643. The cultivation path 2 comprises a number of support members 4 (cultivation shelves) pivotally mounted between a framework and arranged at a distance from each other, which are connected to each other via chains 5 or the like. Through the construction, an endless serpentine-shaped web is obtained. The serpentine-shaped cultivation path forms in a side view at least two substantially V-shaped loops 6. In order to supply cultivation light, the cultivation path is provided with at least one light source 7 for emitting artificial light. The light is mainly arranged to illuminate the plants presented from above inside the respective V-shaped loops. Because the serpentine loops are V-shaped and the artificial light is arranged to illuminate the interior of the diverging paths in its V-loop from above, optimal replacement of the artificial lighting is obtained.

For the operation of the cultivation path, this is provided with at least one drive unit (not shown in fi gures) which transmits a rotating torque which drives the endless path. For control of the speed of the endless path, lighting, temperature, accuracy and other parameters, the cultivation system is provided with at least one control system 8. The control system consists of already known technology, which is why this is not described in more detail in this patent application. To supply water and nutrients, the cultivation system comprises at least one irrigation device 9.

Figure 2 shows an embodiment of a support member 4, which carries a number of cultivation boards 10, mainly intended for use in connection with the cultivation of forest plants and similar plants. The support means 4 are at each end with at least one holder 12 stored connected to an endless chain 5 or the like in the cultivation path 2. The support means 4 comprise a V-shaped profile 13. The support means 4 contains, unlike the support means in the cultivation path in patents SE467643 and SE 527520 , at least two spacers 14 which simultaneously function as holding means for the cultivation trays 10. Furthermore, the supporting means 4 are provided with at least one hole 15, preferably at least 20 holes on each side of the V-shaped profile 13. Through the holes 15, the spacers 14 and the the movement of the endless cultivation path enables a circulation of air in accordance with the arrows 16 through the V-shaped profile 13 and around the lower parts of the containers 11 on the underside of the cultivation trays 10 where the roots of the cultivated are located. Through the air flow, the lower edge of the containers 11 and the nearest enclosed culture medium dry, respectively. This has the unexpected technical effect that the roots of the cultivated plants do not tend to grow out of (through) the holes in the containers in the cultivation trays. This is a particularly important advantage in connection with plants that must be replanted in connection with the cultivation of these. Because the roots of the plants do not grow together, cultivation becomes more cost-effective and an increased quality of the root systems of the cultivated plants is achieved.

The spacers 14 each comprise at least one V-shaped segment 17 which is arranged to be partially inserted between two containers 11 in the cultivation tray 10. The V-shaped segments 17 prevent the cultivation trays 10 from sliding off the spacers 14. The spacers 14 also make it possible to light can be applied to the underside of the cultivation trays.

To enable illumination of the underside of the cultivation trays, the cultivation system may comprise at least one artificial lighting unit (not shown in the figure) which emits a light directed upwards or angledly directed upwards. The emitted light dries up the lower parts of the containers 11 and the nearest enclosed culture medium. This prevents the roots from growing out through the holes in the containers in the growing broths. Because the roots of the plants do not grow together, cultivation becomes more cost-effective and an increased quality of the root systems of the cultivated plants is achieved.

In order to enable an efficient handling of irrigation of forest plants and the like, this is provided with an irrigation device 9 for supplying liquid to the cultivation trays 10.

The device comprises a function for automatically sensing the moisture content in the cultivation trays. This can be done by sensing weight or by examining the conductivity of the soil (which is changed by the moisture content). A variant that can be used consists of the device and the method in accordance with the patent specification SE527520, so this system is not described in more detail in this patent application. The support means (cultivation shelves) can accommodate any number of cultivation trays 10. The number of cultivation trays 10 depends on the size of the cultivation trays 10 and the cultivation path width. Furthermore, the size, number and design of the growing boards 10 depend on the type of plant to be grown. The cultivation trays contain a large number of smaller containers 11, the lower part of which contains holes (not shown in fi gures). Through the holes, water can flow into and out of the containers ll in connection with irrigation. The irrigation takes place by immersing at least the lower parts of the cultivation trays 10 in a trough with water with a device according to patent SE527520 or another irrigation device suitable for the purpose.

With reference to Figure 3, a variant of an irrigation system 9 for the cultivation path is schematically shown. The framework with bearings with your components, chains and the like which connect a support member 4 to other support members has been disclosed in the figure.

The irrigation system is equipped with a function for supplying, collecting and recycling nutrient solution 19 (water and nutrients). The embodiment is mainly intended for use in the cultivation of plants such as, for example, lettuce plants and herbs. The support means 4 is seen from the front, which at its end is provided with a number of plants 20 in pots 21, or another container suitable for the purpose, immersed in holes in the upper side of the support means 4. At one end 22 of the support means 4 nutrient solution from a tank 23 (with input pump system) via at least one nozzle 24 or similar. 535 207 The nozzle 24 is connected via at least one pipeline, hose or the like to the tank 23. At the other end 25 of the support means 4 there is a container 26 for collecting excess nutrient solution. The support member 4 is mounted so that it has a certain slope according to the longitudinal direction of the support member. The slope causes excess nutrient solution to flow down the length of the support member 4 to at least one container 26.

At at least one position along the path, the container 26 is actuated (operated) to be rotated around the center of rotation 27 (storage) so that nutrient solution in the container is transferred to a collecting chute 28 or the like. Actuation of the container can take place with an operating equipment 29. The operating equipment 29 consists in the figure of a pressure cylinder which via an arm 31 causes the container 26 to be rotated about the center of rotation 27.

Preferably, the pressure cylinder is pneumatically driven and of a double-acting type.

Via the collecting tube 28, the collected nutrient solution flows down into tank 23 for the nutrient solution 19. Thereafter, the process can begin again with nutrient solution being added to the plants placed in the support means and excess nutrient solution being collected in the container and so on. Figure 3 also shows holders 32 which are stored connected to the endless chains (not shown in the figure) in the cultivation path. Preferably, the holders 32 should be able to be quickly released from the endless chains so that a rapid change of the supporting members can be enabled. Figures 4A - 4C show illustratively and schematically embodiments of the cultivation path where this year is provided with a dark zone 33 which preferably consists of one third of the length of the path.

The dark zone 33 is substantially sensed from the rest of the cultivation path. The cut-off takes place by guiding the web through a first opening 34 into an enclosing housing 35 or the like, which shields the dark zone from ambient light such as the light from the artificial lighting. In the dark zone, the loops are preferably substantially vertical as shown in Figure 4A. Alternatively, the loops may be drawn horizontally in accordance with Figures 4B and 4C. The vertical loops or the horizontal loops save space in the dark zone. The dark zone is terminated by leading the web out of it through a second opening 36 in the housing. The climate of the dark zone is regulated by means of some type of climate system 37, of a previously known construction, which is why this is not described in more detail in this patent application. The space in the dark zone is mainly cooled. The dark zone produces vital plants and is favorable for plant growth. Particularly favorable is the dark zone for growing lettuce, spices and the like. Horizontal loops in accordance with Figures 4B and 4C have unexpectedly been found to lead to a simpler design of the cultivation path out of the dark zone and have resulted in improved energy use in the air conditioning system.

The displaceable unit 3 can be of a previously known type of container such as that shown, for example, in the clock. Alternatively, the removable unit 3 may consist of a removable building or any other suitable unit suitable for the purpose.

It is conceivable that the removable unit may consist of your interconnectable units. The cultivation path can thereby be moved in your separate units which are connected at the place where these are to be connected.

If the displaceable unit consists of a container, this may consist of a standardized 20-foot ISO container which is adapted to the present end needle to enclose the cultivation path. In alternative embodiments, other types of enclosures may be used. The length, width and height of the container are not limiting for the present invention but can vary greatly within the scope of the present invention. Thus, other sizes of standardized containers can be used and specially designed for removable enclosures suitable for the purpose can be used.

In order to illustrate (show) the enclosed cultivation path, for example when placing the cultivation system adjacent to a shopping center or the like, at least one side of the enclosure may be wholly or partly of a transparent material such as glass, polymeric material or the like.

In the specific application where the cultivation system is used in space, it is obvious that the enclosure is completely tight. Alternatively, the cultivation path in the enclosure can in turn be enclosed by a completely tight casing such as some form of spaceship, space station or the like.

It is conceivable that the enclosure can be moved to a number of separate units which are connected at the place where the cultivation path is to be used.

To enable adjustments of the framework as well as a quick assembly and disassembly of the cultivation path for maintenance and the like, the framework is joined with connecting elements with which the cultivation path can be quickly joined or disassembled. A suitable such coupling element is described in the Swedish patent SE526962. Although certain preferred embodiments have been described in detail, variations and modifications within the scope of the invention may be apparent to those skilled in the art and all of them are considered to fall within the scope of the appended claims. For example, the equipment may include functions for generating electrical energy such as solar cells or a smaller wind turbine.

Advantages of the invention The present invention provides a portable cultivation system in an enclosure which can be moved from one place to another substantially quickly and easily. Furthermore, the advantage is achieved that a cultivation in a controlled environment can take place. Furthermore, an opportunity is obtained to control the growing environment for growing plants with great precision. The design achieves the important advantage that the roots of the cultivated plants do not grow together, whereby the cultivation becomes more cost-effective and an increased quality of the root systems of the cultivated plants is achieved. Another advantage of the present invention is that the cultivation path can be easily adapted to the type of plants to be cultivated with it. A further advantage of the present invention is that this can be used outside the Earth's atmosphere, for example in a spaceship, on a space station or the like, and also on celestial bodies other than the earth.

Claims (9)

535 207 / I Patent claim Cultivation system (1) comprising an endless cultivation path (2), with at least a number of supporting members (4) each carrying one or more cultivation trays (10) resting on the supporting means (4), the path of which comprises at least two substantially V-shaped loops (6), at least one source of artificial light (7), at least one device (9) for irrigating the cultivated plants, at least one control system (8) and at least one dark zone (33) characterized by the supporting means (4) are provided with at least two spacers (14) which allow an air gap around the lower parts of the cultivation trays (10). Cultivation system (1) according to claim 1, characterized in that the spacers (14) comprise a V-shaped segment (17) arranged to be partially inserted between two containers (1 1) in the cultivation tray (10). Cultivation system (1) according to at least one of the preceding claims, characterized in that the supporting means (4) are provided with a number of holes (15) which improve the air flow around the lower parts of the cultivation trays (10). Cultivation system (1) according to at least one of the preceding claims, characterized in that the cultivation system is arranged to be quickly transferable from one cultivation site to another in that the cultivation system is enclosed in a transferable unit (3). Cultivation system (1) according to claim 1, characterized in that the lighting source (7) is artificial and is located in the space between the V-shaped loops (6). Cultivation system (1) according to at least one of the preceding claims, characterized in that the cultivation system comprises at least one lighting unit which emits light towards the underside of the cultivation trays (10). Cultivation system (1) according to at least one of the preceding claims, characterized in that the replaceable unit (3) comprises a standardized container. Cultivation system (1) according to claim 7, characterized in that the standardized container consists of a 20-foot container. 535 20? ll Cultivation system (1) according to at least one of the preceding claims, characterized in that the dark zone (33) comprises at least two substantially vertical loops. lO. Cultivation system (1) according to at least one of the preceding claims, characterized in that the dark zone (33) comprises at least two substantially horizontal loops.