SE527520C2 - Addition method of liquid solution into plant cultivation substrate, involves temporarily lifting growing tray, with aid of lifting mechanism, from cultivation system's growing shelf - Google Patents

Abstract

A growing tray, with the aid of a lifting mechanism, is temporarily lifted from the cultivation system's growing shelf. The lifting mechanism includes a sensor that senses the weight of the growing tray and need for moisture for the cultivation substrate and plant. An independent claim is also included for a device for addition of a liquid solution into a plant cultivation substrate.

Description

527 520 Z Filled pots or other containers are placed on or in the support means in which the product to be operated is arranged to be stored. The cultivation path has an adjustable feed rate. Furthermore, the luminaire is designed to provide an artificial light.

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 only from above the plants advanced 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 divergent paths in its V-loop from above, an optimal exchange of the artificial lighting is obtained. Although the construction described in patent specification SE 467643 fulfills its seams, it does not comprise an automatic irrigation device where a weight sensing sensor controls the containment of the cultivated. Furthermore, the construction does not include an automatic input and output unit of the cultivated to and from the machine. The aim of the present invention is therefore to create a simple equipment which in a cost-effective manner both irrigates and moves the cultivated in and from cultivation systems and the like. Preferably, the invention aims to create a construction which can be integrated with the cultivation system described in patent SE 467643.

Prior Art Cultivation tracks which include devices for automatic irrigation by underwater irrigation, i.e. where irrigation of the culture medium and the culture takes place from below, are already known. Thus, in patent loops GB 984404, FR 2345912 with your patents, endless cultivation paths with containers are described which describe vertical serpentine-found loops. The containers with the cultured medium are lowered, in the lowest position in a serpentine-shaped loop, into a basin filled with water and possibly with nutrients. The construction does not include an automatic sensing of the liquid demand and lacks a unit for efficient input and output of the cultured.

A similar technical solution is described in patent patent US 5943818 which constitutes a system for growing plants in a greenhouse, where the plant containers are allowed to circulate along an endless serpentine-shaped path. Via the serpentine-shaped web, the containers with the cultivated are moved vertically so that the height of the building is used more efficiently. The plants in the containers are irrigated and fertilized 527 520 n J passively with nutrients by the containers when moving along the path passing one or fl your irrigation stations where the containers are dipped in basins filled with water.

Via the US patent application US 2004/01 11965, a cultivation path with weight-sensing control for irrigation is known. The construction is based on sensing the weight of cultivation shelves which are added to the cultivation track. As a consequence of the cultivated plants consuming added water, the weight of the cultivation shelves with its contents decreases. When the weight decreases to a certain level, the cultivation shelves are moved to a position where new water filling takes place. The construction is based on a substantially different technology than that of the present invention.

None of the above constructions comprises a combined irrigation device which, by means of weight sensing, senses the need for irrigation. Furthermore, none of the above constructions comprises a combined device for automatic irrigation and automatic insertion and exhaustion of the cultivation trays with embryos, seeds, cuttings or plants in cultivation substrates. Description of the invention The device according to the invention is preferably integrated with the cultivation system described in patent SE 467643. the device according to the invention can also be connected to other cultivation systems.

The present invention is included as an important element in the cultivation of all kinds of plants and more particularly to meet the need for liquid. This primarily refers to the cultivation of plants from the seed stage. Preferably, seeds, plants, cuttings or embryos (for example somatic embryos) are placed in the culture trays, which according to the invention are placed on a suitable load carrier and which are hereinafter referred to as a culture shelf.

The liquid may consist of water only, but may also contain growth-promoting nutrients. In some cases, the liquid may also contain biocides. Characteristic of the invention is that the supply of liquid takes place by automatic means. With the support of the elements 1 - 5, the invention will be described in more detail. Fig. 1 shows in a first side perspective a sketch of vital parts of the device. Fig. 2 shows in cross section vital parts of the device Figs. Fig. 3 shows in bird's eye view a transport path for the cultivation trays. Fig. 4 shows in side perspective a simplified sketch of the conveyors of the invention. Fig. 5 shows a perspective drawing of the shelter device I ly g. 1 shows the cultivation trays (boxes) 1 which are located on a cultivation shelf 2. The cultivation shelf can have space for any number of cultivation trays. To obtain rational and high capacity, at least three cultivation trays are placed on each cultivation shelf. Sketches in fi g. 1 and 4 show exactly three (distributed over three conveyors) cultivation trays while in fi g. 3 shows the five cultivation trays.

Of course, this has no bearing on the meaning of the extension as the choice of the number of cultivation trays is arbitrary (as long as there is space on the load carrier).

The material in the cultivation trays can be made of different materials which do not have a detrimental effect on either the external or internal environment. Examples of such materials are polyethylene plastic and so-called bioplastic which is degradable in nature. Other degradable materials are wood, cardboard of pulp with or without the admixture of peat beads. Inert materials such as aluminum can also be used.

The size of the cultivation shelf and the cultivation tray can be chosen arbitrarily. As for the cultivation shelf, its length can vary from 0.5 m up to 10 meters and its width from 20 cm up to 80 cm.

Deviations from specified dimensions are of course possible, but can lead to practical problems. Furthermore, the dimensions of the cultivation shelf depend on the size of the cultivation tray and of course on their number.

Suitable dimensions on the sides of the cultivation boards range from 100 mm up to 800 mm and the shape can be square or rectangular. In rare cases, the culture tray can have a circular shape. Regardless of shape, the cultivation boards should preferably have a depth of at least 5 mm. For irrigation under the river, the cultivation tray is provided with a perforated bottom. Within the scope of the invention, the cultivation trays without perforated bottom can also be used if the irrigation takes place only on the upper side of the cultivation.

Described cultivation shelf with the cultivation trays, which is shown in fi g.l is lifted off from a continuously operating cultivation system 3 (shown only symbolically in fi g. 1), which contains a large number of load carriers with the cultivation trays. It can be mentioned that each cultivation shelf is suspended in such a way that the bottom part of the cultivation shelf always settles below its upper part with the cultivation boards. 527 520 S 'These units are held up and moved by means of endless elongated bands or chains whose movement patterns can be described as a roller coaster.

This arrangement means that one and the same cultivation tray returns to the same position before they are lifted off the cultivation shelf.

The movement of a cultivation shelf with its cultivation trays usually takes place at a speed of between 5 cm and 20 cm per second (3 m and 12 m per minute, respectively). In other words, the speed is low and this is of course largely due to the slow growth of plants. The relatively slow speed is amplified by the fact that the displacement preferably takes place within certain intervals. Suitable time intervals are 2-4 minutes. For example, the transfer can take place every 3 minutes and for 5-10 seconds. Another reason for the slow speed is that the plants, such as lettuce heads or forest plants, can be exposed to artificial light in certain positions and at certain time intervals. Some of the light can radiate from a light source that emits ultraviolet (UV) light.

Irrom within the framework of the invention, liquid with nutrients can be added to the cultivation trays by automatic feeding.

According to the invention, each culture tray is filled with a predetermined amount of culture substrate with known moisture content. The cultivation substrate can consist of olika your various materials such as peat, sand, cultivated soil, soil obtained from composting, bark and sludge.

The total weight of culture medium, plant (fi island, plant, sticlding or embryo) is weighed with great precision. A core part of the invention is that this weight is followed up at regular intervals. To achieve this automatically, the present invention is applied.

According to a certain schedule, the cultivation trays are lifted from the transport system for weight control, which indirectly constitutes a measure of moisture content and achieved growth. For said weight and growth control, the cultivation trays are fl replaced by means of a ly fi device 4. The ly fi device, which may be an ordinary hoist, comprises a sensor which, after correction of accessories, senses the weight of the culture medium and in particular registers the weight of the plant.

If in the above-mentioned operation it appears that there is a need for liquid, the culture tray is passed on and lowered into a basin 5 completely or partially filled with water. The water may contain nutrients or biocides. Depending on the ability of the substrate to effectively absorb liquid, a relatively rapid increase in the total weight of the culture trays is obtained. This change in weight is registered by means of the previously mentioned sensor by illuminating the culture tray from the pool. 527 520 é To achieve an fi unnecessary uptake of water to the cultivation substrate and the plant, the cultivation tray is kept immersed in the pool for any time. For example, when growing pine plants, the growing board is kept immersed in the pool for at least 20 seconds and sometimes up to 80 seconds. In the event that the sensor of the ly device notices that the amount of water absorbed falls below a specified setpoint, which is in principle equivalent to a saturated culture medium, the culture tray is dipped back into the basin, after which the previously described procedure is repeated.

The water can also be applied via one or more nozzles (not shown in ur gur) which can, for example, be arranged on a carriage which runs on the edges of the pool.

The control of weight described above also constitutes an indirect control of growth. A more direct measure of growth is the use of equipment and instruments that indicate units of measurement in parts of the meter system or other measurement systems. In its simplest form, the measurement can be performed manually using a ruler or ruler. By using optical measurement, such as laser, more accurate measurements are obtained and in addition the measurement can be done automatically and with registration.

When the plant has reached a weight and / or dimensions that show that the plant can leave the system, additional work steps occur. As a first step, the pool is emptied of its liquid content.

The liquid can of course be reused if it is filled into a container suitable for this purpose. This container can be provided with an somlter which can purify the liquid from particles which may have been released from the culture medium.

When the basin is emptied of its liquid content, it is moved half a turn (180 °) by its rotation around its bracket towards the shaft 6. A transport device 7 is connected to the same shaft.

A core part of the invention is thus that the transport device and the basin are connected to one and the same rotatable shaft. As shown by fi g. The conveyor belt is below the basin and in its lowest position. After half a van / s (180 °) rotation, each unit assumes opposite positions. This change is illustrated by fi g. 2.

Because the conveyor has the position shown in fi g. 2, the cultivation trays can be placed on the conveyor for further transport to an intermediate storage or directly to the user of, for example, seedlings or lettuce heads. This removal from the system can advantageously be carried out by means of a conveyor belt 8. At the receiving station, the cultivation trays can, for example, be loaded on pallets or racks.

Filling of new cultivation trays can take place in different ways. The easiest way is manual loading. For a more rational handling, feed can be used via a conveyor belt 9, which is in the same plane as the rotatable conveyor. 527 520 fi ki Fig. 3 schematically shows a conveyor belt with the cultivation trays on which lie five cultivation trays filled with seeds and cultivation substrate which is fed to the rotatable transport device (7). The new cultivation tray is weighed in connection with it being placed on one of the cultivation system's many cultivation shelves. Because the cultivation board is weighed at certain intervals, a good control of the plant's continued growth is achieved.

Most of the described work steps are controlled with the help of computerized control and regulation technology.

This also facilitates the registration and storage of data such as water consumption and plant growth. _ With the support of fi g. 5, the lyre device (4) which constitutes an essential tool in carrying out the method in accordance with the invention will be described in more detail. The Ly device has a fixed frame 10 which comprises a number of moving parts. On the upper beam parts 1 1. 12 of the stand runs in a horizontal direction a hoist 13, which can also move the gripping claws 14 of the device up and down.

These claws are laterally displaceable. The movement patterns of telephones and gripping claws are shown by arrows (A-C) in fi g. 5.

In accordance with the design of the invention, the cultivation trays (1) are detached from the cultivation system (4) for irrigation and growth control of the cultivated object. Thus, the cultivation trays (demonstrated by arrow H) are moved by means of the hoist to the basin for irrigation. This irrigation can take place by immersing the cultivation boards in the basin (5) or by means of nozzles which apply the water (with or without additive) in a position above the plant. Said nozzles are connected to a conduit 16, which in turn is driven by a carriage 17. This carriage is moved back and forth (illustrated by arrow I) on the basin, which thus functions as a ramp.

Within the rafters for the invention, the cable can be moved with nozzles from a ramp that extends between the beams of the stand (l1,12). After irrigation, a reverse order of the described takes place for fl the cultivation boards.

As stated in the decision for the actual execution of the invention, the pool or emptying of liquid can be made to rotate half a turn so that the belt conveyor (7) of the device will be above the pool. Described movement pattern is illustrated by arrows E., G and F.

When applying the invention, your benefits are obtained. Through far-reaching automation, few people are required to manage the plant, which also has a high production capacity.

The high capacity has surprisingly not resulted in poorer quality of the plants.

Particularly surprising is the exceptionally even size obtained with the plants. This regardless of the type of plant.

Claims (8)

1. 527 520 å? Claim 1 Method for supplying liquid to culture media containing seeds or plants, seedlings or embryos and which device i.a. comprises cultivation shelves (2) on which are placed the cultivation trays (1) which are integrated with a cultivation system (3) which automatically moves the cultivation trays, characterized in that the cultivation trays are temporarily lifted from the cultivation system's cultivation shelf (2) by means of a shelter device (4). sensor, which detects the weight of the culture board and the need for liquid for culture medium and plant. Method according to Claim 1, characterized in that the culture tray is immersed in a basin (5) partially filled with liquid when registration of liquid demand. Method according to claims 1 and 2, characterized in that the culture tray, after taking up liquid, is lit up by the pool and again weighed by means of the sensor of the lifting device, which registers any need for additional liquid for saturation of the culture medium. Method according to claims 1-3, characterized in that the culture tray is returned to the culture shelf. Method according to claims 1-4, characterized in that a fertile plant with the cultivation board is removed from the cultivation shelf and removed from the device via the lyñ device and a conveyor (7), the pool being emptied of its liquid content before this operation. Method according to seas 1-5, characterized in that the pool emptied of water is caused to rotate half a turn with its rotatable shaft (6), the previous position of the pool being replaced by a conveyor (7), etc. on the surface of the cultivation boards to storage or directly to consumers, after which new cultivation trays are filled on the cultivation system with the aid of the conveyor and the shelter device. 7. A method according to claim 6, characterized in that new culture trays with culture medium, which contain embryos alternatively ün ün, cuttings or plants, are fed to the culture shelf of the culture system by means of the conveyor and ly fi device. Device connected to the method according to claims 1-7 and which device comprises the cultivation ridge (1) which are integrated with a cultivation system (3) which automatically moves the cultivation trays, characterized in that the cultivation trays by means of a ly fi device (4) are temporarily ly from the cultivation shelf. 527 520 "in (2) and which means comprises a sensor which senses the weight of the culture tray and the need for liquid for culture medium, the culture tray being submersible in a basin (5) partially filled with liquid and the culture tray being readable and usable with the pool. of the ly fi device and a conveyor (7) -