NL1037004C2 - GROWING DEVICE AND METHOD FOR GROWING PLANTS. - Google Patents

Description

Short description: Growing plant and method for growing plants.

DESCRIPTION

According to a first aspect, the present invention relates to a growing device for growing plants, comprising a liquid holder with a wall that defines a liquid space in which a liquid is accommodated in operation, and at least one plant holder with a further wall defining a growing space. for growing plants in operation in the growing room, wherein the further wall is at least partially vapor-permeable.

A known device for growing a plant comprises a container containing growing soil containing nutrients for the plant to be grown in the container. The plant and / or the soil is sprinkled with water from above. Any excess water can drain through holes provided in the bottom of the container.

In a known device for growing a plant according to the introduction, the plant is also grown in a container containing growing soil with nutrients for the plant. The known device furthermore comprises a water trough in which the holder is placed, the holder having on its underside a number of openings through which water can penetrate into the holder so that the growing soil present in the holder is moistened for the plant. A drawback of the above-described known device according to the introduction is that a considerable amount of water is required for growing a plant. It is therefore an object of the present invention to provide a device for growing plants, wherein considerably less liquid is required for growing the plants. Said object is achieved with the device according to the present invention, which is characterized in that the liquid space during operation is at least substantially closed off from the ambient air by the wall of the liquid container and by a vapor-permeable part of the further wall of the at least one plant container wherein the liquid and the vapor-permeable part of the further wall are mutually separated by a vapor layer. An advantage of the device according to the present invention is that a vapor-permeable portion of the wall of the at least one container is surrounded by a vapor layer that is at least substantially sealed from the ambient air, which vapor layer is present between the vapor-permeable portion and located in the fluid space. As a result, during operation the vapor layer will saturate with liquid vapor, or at least the relative humidity, or the vapor content in the vapor layer, will increase considerably, which vapor can penetrate through the vapor-permeable part of the wall into the culture space of the container. The amount of moisture absorption by the plant is completely regulated by the plant itself. Evaporation of liquid which, in the case of the above-described known device according to the introduction, is in contact with ambient air, is thus not an issue with the device according to the present invention. The liquid present in the liquid space thus fully benefits the plant, as a result of which considerably less liquid is required for growing the plant relative to the above-described known device. An additional advantage of the device according to the present invention is that the plant appears to grow considerably faster than plants grown in the above-described known devices. The reason for this is that plants are sensitive to both a shortage and a surplus of liquid supplied to the plant. Since the plant itself regulates moisture absorption, the amount of liquid supplied to the plant is thus optimal. A still further advantage is that the quality of the liquid is of secondary importance, since the liquid does not come into direct contact with the plant container, or at least cannot penetrate into the growing space. As a result, excellent salt water, such as sea water, can also be used. Waste water can also be considered, for example, as long as the waste water does not contain volatile substances such as, for example, chlorine.

The wall of the liquid container preferably comprises an opening 25 with a shape which is adapted to the shape of a part of the further wall of at least one plant holder which comprises a vapor-permeable part, for forming the liquid space in operation by closing part of the further wall of the at least one plant holder from the opening in the wall of the liquid holder. As a result, the liquid space at least substantially closed off from the ambient air is simply realized by placing the plant holder on or in an opening in the liquid holder.

The liquid container herein preferably further comprises a number of openings, each of which can be closed by means of at least one plant holder. Thus, with a single water layer in the liquid container, water vapor can be generated in the vapor layer sealed off from the ambient air for the purpose of cultivating a number of plants grown in separate plant containers, which close different openings. In this context, consideration may be given to providing a square container with a cover plate in which a matrix of openings is arranged. The openings can herein be suitable to be closable by means of one or by means of several plant holders. In this context, the liquid container is further preferably provided with a closing element for closing an opening in the absence of a plant holder. Thus, it is not necessary for each of the number of openings to be closed by a plant holder such that contact between the vapor layer in the liquid space and the outside air is prevented or at least minimized. The closing element can in this case be a separate cover or, for example, a valve connected to an opening which, in the presence of a plant holder, is in an open position and which, in the absence of a plant holder, is in a position closing the opening.

In a further favorable preferred embodiment, the liquid container comprises a pipe-shaped element through which liquid is forced in operation, wherein the openings are provided in a wall of the pipe. The advantage of forcing liquid through the tubular element is that this will prevent or at least greatly reduce any possible deposition of components present in the liquid, such as, for example, salt. Cleaning costs of the liquid container are thus limited. It is favorable here if the openings are provided in a higher-lying wall portion of the pipe. A separation of the vapor-permeable part of the further wall of the plant container and the liquid can thus be realized in a simple manner. Furthermore, it is favorable if the pipe-shaped element comprises a liquid supply and a liquid discharge, wherein the liquid supply and the liquid discharge are preferably situated below the liquid surface in the pipe-shaped element. Liquid can thus be forced through the tubular element, whereby any contact between the vapor layer and the outside air is effectively prevented.

In a simple and practical embodiment, the liquid container supports the at least one plant container. Plant holders can thus simply be changed, for example if the plant grown in the plant holder is ready for sale, for example.

It is also conceivable that the wall of the liquid container is attached to the further wall of the at least one plant container. In this case, the wall and the further wall, or the liquid container and the plant container, can be manufactured as a whole, or the wall of the liquid container can be permanently or permanently attached to the further wall of the plant container. Such a measure has particular advantage in, for example, the transport of growing devices with plants therein. By attaching the liquid container and the plant container to each other, it is prevented, for example by vibrating during transport, that the liquid space temporarily comes into contact with ambient air and thus the vapor-saturated vapor layer is lost.

In a practical embodiment, the at least one plant holder comprises a bottom wall that is at least partially vapor-permeable.

In a simple and cost-effective embodiment, the vapor-permeable part of the further wall of the at least one plant holder is a part of the further wall in which passages are arranged. Here, one can think of manufacturing a plant holder by means of injection molding, wherein a number of passages in the further wall of the plant holder are already provided in the mold.

According to a second aspect, the invention relates to the use of a fluid container in a culture device according to the first aspect of the present invention, characterized in that the fluid space in operation is at least substantially closed off from the ambient air by the wall of the fluid container and by a vapor-permeable part of the further wall of the at least one plant holder, wherein the liquid and the vapor-permeable part of the further wall are mutually separated by a vapor layer. Advantages of using such a liquid container are analogous to the advantages of the culture device according to the first aspect of the present invention.

According to a third aspect, the invention relates to a method for growing plants, comprising the steps of: a. Providing a liquid container with a wall that defines a liquid space and providing at least one plant container with a further wall that determines a growing space in which the plants are grown, wherein the further wall is at least partially vapor-permeable; b. supplying fluid to the fluid space.

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The method is herein characterized in that it comprises the step of: c. closing the liquid space through the wall of the liquid container and through a vapor-permeable portion of the further wall of the at least one plant container, at least substantially from the ambient air, wherein the liquid and the vapor-permeable portion of the further wall are mutually covered by a vapor layer separated. Advantages of such a method according to the present invention are analogous to the advantages of the culture device according to the first aspect of the present invention. The order of the steps mentioned, and in particular the order of steps b. and c. 10 is of secondary importance here. It is possible, for example by placing a plant holder on a liquid holder, to realize the vapor layer that is at least substantially closed off from the outside air, whereafter the liquid is introduced into the liquid holder.

The liquid is herein preferably at least substantially salt water. Naturally, the use of fresh water, such as rain water or tap water, is eminently suitable for use. However, it is also possible to use salt water since the liquid does not come into direct contact with the plant container, or at least cannot penetrate into the growing space, and thus the quality of the liquid is of secondary importance. Consequently, in addition to the use of salt water, waste water can also be envisaged, for as long as the waste water does not comprise volatile substances such as, for example, chlorine.

The present invention will be further elucidated on the basis of the description of preferred embodiments of breeding devices according to the invention with reference to the following figures: Figure 1 shows a cross-section in side view of a preferred embodiment of a growing device according to the present invention;

Figure 2 shows, in isometric view, a part of a part of a further preferred embodiment of a culture device according to the present invention; Figure 3 shows a cross-section in side view of a still further preferred embodiment of a breeding device according to the present invention.

Figure 1 shows a growing device 1 for growing a plant 2. Device 1 comprises a pot 3 and a water bowl 4. Pot 3 is round, 6 made of a plastic and has a bottom 31 which is provided with a number of holes 32 and as a result thereof is vapor-permeable. Furthermore, the pot 3 is filled with growing soil 33 which forms a support for a plant 2 contained therein. In pot 3, both one plant 2 can be grown simultaneously, or several plants included in pot 3, such as plant 2. If the cultivation of the plant (s) included in pot 3 is complete, it can be removed from pot 3, so that pot 3 can be used in growing a next plant or a number of following plants.

A vapor-permeable bottom can be provided as described above by providing the bottom with holes, or by, for example, selecting a porous material as material for the bottom. If a soil with holes is chosen, the size of the holes must be adjusted to, for example, the growing soil and, for example, the root size of the plant to be grown. The latter is to prevent or at least limit that roots grow through the holes to a large extent. It is also possible, for example, to provide a root-resistant (but vapor-permeable) cloth on top of the bottom with holes of the pot.

Pot 3 has a height and largest diameter of about 20 cm, the holes being round with a diameter of about 0.5 cm. The size of the pot is of course dependent on the size of the plant or plants to be grown.

Water bowl 4 is also round, has an open top and is made of plastic. The opening at the top of water trough 4 is here adapted to the shape of outer wall 34 of pot 3. More specifically, surfaces 43 of water trough 4 are designed such that they form an at least practically airtight seal with the wall 34 of pot 3, so that in the inner space of water trough 4 is provided with an air layer 41 at least substantially closed off from the ambient air. A water layer 42 is furthermore provided in the inner space of water basin 4. Air layer 41 thus forms a separation between water layer 42 and the bottom 31 of pot 3.

Because air layer 41 is sealed off from the ambient air, the air layer 41 will, as a result of the present water layer 42, become saturated with water vapor, or at least the relative air humidity will increase considerably. Air layer 41 can thus also be referred to as a vapor layer. This water vapor penetrates through holes 7 32 in the bottom 31 of pot 3 into the growing soil 33. The roots 21 of plant 2 hereby have the possibility of absorbing the amount of moisture required for plant 2. It appears that in practice the regulation of the amount of moisture absorption is completely determined by the plant itself. The consequence of this is therefore that plant 2 grows relatively quickly. Since the water layer 42 is sealed off from the ambient air, water that evaporates cannot escape directly into the ambient air. As a result, virtually all of the water from water layer 42 is absorbed by the plant 2, so that the level of water layer 42 drops only very slowly and the water is thus used very efficiently. Thus, first of all, very little water 42 needs to be used for growing plant 2, whereby the required amount of water can also be filled in water tank 4 at long intervals. In other words, supplying water to plant 2 every day or once every few days is therefore no longer necessary.

Since the water of the water layer 42 in the water tank 4 does not come into direct contact with the culture soil 33, the quality of the water is of secondary importance. As a result, excellent salt water, such as sea water, can also be used (water vapor from sea water does not contain salt). Waste water can also be considered, for example, as long as the waste water does not contain volatile substances such as, for example, chlorine.

It is further noted that the water layer 42 can also be included as a gel-shaped layer in the inner space 41 of the water basin 4. The use of such a gel-shaped layer is particularly relevant in the transport of plants. Supply of moisture to the plants remains guaranteed by the evaporation of water from the gel-shaped layer, while furthermore leakage of water from water basin 4 is no longer an issue, so that a vertical orientation of water basin 4 with pot 3 during transport is of secondary importance. . On the other hand, during long-term transport, efficient water use such as the above-mentioned dehydration of plants 2 can effectively prevent it.

Air layer 41 is of such a height that roots 21, if they were allowed to penetrate through holes 32, cannot reach water layer 42. This height depends on the type of plant present in pot 3. The situation of regulating moisture absorption by the plant itself is thus not disturbed and water layer 42 and air or vapor layer 41 are used in the most effective manner.

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It is furthermore advantageous if the walls of water container 4 are not porous, that is to say that the walls of water container 4 are preferably not vapor-permeable. The same applies to the walls of pot 3, of course with the exception of its bottom.

As an alternative to water basin 4 as shown in figure 1, it is also possible to envisage a water basin that is considerably larger and has a top side in which there are a number of openings in which pots such as pot 3 can be placed appropriately. Thus, the water layer present in the water trough can be used for supplying moisture to a number of plants such as plant 2. It is noted here that if not all openings in the water trough are closed with pots, these openings should be covered with, for example, a lid or by, for example, a valve, so that it is ensured that an air layer at least substantially closed off from the ambient air is created between the underside of the pots and the water layer present in the water trough, whereby this air layer can saturate with water vapor.

Although in Figure 1 a round container 4 and a round container 3 are divided, the shape of the container 4 and the container 3 is not important within the scope of the present invention. The tray 4 can, as already mentioned, have several openings. The individual openings can in this case be covered by both one and several pots 3. It is also possible within the scope of the present invention to provide the container 4 with a supply of water, wherein the supply opening is preferably located below the surface of the water layer 42 in container 4, so that any vapor escaping from the air layer 41 through the supply opening is out of the question. If the water supply is provided with a sensor included in tank 4 or a float, it can be realized in a simple manner that the water level in tank 4 remains at the same level. A water drain can also be provided, as a result of which it is possible to periodically flush the container 4 with water, for example in the context of cleaning activities. Furthermore, a humidity sensor can be provided in the air layer, for the purpose of monitoring the vapor content in the air layer. If the vapor content is too low, there is a risk of the plant drying out.

Figure 2 shows a part of a pipe 400, with a number of openings 402 being provided in the upper surface 401 of pipe 400. Pipe 400 is made of plastic. A pipe with a different cross-section than the one shown, for example round, of course also suffices fine. The geometry of opening 402 is adapted to a container suitable for growing a plant, such as the pot 3 shown in Figure 1, by providing such a pot 3 in all openings 402 of pipe 400 or by covering openings 402 in which no pot 3 is provided inside the pipe 400 an air layer 403 sealed off from the ambient air is created. A quantity of water can then be forced through pipe 400, wherein it is important that the height of the water layer 404 is not such that the pipe 400 becomes completely stuffed. Thus a situation similar to that of figure 1 arises, wherein air layer 403 saturates with water vapor for the purpose of cultivating the plants. The advantage of such a pipe 400 is particularly relevant if, for example, salt water is used. As a result of the continuous or periodic flow of pipe 400 with the salty water, salt deposition as a result of evaporation of water within the pipe will not occur, or at least to a considerably lesser extent, so that cleaning will no longer or at least considerably less. frequently necessary. The water supply and discharge are herein, as already described above, preferably below the surface of the water layer 404 in the pipe 400.

An alternative embodiment of water basin 4 according to figure 1 is shown in figure 3. Figure 3 shows a part of the earth's soil 50, wherein the earth's surface is indicated by reference numeral 52 and wherein the groundwater level is indicated by reference number 51. In the earth's soil 50 First of all, a hole has been made which extends below groundwater level 51, after which a vertical pipe 500 is placed in the hole. This results in a situation comparable to that of figure 1, wherein the water layer is now formed by a layer of ground water 53 at the bottom of pipe 500, and furthermore an air layer 54 sealed off from the ambient air is created by connecting the bottom of pot 3 on the upper end of pipe 500. This embodiment is particularly suitable for use in naturally dry areas such as desert areas.

In general, it holds for the air layer 41 that its temperature influences the vapor pressure. As the temperature of air layer 41 increases, the vapor pressure increases (more than proportionally) and the air layer can comprise more vapor, so more moisture is available for the plant to be cultivated. If a further increased moisture supply is temporarily desired for the plant, it is advantageous to heat the water layer 42 such that its temperature is higher than that of the air layer 41. Thus, the air layer is at least temporarily over-saturated with vapor. Therefore, a relatively large amount of moisture is temporarily available for the plant. Eventually the situation will stabilize and a saturated air layer 41 will arise, now at a higher temperature, with a higher vapor pressure. The heating of the water layer 42 can be effected, for example, by actively heating it or, for example, by supplying relatively warm water to the water layer.

10 1037004

Claims (11)

1. Cultivation device for growing plants, comprising a liquid holder with a wall that defines a liquid space in which a liquid is accommodated in operation, and at least one plant holder with a further wall that defines a growing space for growing in operation in the growing space plants, wherein the further wall is at least partially vapor-permeable, characterized in that the liquid space during operation is at least substantially closed off from the ambient air by the wall of the liquid container and by a vapor-permeable part of the further wall of the at least one plant holder, wherein the liquid and the vapor-permeable part of the further wall are mutually separated by a vapor layer. 2. Device as claimed in claim 1, characterized in that the wall of the liquid container comprises an opening with a shape adapted to the shape of a portion of the further wall of at least one plant container comprising a vapor-permeable portion, for forming the liquid space in operation by closing the opening in the wall of the liquid container by means of the part of the further wall of the at least one plant holder. 3. Device as claimed in claim 2, characterized in that the wall of the liquid container comprises a number of openings, each of which can be closed by means of at least one plant container. Device as claimed in claim 3, characterized in that the liquid container comprises a pipe-shaped element through which liquid is forced in operation, wherein the openings are provided in the wall of the pipe. Device according to one of the preceding claims, characterized in that the liquid container supports the at least one plant container. Device according to one of the preceding claims, characterized in that the wall of the liquid container is attached to the further wall of the at least one plant container. Device as claimed in any of the foregoing claims, characterized in that the at least one plant holder comprises a bottom wall that is at least partially vapor-permeable. Device as claimed in any of the foregoing claims, characterized in that the vapor-permeable part of the further wall of the at least one plant holder is a part of the further wall in which passages are arranged. 9. Use of a liquid container in a culture device according to any one of the preceding claims, characterized in that the liquid space in operation is at least substantially closed off from the ambient air by the wall of the liquid container and by a vapor-permeable part of the further wall of the at least one plant container, wherein the liquid and the vapor-permeable part of the further wall are mutually separated by a vapor layer. 10. Method for growing plants, comprising the steps of: a. Providing a liquid container with a wall that defines a liquid space and providing at least one plant container with a further wall that defines a growing space in which the plants are grown wherein the further wall is at least partially vapor-permeable; and 15 b. supplying liquid to the liquid space, characterized in that the method further comprises the step of: c. closing the liquid space through the wall of the liquid container and through a vapor-permeable part of the further wall of the at least one plant container, at least substantially from the ambient air, wherein the liquid and the vapor-permeable part of the further wall are mutually covered by a vapor layer separated. A method according to claim 10, characterized in that the liquid is at least substantially salt water. 25,137,304