NL2018858B1 - Cultivation system - Google Patents

Abstract

Cultivation system for growing crops in a growing medium, comprising a heat-conducting growing tray for growing the crops in the growing medium therein and heat exchange means connected to the growing tray and adapted to adjust the temperature of an inner surface of the growing tray in order to adjust the temperature of the growing tray adjust the growing medium.

Description

Cultivation system

The present invention relates to a growing system for growing crops in a growing medium.

In soil-bound cultivation, also known as open ground cultivation, the growing medium in which the crops are grown, in this case soil, is usually steamed several times a year to disinfect them in order to make them suitable for cultivation.

Furthermore, in the soil-bound cultivation of various crops, the soil is artificially maintained by means of pipes filled with hot or cold water in the soil in order to control the temperature near the bulb, tuber or root of the crop crops in order to promote the growth and development of these crops. to optimize.

A disadvantage of steaming the soil, however, is that it requires a lot of energy and causes undesirable disturbances in the greenhouse climate, such as condensation.

Moreover, the heat from the introduced steam remains in the soil for a long time, which necessitates cooling of the soil after steaming in order to obtain a soil temperature desirable for cultivation. As a result, an undesirably large amount of energy is used for the required optimization of the greenhouse climate and cooling of the soil after steaming. Moreover, this optimization and cooling is at the expense of the time that can be grown; in other words, the lead time is thereby undesirably extended.

Furthermore, despite the temperature control of the soil described above, there are still undesirable differences in growth and quality between the crops grown in the soil mentioned.

It is an object of the invention to eliminate or at least reduce the abovementioned disadvantages of the known techniques.

To this end, the present invention provides a cultivation system of the type mentioned in the preamble with the special feature that it comprises a heat-conducting cultivation tray for growing therein the crops in the culture medium and heat exchange means connected to the culture tray and adapted to control the temperature of an inner surface of adjust the culture container to adjust the temperature of the culture medium. The special advantages of such a cultivation system are as follows.

On the one hand, by making use of a heat-conducting cultivation container with associated heat exchange means, heat is transferred very locally to the crops, so that little energy is lost to the greenhouse environment and beyond. Moreover, the use of a cultivation tray means that soil steaming is no longer necessary, since the cultivation medium, preferably a natural or artificial substrate, can be replaced in a simple manner prior to a new cultivation. In this way the amount of energy used for the desired greenhouse climate and the throughput time of the cultivation are drastically reduced.

On the other hand, it has surprisingly been found that the mutual uniformity in the growth and cultivation quality of the crops to be grown and subsequently harvested has increased considerably with the cultivation system according to the present invention. In that connection, it is assumed that in soil-bound cultivation mutual equality of temperature at the growing point of the bulbs, tubers or roots of the crops to be grown in the soil is difficult to achieve. This would be caused by the fact that planting machines are used that cause the tubers to fall at a certain distance from the heating or cooling pipes arranged in the ground for heating and / or cooling the ground. If a bulb or tuber comes to lie 1 cm farther from a pipe than another bulb or tuber just next to the pipe, a mutual temperature difference of approximately 0.5 ° C would arise at the growing points of the bulbs or tubers. Mutual differences in location relative to the pipe up to 3 cm, this would correspond to a mutual temperature difference of 1.5 ° C, are not unusual. The result of this is a delayed budding of the bulbs or tubers that are further away from the line and, consequently, a delay in flowering, which leads to an undesired amount of afterglow in the final phase of the cultivation. As a result, the exposure period must be extended in order to obtain a high quality of the last branches. Moreover, a relatively large amount of time and labor is required for the later harvest up to and including the last branch.

In other words, the cultivation system according to the present invention allows for more accurate control of the temperature at each bulb or tuber. as a result of which mutual equality in growth and development increases, resulting in an improved average quality of the crop to be harvested and an increased yield of harvest. In other words, due to the heat-conducting properties of the cultivation tray and the heat exchange means connected thereto, the temperature of the heat exchange means is distributed very uniformly over at least the inner surface of the cultivation tray, so that the cultivation medium is spatially heated or cooled to the desired extent growing temperature, which results in a very uniform temperature distribution in the growing medium, resulting in a high uniformity in the growing quality of the crops to be grown and subsequently harvested. Particularly in the case of root vegetables, such as freesias, which are usually grown outdoors, such a uniformity of the temperature of the growing medium provides a special advantage. Moreover, a further energy saving as well as an increase of the cultivation capacity is also realized, since respectively the above-mentioned extension of the exposure period can be omitted and the crops can be harvested almost simultaneously.

In a preferred embodiment of the invention, the cultivation system further comprises a temperature sensor arranged in the culture medium for measuring the temperature of the culture medium and a controller for controlling the heat exchange means on the basis of the temperature of the culture medium. A special advantage of such a temperature sensor and controller is that it keeps the temperature of the growing medium very accurately at the desired temperature, whereby the growth of the crops is further optimized, resulting in an improved average quality of growing and then harvesting. crop and an increased harvest yield.

In a preferred embodiment, the cultivation system further comprises a dimensioned heat-insulating holder which corresponds substantially to the cultivation tray, in which the cultivation tray is at least partially arranged. In the most favorable case, all the cold or heat supplied by the heat exchange means is transferred to the bulbs, tubers or roots. Therefore, cold or heat losses, for example cold or heat transfer to the air outside the cultivation container, must be prevented. Such a heat-insulating container has the special advantage that it is prevented that the heat to be transferred via the cultivation tray between the heat exchange means and the cultivation medium flows away to the environment of the cultivation tray. This increases the efficiency of energy transfer, whereby the temperature of the growing medium can be kept even more accurately over the entire growing medium at the desired temperature. Moreover, the air present between the holder and the cultivation container is uniformly heated or cooled spatially, so that a constant climate is created in the vicinity of the cultivation container. In this way, the constancy of the temperature of the cultivation bin is further optimized.

In a preferred embodiment, the heat exchange means comprise a heat-conducting conduit and a fluid to be passed therethrough, the conduit being in heat-conducting contact with the cultivation trough. Such an embodiment has the advantage that pipes, often already present in greenhouses, connected to ground cooling and heating systems can be used in the cultivation tray according to the present invention connected as heat exchange means. The heat-conducting conduit is preferably made of a metal. More preferably, it is made of aluminum or copper because of the excellent heat-conducting properties of these materials. As a result, the cultivation tray can be brought to the desired temperature in an accurate manner or kept at that.

In a preferred embodiment, the cultivation tray is formed such that it comprises a cavity corresponding to the conduit for receiving the conduit therein and the conduit is arranged in the cavity. Because of such a cavity corresponding to the pipe and the pipe arranged therein, the pipe is in contact with the cultivation trough over a part of its outer surface, whereby the heat transfer takes place in a very efficient manner. This again contributes to precise control of the target temperature to be uniformly distributed over the growing medium. Moreover, the said cavity and the placement of the conduit therein have the advantage that it is possible to feed the conduit continuously into the cultivation trough, which results in a simple, elegant and rapid embodiment.

In a preferred embodiment, the line is arranged between the holder and the cultivation tray. A special advantage hereof is that the heat transfer between the pipe and the growing medium via the growing bin is very efficient, since hardly any or no heat transfer can take place between the pipe and the immediate vicinity of the pipe as a result of the adjacent heat-insulating container.

In a preferred embodiment, the line is arranged at least substantially centrally relative to a distribution of the crops. A particular feature of such a central location of the conduit is that the spread of the roots, bulbs or tubers of the crops to be grown relative to the conduit is minimized, so that the uniformity of the distribution of the temperature at said bulbs, tubers or tubers roots is optimal.

In a preferred embodiment, the holder comprises an inner shell, an outer shell and one or more channels filled with air between the inner shell and the outer shell. A special advantage is that air is a good thermal insulator and also has a low specific gravity, so that the container is very well thermally insulating and at the same time lightweight, which is eminently advantageous in the production, distribution, installation and uninstallation of the cultivation system of the present invention. The container is preferably provided between the inner and outer shell thereof with ribs or the like, which form the said air ducts or air compartments. A special advantage of such stiffening elements is that the holder has such a strength that it can be loaded. In this way the cultivation trays according to the present invention can be used as a guide for, for example, a transport system for transporting a device for planting bulbs and tubers and / or the like over the cultivation tray.

In a preferred embodiment, the cultivation system further comprises a thermal buffer for storing thermal energy to be coupled to the heat exchange means. A special advantage of such a thermal buffer is that heat released by the culture medium to the heat exchange means can be used at a later stage to heat the culture medium, thereby saving even more energy.

In a preferred embodiment, the cultivation container is provided on its underside with drainage holes for draining drain water therethrough and the container is arranged on a slope. In this way nutrient water that is not absorbed by the crops is discharged in a controlled manner, whereby the groundwater and / or surface water is prevented from being contaminated by crop growth promoting nutrients present in the nutrient water.

In a preferred embodiment, the cultivation system furthermore comprises hoses arranged close to the cultivation medium and adapted to provide the cultivation medium with or without droplet of nutrient water for the crops. Such drip tubes, also called drippers, guarantee an uninterrupted and constant delivery of a desired amount of nutrient water, so that the climate in the growing medium is optimized for the growth of the crops to be grown.

In a preferred embodiment, the growing medium comprises a coconut mixture. A coconut mixture is pre-eminently suitable for growing root vegetables, such as freesias, in a cultivation system according to the invention. It is noted that the growing medium can also be another crop-specific substrate or mixture of substrates. Examples thereof are (Baltic) peat, rock wool, soil, shredded paper, perlite, shells and the like or a mixture thereof.

In a preferred embodiment, the heat-conducting conduit comprises a hose made of tylene. Such nylon hoses are already used in soil-bound cultivation because of the advantage that they do not harm the environment. An advantage of the use of such tyleen hoses in the cultivation system according to the invention is therefore that they are generally already available in current cultivation systems, whereby they can be reused for the cultivation system according to the invention. In addition, they are flexible and at the same time have sufficient heat-conducting properties, which on the one hand facilitate in the installation of the cultivation system and on the other hand are suitable for the intended precise control of the temperature uniformly distributed over the cultivation medium. It should be noted, incidentally, that due to the surface contact of the pipe with the cultivation container, sufficient heat transfer takes place via the cultivation container. despite the moderate heat conductivity of tylene.

In a preferred embodiment, the cultivation tray is made of metal, preferably of aluminum. Metal and eminently aluminum has an excellent thermal conductivity, as a result of which the heat transfer between the growing medium and the heat exchange means is very efficient, whereby the temperature of the growing medium can be kept very accurately over the entire growing medium at the desired temperature. Moreover, aluminum has a relatively low specific gravity relative to other metals, so that a lightweight cultivation container can be manufactured, which is eminently advantageous in the production, distribution, installation and uninstallation of the cultivation system according to the present invention. In addition, aluminum is corrosion-resistant, so that a cultivation container made of aluminum is durable.

In a preferred embodiment, the cultivation system furthermore comprises a lid to be arranged on the cultivation bin which is provided with an opening corresponding to a cross-sectional shape of a pot of a pot crop to be grown, such that the pot can be inserted through the opening at least partially into the cultivation bin is. A special advantage of such a lid is that the cultivation system is also suitable for growing pot crops in pots. This implies that the cultivation system can be used as a so-called ebb tidal system, wherein the container is filled with feed water for the said pot crops during a flood period of, for example, 5 to 10 minutes and subsequently emptied by draining off the non-absorbed part of the said feed water. In the subsequent ebb period, the heat-conducting cultivation tray and the heat exchange means connected therewith ensure uniform heating or cooling of the air in the cultivation tray in order to keep the air very constant at the optimum growth temperature for the crop.

The opening is preferably dimensioned such that the pot does not touch the bottom of the cultivation tray when the pot is arranged in the cultivation tray. In this way it is achieved that the part of the pot that is present in the cultivation bin is completely surrounded with the said conditioned air, which benefits the uniformity of the temperature distribution of this air. Furthermore, in this way the pot closes the opening so well that a substantially closed space is created in the cultivation bin, which ensures that the climate in the said space can be kept as constant as possible. Moreover, because of the said size of the opening, the pot hangs as it were in the lid, as a result of which it is arranged mechanically in a stable manner in the cultivation container and therefore cannot fall over, which is important if the crop starts to grow and the center of gravity of the crop relative to it is from the cultivation bin will be higher.

The present invention is further elucidated with reference to the following figures, which show preferred embodiments of the cultivation system according to the present invention and are not intended to limit the scope of the invention in any way, wherein: figure 1 is a perspective view of an embodiment of the cultivation system according to the present invention; Figure 2 shows a cross-sectional side view of the cultivation system shown in Figure 1; and figure 3 shows a perspective view of an embodiment of the cultivation system according to the present invention.

Figures 1 and 2 show a preferred embodiment of a cultivation system 100 according to the invention. The cultivation system 100 comprises a thermally conductive cultivation tray 101 and a thermally insulating container 102 in which the cultivation tray 101 is arranged. The cultivation tray 101 is formed on its underside such that it forms a cavity 103 for receiving therein a conduit 104, in this case a tylene hose, through which a cold or warm fluid, that is to say a gas or a liquid such as water, is guided to cool or heat the cultivation tray 101 respectively. The cavity 103 is formed corresponding to the line 104, so that the line 104 makes good heat-conducting contact with the cultivation tray 101. Furthermore, the cultivation tray 101 is made entirely of aluminum, so that the heat absorbed or released by the line 104 from or sewn on. inner surface 105 of the cultivation tray 101 is guided, that the inner surface 105 of the cultivation tray 101 has the same temperature everywhere, such that the culture medium to be introduced into the culture tray 101 has the same optimum temperature everywhere for the development of the bulbs and tubers of plantation to be planted in culture medium the crop to be grown. It is noted that the cultivation tray 101 can be additionally or in an alternative embodiment or also or alternatively made of a material other than aluminum with a high thermal conductivity, as long as the distribution of the temperature to be applied along at least the inner surface of the cultivation tray 101 is uniform .

As stated, the cultivation tray 101 is further placed in a thermally insulating container 102 to thermally isolate the cultivation tray 101 from its immediate environment, which benefits the efficiency of the heat transfer between the fluid and the culture medium and thereby the accuracy of the adjustment and keeping the temperature close to the bulb, tuber or root of the crop to be grown constant. For the purpose of its placement in the holder 102 along its upper edges, the cultivation tray 101 is converted to rest on upper edges of the holder 102. The holder 102 is made of a plastic with a low thermal conductivity. Furthermore, the holder 102 is not solid, but is provided with air ducts 106, which extend in the longitudinal direction of the holder 102. The air ducts 106 contribute - in addition to the thermally insulating properties of the material of the container 102 - to the insulating capacity of the container 102. The air ducts 106 are limited, in other words formed by ribs 108 which provide rigidity to the container 102 , whereby the holder 102 can be (heavily) loaded.

In the embodiment of figures 1 and 2, the line 104 is placed between the holder 102 and the cultivation tray 101 in the cavity 103 formed therein. A special advantage of this is that the heat transfer between the pipe 104 and the growing medium via the cultivation bin 101 is very efficient, since there is hardly any or no heat transfer between the pipe 104 and the immediate surroundings of the pipe 104 due to the adjacent heat-insulating container 102. can take place. The dimensions and shape of the cultivation tray 101, the holder 102 and the conduit 104 are furthermore such that they fit well into each other and can therefore be installed in and onto each other in a simple manner. The conduit 104 shown is a hose made of tylene. An advantage of using such tyleen hoses is that they are generally already available in current cultivation systems, whereby they can be reused for the cultivation system 100. In addition, they are flexible and at the same time have sufficient heat-conducting properties, which on the one hand facilitate in the installation of the cultivation system 100 and on the other hand are suitable for the intended precise control of the temperature to be distributed in the cultivation tray 101 to be applied to the cultivation tray 101. Incidentally, pipe 104 is arranged centrally with respect to the cultivation bin 101 and therefore centrally with respect to the distribution of the crops grown in the cultivation bin 101, so that the spread of the roots, bulbs or tubers of the crops to be grown relative to the pipe is minimized. results in an optimum uniformity of the distribution of the temperature at the said bulbs, tubers or roots of the crops.

Furthermore, the cultivation tray 101 is provided on its underside with drainage holes 107 for draining drainage water therethrough and the holder 102 is arranged on a slope. In this way nutrient water that is not absorbed by the crops is discharged in a controlled manner, thereby preventing the groundwater and / or surface water from becoming contaminated by crop growth promoting nutrients present in the nutrient water.

Figure 3 shows a preferred embodiment of the cultivation system 100, wherein a lid 110 is arranged on the cultivation tray 101. The cover 110 is provided with a plurality of openings 112, which is formed corresponding to a cross-sectional shape of pots 114 of pot crops 116 to be grown, such that the pots 114 are (partially) arranged in the cultivation tray 101 through the openings 112. The lid 110 allows the cultivation of pot crops 116 in pots 114 with the cultivation system 100 in this way. This implies that the cultivation system 100 can be used as a so-called ebb tidal system, wherein the holder 102 is filled with feed water for the pot crops 116 during a flood period and subsequently emptied by draining off the non-absorbed part of the said feed water . In the subsequent ebb period, the heat-conducting cultivation trough 101 and the line 104 in contact therewith ensure uniform heating or cooling of the air in the cultivation trough 101 so as to keep the air very constant at the optimum growth temperature for the crop 116.

Openings 112 are dimensioned such that the pots 114 do not touch the bottom of the cultivation tray 101 when the pots 114 are arranged in the cultivation ball. There is therefore a layer of air 113 between the pots 114 and the cultivation tray 101. In this way it is achieved that the portions of the pots 114 which are located in the cultivation tray 101 are completely surrounded with the said conditioned air, which benefits the uniformity of the temperature distribution of this air.

It is noted, incidentally, that the cultivation system according to the present invention, which is embodied in Figures 1 to 3 as inter alia an elongated cultivation tray and an elongated holder, can be dimensioned and shaped in many ways.

The present invention is not limited to the embodiments shown, but also extends to other embodiments that fall within the scope of protection of the appended claims.

Claims (16)

A cultivation system for growing crops in a growing medium, characterized by a heat-conducting growing tray for growing the crops in the growing medium therein and heat exchange means connected to the growing balls and adapted to adjust the temperature of an inner surface of the growing tray in order to adjust the temperature of an inner surface of the growing tray. adjust the temperature of the growing medium. Cultivation system according to claim 1, further comprising a temperature sensor arranged in the culture medium for measuring the temperature of the culture medium and a controller for controlling the heat exchange means on the basis of the temperature of the culture medium. 3. Cultivation system as claimed in claim 1 or 2, further comprising a dimensionally insulating heat-insulating container corresponding substantially to the cultivation tray in which the cultivation tray is at least partially arranged. Cultivation system as claimed in claim 1, 2 or 3, wherein the heat exchange means comprise a heat-conducting conduit and a fluid to be passed therethrough, the conduit being in heat-conducting contact with the cultivation trough. 5. Cultivation system according to claim 4, wherein the cultivation tray is formed such that it comprises a cavity corresponding to the conduit for receiving the conduit therein and wherein the conduit is arranged in the cavity. 6. Cultivation system according to claim 4 or 5, wherein the line is arranged between the holder and the cultivation tray. 7. Cultivation system according to one of claims 4 to 6, wherein the line is arranged washed at least substantially centrally relative to a distribution of the crops. The cultivation system according to any of claims 3 to 7, wherein the holder comprises an inner shell, an outer shell and one or more channels filled with air between the inner shell and the outer shell. 9. Cultivation system according to one of the preceding claims, further comprising a thermal buffer for storing thermal energy to be coupled to the heat exchange means. 10. Cultivation system as claimed in any of the foregoing claims, wherein the cultivation tray is provided on a underside thereof with drainage holes for draining drain water therethrough and the container is arranged on a slope. 11. Cultivation system as claimed in any of the foregoing claims, further comprising hoses arranged close to the growing medium and adapted to provide the growing medium with or without droplet of nutrient water for the crops. 12. Cultivation system according to one of the preceding claims, wherein the growing medium comprises a coconut mixture. Cultivation system according to one of the preceding claims, wherein the heat-conducting pipe comprises a hose made of tylene. 14. Cultivation system according to one of the preceding claims, wherein the cultivation tray is made from metal, preferably from aluminum. 15. Cultivation system according to one of the preceding claims, further comprising a lid to be arranged on the cultivation bin which is provided with an opening corresponding to a cross-sectional shape of a pot of a pot crop to be grown, such that the pot is at least through the opening can be partially inserted in the cultivation bin. 16. Cultivation system according to claim 15, wherein the opening is dimensioned such that the pot does not touch the bottom of the cultivation tray when the pot is arranged in the cultivation tray.