NL2010291C2 - FARMING FLOOR SYSTEM. - Google Patents

Description

FARMING FLOOR SYSTEM

The invention relates to a cultivation floor system with a floor on which plant holders are placed. The cultivation floor system comprises a watertight basin and a water-permeable structure in the basin. The water-permeable structure has a permeable top cloth that forms the floor on which plant holders are placed. The structure further has one or more water-retaining layers, for example of granular material, such as, for example, of lava rock. The permeable topcloth has a high porosity with small pores. Preferably, as also in known systems, the top cloth is a woven top cloth with small pores between the yarns of the top cloth.

The system further comprises a water installation that is adapted to supply water so that water is available for the plants in the plant holders, for example a sprinkling installation or, as is preferred in the context of the invention, an ebb / flood water installation.

Various embodiments of cultivation floor systems according to the preamble of claim 1 are known from the prior art. For example, an ebb / flow water installation, in which one or more layers of granular material is provided, a capillary mat on top of the top layer of granular material (also for stabilization), and on top the top cloth.

Occasionally, undesirable effects come to the fore in the application of such cultivation floor systems, in particular in greenhouse applications.

For example, a problem is that the topsheet can become contaminated / clogged up undesirably due to algae growth. As a result, unwanted cleaning of the top cloth is often required, which is labor-intensive.

Another problem concerns the climate in the greenhouse, where people would sometimes like to have a lower moisture percentage than can be achieved without excessive removal of air from the greenhouse (and associated energy loss).

The invention has for its object to provide an improved cultivation floor system and cultivation floor therefor, with which one or more of the aforementioned problems can be solved.

The invention provides a cultivation floor system according to the preamble of claim 1, characterized in that a perforated film is made between the permeable top cloth on the one hand and the one or more water-retaining layers on the other hand and made of non-permeable film material provided with distributed perforations such that the film reduces the free water evaporation surface from the water-retaining layer or layers, preferably reduces at least 50%, more preferably reduces at least 90%.

The invention is based on the insight that, for example, a granular layer or another type of water-retaining layer, even when the water has flowed out of the basin, retains a considerable amount of water. Due to the (usually heated) climate in the greenhouse (or possibly by heating in the cultivation floor itself), part of that water will want to evaporate and rise through the permeable structure and the permeable top cloth to subsequently make the air in the greenhouse more humid.

The invention is based on the insight that evaporation in known floors takes place to an undesirable extent. As a result, for example, the effect regularly occurs that the top cloth always remains moist, because the drying from above is effectively undone by the unimpeded rising evaporation moisture. This offers ideal conditions for algae growth on and in the top cloth, which therefore becomes dirty and possibly clogged.

The same rising water vapor also contributes to the moisture percentage in the air in the greenhouse, so that the grower cannot achieve a low percentage if desired unless the air is replaced by drier air.

The invention provides for the use of a film which is in itself dense but which is preferably provided with relatively large perforations and which substantially reduces the free evaporation surface. As a result, water that has remained in the one or more aqueous layers of the structure can evaporate much less easily. Furthermore, that vapor only comes up at the location of the perforations in the foil, as a result of which drying of the top cloth can easily occur in surface areas between those perforations.

With an ebb / flood water installation, the size of the perforations is preferably chosen such that the perforations do not impede a possible flow with water in an ebb / flood water installation. For example, perforations with a diameter that is between 0.5 mm and 12 mm are provided. Preferably the smallest diameter is at least 1 mm or more preferably 2 mm. For example perforations with a diameter of 1.5 mm that are at least 4 mm apart or more preferably perforations with a diameter between 7 and 11 millimeters that are between 30 and 60 mm apart.

For example, the distance between adjacent perforations in the foil, or between groups with smaller perforations, is at least 10 mm, resulting in easy dry zones in the top cloth.

In a practical embodiment, a perforated film is provided which is made of impermeable film material which is provided with distributed perforations with an average opening surface of between 0.75 mm 2 and 108 mm 2, the perforations preferably constituting at most 10% of the surface , possibly at most 5% of the surface.

In a variant, the perforations are small, for example between 50 and 200 micrometres, which variant is not or hardly suitable, in particular for ebb / flood water installations, but possibly with other water supply installations, such as drippers or sprinklers.

In an advantageous embodiment, the perforated film is a single-layer film, for example of plastic. Because the top cloth will as a rule be UV-resistant, and as a rule not transparent, this foil does not have to be particularly UV-resistant.

The perforated film is preferably located as high as possible in the water-permeable structure, but under the topsheet. So, for example, the top cloth is directly on top of the perforated foil.

In a variant, hydraulic connection between plants via the cultivation floor is considered important. In that case, a capillary mat can be provided directly under the top cloth, which capillary mat has a capillary action in the vertical direction and in the horizontal direction, and below that the perforated foil, for example with one or more layers of water-containing material underneath, for example of granular material .

For example, a concrete basin is provided, on which lies a capillary mat on the concrete with the perforated foil on top and on top the top cloth. This can be done in combination with an ebb / flood water installation, so that the water periodically rises above the top canvas. A second, thin, capillary mat can optionally be provided between the perforated foil and the top cloth to realize the aforementioned mutual water-bearing connection between plant holders if this is considered important. The underlying, possibly thicker, capillary mat then serves as an aqueous layer.

In a more complex embodiment, the topsheet rests on a compressible mat with an open structure, which compressible mat is locally compressible under the weight of each plant container, with non-compressed areas of the mat showing no capillary action and compressed areas providing a hydraulic connection between the plant container and the one or more water-retaining layers, wherein the compressible mat is on top or below the perforated film and wherein the one or more water-retaining layers are lower.

In this embodiment, the topsheet is, as it were, kept at an extra distance from the one or more water retaining layers in the non-compressed areas, and due to the airy composition of the compressible mat, the topsheet can easily dry in those places. Where the compressible mat is compressed under the weight of the plant holder, there is a hydraulic connection so that the plant can be supplied with water.

If the perforated film is below the compressible mat, which is preferred, this film prevents or impedes that moisture vaporizing from the water-retaining layer or layers can get into that compressible mat. Due to the reduced moisture supply from below, a relatively dry climate can arise in the non-compressed parts of the mat.

In a possible variant of a floor with a compressible mat, the perforated film lies on a capillary mat which has capillary action in the horizontal direction and in the vertical direction, for example a non-woven mat of fibrous elements, for example a compacted non-woven mat. As a result, moisture transport in the horizontal direction is also possible under the foil, for example from plant to plant.

In a preferred embodiment an ebb / flood water installation is provided which is arranged for effecting an alternate supply of water to the cultivation floor and drainage of water from the cultivation floor, which water installation comprises: - one or more irrigation pipes in the basin, which irrigation pipes have multiple outlets along their length allowing water to flow out of the one or more irrigation lines, the one or more irrigation lines being covered by the water permeable structure.

The invention also relates to a method for growing plants, for example in a greenhouse, wherein use is made of a cultivation floor system according to the invention.

The invention also relates to a method for growing plants, preferably in a greenhouse, wherein use is made of a cultivation floor system according to the invention, and wherein the perforated film is dimensioned with a free evaporation surface of water from the water-retaining layers such as that at least one of the following effects is achieved: - drying of the top cloth during periods in which the water basin has been emptied such that algae growth on / in the top cloth is prevented / prevented; - reduction of the percentage of moisture in the air in the greenhouse by reducing the evaporation of water from the layers retaining one or more water; - maintaining a desired humid climate in the one or more water retaining layers in view of a biological condition in those one or more retaining layers.

Plastic pots, for example provided with holes at the bottom, are used as plant holders, but other plant holders are also known. For example, the pot is of porous and / or biological material, such as coconut, or no pot is present and the plant container is, for example, a block of growth substrate, for example of rock wool or the like.

The invention will be explained in more detail below with reference to the drawing. Fig. 1 shows diagrammatically, cut-away, a cultivation floor installation according to the invention, - Fig. 2 shows in cross-section diagrammatically the construction of a cultivation floor according to the invention, - Fig. 3 schematically shows an example of a perforated foil used in a cultivation floor installation according to the invention. invention, - Fig. 4 is a diagrammatic sectional view of the construction of an alternative cultivation floor according to the invention.

Figure 1 shows a cultivation floor system and a floor 1 on which plant holders 2 are placed. The cultivation floor system comprises a watertight basin 3.

A water-permeable structure is present in the basin 3, which structure has a permeable top cloth 4 which forms the floor on which plant holders are placed.

The structure further comprises one or more water-retaining layers, here a single layer 5, here - as is preferred - of granular material.

An ebb / flood water installation is further provided which is adapted to supply water so that water is available for the plants in the plant holders 2.

The water installation comprises one or more irrigation pipes 6 in the basin 3, which irrigation pipes have several outflow openings along their length that allow water to flow out of the one or more irrigation pipes, the one or more irrigation pipes being covered by the water-permeable structure.

A water storage facility 7, for example a storage pond or an underground water storage facility, is provided from which water can be pumped out via pump 8 to supply water to the basin 3, for example until a water level above the topsheet 4 is reached. After this "flood situation" has existed for a sufficiently long time, the water is allowed to flow away via the pipes 6 to the storage 7. A valve assembly 9 can be provided for controlling the desired supply of water to the basin and discharge from the basin 3.

The water-containing layer 5 will remain wet even when the water has flowed out of the basin 3 and thus retain water.

The topsheet 4 is permeable with a relatively high porosity with small pores. Preferably, there is a woven top cloth, for example of suitable plastic yarn, with relatively small pores between the yarns of the top cloth 4. The top cloth is preferably UV-resistant and also wear-resistant, for example suitable for driving over with light vehicles.

Figure 2 shows in cross section, schematically and not to scale, the structure of a cultivation floor in the system according to the invention.

Herein, the top cloth 4 lies directly on top of a perforated foil 10 with perforations 11, so that between the permeable top cloth 4 on the one hand and the water-retaining layer 5 on the other, a perforated foil is made which is made of impermeable foil material which is provided with distributed perforations, such that the film reduces the free evaporation surface of water from the water retaining layer 5, preferably at least 50%, more preferably at least 90%.

In this example, as an optional aspect, a capillary mat 15 is furthermore provided which has capillary action in the horizontal direction and in the vertical direction, for example a non-woven mat of fibrous elements, for example a compacted non-woven mat. As a result, moisture transport in the horizontal direction is also possible under the foil, for example from plant to plant. That mat 15 here lies under the perforated foil, directly on the granular layer 5. The mat 15 preferably also forms a stabilizing mat on top of the granular layer 5.

Alternatively, but less advantageously, the mat 15 lies between the top cloth 4 and the perforated foil 10.

The foil 10 is sealed as such, and therefore does not allow water and water vapor to pass through except at the location of the perforations in said foil 10.

The film thus forms, as it were, a blockage, albeit not perfect, for water that will want to evaporate from the layer 5 through the (usually heated) climate in the greenhouse (or possibly through heating in the cultivation floor itself) and through the permeable structure and the permeable top cloth wants to rise.

The film 10 reduces the free evaporation surface considerably, as it were. As a result, water that remains in the aqueous layer 5 can evaporate much less easily. Furthermore, that vapor only comes up at the location of the perforations in the foil 10, as a result of which drying of the top cloth 4 can easily occur in areas between those perforations.

The size of the perforations 11 is preferably chosen such that the perforations do not impede a possible flow with water in an ebb / flood water installation.

For example, perforations 11 with diameters between 1 mm and 12 mm are provided, or perforations with corresponding surface dimensions if a non-round shape is chosen.

For example, the distance between adjacent perforations 11 in the foil 10, or between groups with smaller perforations, is at least 10 mm, whereby easy dry zones are created in the topsheet 4.

In a practical embodiment, a perforated foil 10 (see figure 3) is provided which is made of impermeable foil material which is provided with distributed perforations 11 with an average opening of between 0.75 mm 2 and 108 mm 2, the perforations preferably being at least no more than 10% of the surface, possibly no more than 5% of the surface.

In an advantageous embodiment, the perforated film 10 is a single-layer film.

Figure 4 shows a more complex embodiment in which the top cloth 4 lies on a compressible mat 20 with an open structure.

This compressible mat 20 is locally compressible under the weight of each plant holder 2, which is shown schematically in Figure 4.

In the non-compressed areas of the mat 20, that mat 20 has no capillary action. In the compressed areas under plant holders 2 there is indeed a hydraulic connection, partly or entirely with capillary action, between the plant holder 2 and the layers or water-retaining layers 5.

The compressible mat 20 here lies, as is preferred, on top of the perforated film 10, and the one or more water-retaining layers 5 lie below the perforated film 10. In this way the film forms a reduction of the free evaporation surface so that water vapor is impeded. to take off and to enter the compressible mat. This is only possible at the location of the perforations 11, not in the vast majority of the surface of the film 10. As a result, also in the compressible mat, at the location of the dense film, there is a relatively dry climate. This contributes to the prevention of algae growth in or on the top cloth, and also contributes to a reduction of the moisture percentage in the greenhouse.

In this embodiment, the top cloth 4 in the non-compressed areas of the mat 20 is, as it were, kept at an extra distance from the one or more water-retaining layers 5, and due to the airy composition of the compressible mat, the top cloth can easily dry on that place.

In a possible variant of a floor with a compressible mat, the perforated foil lies on a capillary mat 15, as shown here. That mat is, as is preferred, directly on a granular layer, so as to also provide for horizontal transport of water.

Claims (9)

Cultivation floor system with a floor (1) on which plant holders (2) are placed, which cultivation floor system comprises: - a watertight basin (3); - a water-permeable structure in the basin, which structure has a permeable top cloth (4) which forms the top of the floor on which plant holders are placed, which structure comprises one or more water-retaining layers (5), for example of granular material, a water installation (6, 7, 8, 9) which is arranged for supplying water so that water is available for the plants in the plant holders, the permeable top cloth (4) having a relatively high porosity with small pores, preferably a woven top cloth with pores between the yarns of the top cloth, characterized in that between the permeable top cloth (4) on the one hand and the one or more water-retaining layers (5) on the other hand is placed a perforated foil (10) made of impermeable material film material provided with distributed perforations (11), such that the film (10) reduces the free evaporation surface for water from the water-retaining layer (s), e.g. preferably reduces at least 50%, more preferably reduces at least 90%. Cultivation floor system according to claim 1, wherein the perforated film (10) is made of impermeable film material which is provided with distributed perforations (11) with an average opening of between 0.75 mm 2 and 108 mm 2, the perforations (11) being preferably form no more than 10% of the surface. The cultivation floor system according to claim 1 or 2, wherein the perforated film (10) is a single-layer film, preferably made of plastic. Cultivation floor system according to one of claims 1 to 3, wherein the top cloth (4) lies directly on top of the perforated foil (10). Cultivation floor system according to one of claims 1 to 3, wherein the top cloth (4) lies above a compressible mat (20) with an open structure, which compressible mat (20) is locally compressible under the weight of each plant container (2), wherein non-compressed areas of the mat (20) show no or hardly any capillary action and compressed areas provide a hydraulic connection between the plant holder (2) and the one or more water-retaining layers (5), the compressible mat (20) above or lies below the perforated foil (10) and wherein the one or more water-retaining layers (5) are lower. Cultivation floor system according to one or more of the preceding claims, wherein the perforated film (10) lies on or below a capillary mat (15) which has capillary action in the horizontal direction and in the vertical direction, for example a non-woven mat (15) of fibrous elements, for example a compacted non-woven mat. 7. Cultivation floor system as claimed in one or more of the foregoing claims, which system further comprises an ebb / flow water installation which is adapted to effect an alternate supply of water to the cultivation floor and drainage of water from the cultivation floor, which water installation comprises Nation : - one or more irrigation pipes (6) in the basin (3), which irrigation pipes have outflow openings along their length that allow water to flow out of the one or more irrigation pipes, the one or more irrigation pipes being covered by the water-permeable structure (5). A method for growing plants, preferably in a greenhouse, wherein use is made of a cultivation floor system according to one or more of the preceding claims. A method for growing plants, preferably in a greenhouse, wherein use is made of a cultivation floor system according to one or more of the preceding claims, and wherein the perforated foil (10) is dimensioned with a free evaporation surface for water from the water retaining layers such that at least one of the following effects is achieved: - drying of the top cloth (4) during periods in which the water basin has been emptied such that algae growth on / in the top cloth is prevented / prevented; - reduction of the percentage of moisture in the air in the greenhouse by reducing the evaporation of water from the layers retaining one or more water; - maintaining a desired humid climate in the one or more water retaining layers in view of a biological condition in those one or more retaining layers.