NL2012248C2 - FARMING FLOOR SYSTEM AND METHOD. - Google Patents

Description

FARMING FLOOR SYSTEM AND METHOD

The invention relates to a cultivation floor system comprising a cultivation floor with a watertight basin and a cultivation floor on which plant holders are placed. The cultivation floor 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. In practical applications the water level is regularly raised to a highest water level above the floor, so that the plant holders are placed in the water with their lower part.

The cultivation floor can be a watertight, for example concrete floor, flooded when there is a flood, so that the lower part of the plant holders are in the water. At low tide the water is drained away so that the floor becomes dry.

In another known embodiment which is also considered to be advantageous in the present invention, the cultivation floor has a water-permeable substructure and the top of the floor is also permeable, for example with a permeable top cloth and with one or more layers of granular material below, such as for example lava rock. In addition, the one or more irrigation pipes are usually located in or underneath the one or more layers of granular material, so that the water distributed over the basin rises uniformly in the permeable structure and falls during the flood and ebb cycle.

Known cultivation floor systems, for example in a greenhouse, often comprise a large number of basins, wherein the ebb / flow cycle can be set separately for each basin. In known systems, a water installation is provided with one or more irrigation pipes in the basin and with a pump for supplying water to the one or more irrigation pipes. Furthermore, a water storage facility is provided, for example a storage pond or an underground water storage facility. The pump draws water from the water storage and supplies it to the basin via the irrigation pipes. After the water level has been kept at the desired higher level for a sufficient time, the water is drained off again via a drain pipe to the water storage. In order to control these flows, in known systems two valves are provided per basin, namely a supply valve to the irrigation pipes and a discharge valve to the discharge pipe. Those valves are generally operated electrically and / or pneumatically.

With such a cultivation floor, correct functioning of the ebb / flood water installation is of the utmost importance, because otherwise the cultivation of the plants can lead to significant damage. The valves are a relevant source of malfunctions. That is why it is required to have completely new valves and / or parts of those valves in stock at the grower and / or to be able to deliver parts through urgent deliveries. This increases costs.

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 has for its object to provide a cultivation system with an improved valve assembly, in particular with regard to sensitivity to malfunctions, ease of repair, and costs.

The invention achieves one or more of the above objectives with a cultivation system according to claim 1. The valve assembly is herein characterized in that the valve assembly comprises a combined supply and discharge valve, the valve comprising: - a housing; - a main cylinder in the housing, which main cylinder has an axis, optionally a horizontal axis; - a pump inlet in connection with the main cylinder, which pump inlet is connected to the pump, - an irrigation pipe connection in the housing, which is connected to the main cylinder and to which the one or more irrigation pipes are connected; wherein a valve piston is provided in the main cylinder, movable along the axis, wherein the housing is provided with a seat at one end of the main cylinder, wherein an outlet connection is provided in the housing to which the discharge line is connected, the outlet connection being provided in an end part of the housing, on the side of the seat remote from the main cylinder, the valve piston being movable to and fro between a closed position in which the piston engages the seat and closes the outlet connection from the main cylinder so that water supplied via the pump inlet to the irrigation lines, and an open position in which the piston is away from the seat so that the outlet connection is in communication with the main cylinder and with the irrigation line connection, and wherein a flow path for water is present between the valve piston and the housing such that water from the pump inlet to the irrigation pipe connection when the valve piston z is in the closed position, the housing having an end cap at the end remote from the seat, for example as a detachable cover, which forms a closure of the main cylinder, so that a variable chamber is formed between said end cap and the valve piston in communication with pump inlet, wherein the valve is further provided with a restriction element which forms a restriction for the water supplied via the pump connection at a location between the valve piston and the housing, so that a water pressure is created and / or energized upstream of the restriction, which water pressure brings and holds the valve piston closed.

In a practical embodiment the restriction element is a stationary and rigidly designed restriction element element, which defines a fixed restriction surface, which surface is preferably smaller than the inner diameter of the pump inlet.

In one embodiment, the restriction element is provided between the outer circumference of the valve piston and the surrounding portion of the housing. The restriction element, for example in the form of a ring, is preferably arranged on the outer circumference of the valve piston, an annular gap being present between the ring and the housing.

In the invention it may further be provided that the valve piston has a tubular section extending along the shaft with a bore that is open at the end of the valve piston remote from the seat, the housing comprising an inlet pipe connected to the pump inlet, which inlet tube extends along the shaft and protrudes into the bore in the tubular portion of the valve piston. The inlet tube preferably has a mouth only at its axial end, so that the water sprays against the valve piston in the axial direction. The inlet tube preferably has a considerably smaller outer diameter than the diameter of the bore, for example such that the surface of the intermediate annulus is larger than the surface of the inner diameter inlet tube or of its mouth.

The invention may furthermore comprise return means, for example one or more springs, for instance one or more tension springs, which return the valve piston to the open position when the supply of water to the pump inlet is stopped.

In a valve according to the invention, locking means can further be provided which are adapted to lock the valve piston in its closed position. For example, a locking pin is provided which can be pressed against the valve piston in the axis direction and fixed.

In a valve according to the invention, an air valve, for example a non-return valve or an operable valve, can further be provided, which air valve serves to - if desired - allow air to escape automatically from the main cylinder, for example from the said chamber.

As will be further apparent from the following description with reference to the drawing, the valve according to the invention operates completely mechanically and the valve can be realized in such a way that the cost price is low. The valve can also be realized in such a way that it is easy to clean / repair, with few demands placed on the skills of the repairman.

In a practical embodiment, a removable end part, such as a lid, is provided at the end of the housing remote from the seat so that the piston is removable from the main cylinder, for example for cleaning and / or repair.

In a practical embodiment, the majority of the piston has a substantially smaller diameter than the main cylinder, so that an annular passage for water is present through which water can flow from the pump inlet to the irrigation pipe connection. The diameter can deviate significantly, so that - except at the location of the restriction element - a gap of more than one centimeter is present between piston and main cylinder.

In a practical, inexpensive and easy to maintain / repair embodiment, it is provided that the housing comprises a plastic pipe section, preferably of PVC, which forms the main cylinder. Preferably, the valve piston also comprises a plastic pipe section, preferably of PVC, which pipe section forms the reservoir of the piston. Other parts of the valve can also be made of plastic, for example the lower part of the housing is designed as a T-piece, preferably from PVC.

In a practical embodiment, the cultivation floor system comprises several basins, with a combined supply and discharge valve being provided at each basin.

The invention also relates to a method for operating a cultivation floor system according to the invention.

For supplying water to the cultivation floor, water is thereby supplied via the pump to the pump inlet of the combined supply and discharge valve, whereby the valve piston is pressed onto the seat in its closed position. The water supplied by the pump then flows through the irrigation pipe connection and the one or more irrigation pipes flows into the basin so that the water level rises therein. This supply is stopped when the water in the basin has reached a desired water level.

The invention also relates to a combined supply and discharge valve intended for use in a cultivation floor system as described herein.

The invention also relates to a greenhouse provided with a cultivation floor according to the invention.

The invention will be explained below with reference to the drawing. Fig. 1 shows diagrammatically a cultivation floor installation to illustrate the implementation of the method according to the first aspect of the invention, - figs. 2a and 2b show a cross-section of a combined water supply and discharge valve for a cultivation floor, in closed and open position, respectively; - Figure 2c shows a detail of the valve of figures 2a, b on a larger scale.

Figure 1 schematically shows a cultivation floor system for illustrating the invention.

The system 1 comprises a cultivation floor 2 with a watertight basin 4, here with a water-permeable structure 5 and a water-permeable top layer or top 17 which forms the actual floor. The structure 5 comprises one or more layers of granular material, but can also (or in combination therewith) comprise one or more water-permeable mats.

Plants or the like to be grown on the floor 2 are placed in plant holders 6, for example in holders 6 which are partially open at the bottom and / or have a water-permeable design.

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 floor is preferably sufficiently stable to drive over it with a vehicle.

The cultivation floor system further comprises an ebb / flow water installation which is adapted to effect an alternate supply of water to the cultivation floor 2 and drainage of water from the cultivation floor, preferably with a highest water level above the topsheet 17.

The water installation comprises: - one or more irrigation pipes 7, 9 in the basin 4; - a pump 10 for supplying water to the one or more irrigation pipes 7,9 which have outflow openings 8 along the length and which here lie in a gutter 14; - a discharge line 13; - a water storage 11, wherein the pump 10 withdraws water from the water storage and the drain pipe returns water to the water storage.

In a possible variant, the water storage 11 is above the level of the cultivation floor, so that the difference in height actually produces the pumping action for the water supply to the cultivation floor and no separate pump is required in the supply to the cultivation floor. Optionally, a pump is then provided in the return flow to the water storage 11, for example between a lower water storage and a higher water storage.

Furthermore, a valve assembly is provided with a combined supply and discharge valve 80, an embodiment of which will be further elucidated with reference to Figures 2a - c.

An example of a combined supply and discharge valve 80 for a cultivation floor system with ebb / flood-water installation will now be described with reference to Figures 2a, 2b and 2c.

The valve 80 comprises a housing 81 with a main cylinder 82 in the housing, which main cylinder has an axis 82a, optionally or even preferably a horizontal axis. By choosing a horizontal arrangement, despite a considerable length, the valve does not form an obstacle, for example in a greenhouse.

The valve 80 further comprises a pump inlet 83, here embodied as an end of an inlet tube 84. The pump inlet 83 communicates via the inlet tube 84 with the main cylinder. Furthermore, the pump inlet 83 is connected to the pump 10.

The housing is further provided with an irrigation pipe connection 85, which is connected to the main cylinder 82 and to which the one or more irrigation pipes 7,9 are connected.

Provided in the master cylinder 82 is a valve piston 86 which is movable along the axis 82a.

The housing is provided with a seat 87 at one end of the main cylinder 82. Furthermore, the housing is provided with an outlet connection 88, to which the discharge line 13 is connected.

The outlet connection 88 is provided in an end part of the housing on the side of the seat 87 remote from the main cylinder.

The valve piston 86 is movable to and fro in the main cylinder between a closed position (Figure 2a) in which the piston 86 is sealingly abutting the seat 87 and thereby closes the outlet connection 88 from the main cylinder 82.

The piston 86 has a smaller outside diameter than the diameter of the master cylinder 82, so that an annular passage for water is provided through which water can flow from the pump inlet 83 to the irrigation pipe connection 85 when the valve is closed.

This solution is very simple and prevents clamping of the piston in the housing.

Figure 2b shows the open position in which the piston 86 is away from the seat 87 so that the outlet connection 88 is connected to the main cylinder 82 and in particular to the connection 85. This allows water to flow out of the basin 4 via the pipes 7,9 to the discharge line 13 and then to the storage 11.

A flow path for water is present between the valve piston 85 and the housing 81, such that water can pass from the pump inlet 83 to the irrigation pipe connection 88 when the piston is in the closed position (see figure 2a).

The housing 81 has at its end remote from the seat 86 an end cap 89 which forms a closure of the main cylinder 82, so that a chamber 90 which is variable in size due to the position of the piston 86 is formed between said end cap 89 and the valve piston 86. communicating with pump inlet 83.

The valve 80 is further provided with a restriction element 91 which forms a restriction for the water supplied via the pump connection 83 at a location between the valve piston 86 and the housing 81, so that a water pressure is created and / or energized upstream of the restriction 91 , which water pressure brings and keeps the valve piston 86 closed.

In the practical embodiment shown, the restriction element 91 is a stationary and rigidly designed restriction element 91, which defines a fixed restriction surface for the water flow, which surface is preferably smaller than the inner diameter of the pump inlet 83.

In the embodiment shown, it is provided that the restriction element 91 is arranged between the outer circumference of the valve piston 86 and the surrounding portion of the housing 81. Here, the restriction element in the form of a ring 91 is arranged on the outer circumference of the valve piston 86, wherein an annular gap is provided between the ring and the housing as a restriction passage for the water flow.

In figures 2a, b it can further be recognized that the valve piston 86 has a tubular portion 86a extending along the axis 82a with a bore 93 which is open at the end of the valve piston 86 remote from the seat 87. The housing further comprises the Inlet tube 84 connected to the pump inlet and extending along the axis 82a and extending into the bore 93 in the tubular portion 86a of the valve piston 86. Preferably, the inlet tube has a mouth 84a only at its axial end, so that the water sprays into the valve piston 86 axially against the blind end of the bore. Preferably, the inlet tube 84 has a considerably smaller outer diameter than the diameter of the bore 93, for example such that the area of the intermediate annulus is larger than the area of the inner diameter inlet tube 84 or of the mouth 84a thereof.

Furthermore, reset means are provided, for example one or more springs, for example one or more tension springs 95, which return the valve piston 86 to the open position when the supply of water to the pump inlet 83 is stopped. For example, a variant of the reset mechanism is provided in a counterweight (via a cable or lever or the like).

In a possible embodiment, locking means are provided which are adapted to secure the valve piston in its closed position. For example, a locking pin is provided which can be pressed against the valve piston in the axis direction and fixed.

The valve 80 may be provided with an air valve 96, for example a non-return valve or an operable valve, which air valve serves to - if desired - allow air to escape automatically from the main cylinder, for example from the said chamber.

In a simple embodiment, the housing 81 comprises a plastic pipe section, preferably of PVC, which forms the main cylinder 82.

In a simple embodiment, the piston 86 comprises a plastic pipe section, preferably made of PVC, which is provided at one end with a cap which can be sealed against the seat.

In a simple embodiment, a portion of the valve 80 is designed as a T-piece of plastic, for example a T-piece of PVC for connecting PVC pipes, one sleeve receiving the pipe piece that forms the main cylinder 82, the other sleeve the irrigation conduit connection 85 forms, and a third insertion socket forms the outlet connection 88. A sealing ring of the T-piece may optionally serve as seat 87 of the valve.

In a system, for example a greenhouse, with a plurality of separately operable basins 4, a combined supply and discharge valve 80 is preferably provided for each basin.

For supplying water to the cultivation floor 2, water is supplied by means of the pump 10 to the pump inlet 83 of the combined supply and discharge valve 80, whereby the piston 86 is pressed onto the seat 87 in its closed position. As a result, the supplied water flows to the irrigation pipe connection 85 and to the one or more irrigation pipes 7,9 to then flow into the basin 4. This supply is stopped when the water in the basin 4 has reached a desired water level. Instead of, or in addition to, the passage between valve piston and the cylindrical part of the housing, a bypass channel may also be provided in the housing.

When the water supply stops, the valve 80 will open and the water can then flow away from the cultivation floor to the pipe 13.

The floor can be flooded by the supplied water so that the plant holders are in the water with a lower part. But it is also conceivable that the water level does not rise above the floor, for example when the water supply is used to wet / keep the permeable structure itself and / or to cool the floor with the water.

Claims (9)

Cultivation floor system comprising a cultivation floor (2) with a watertight basin (4) and a floor on which plant holders (6) are placed, which cultivation floor system further comprises an ebb / flood water installation which is adapted to effect an alternate supply of water to the cultivation floor and drainage of water from the cultivation floor, wherein the water installation comprises: - one or more irrigation pipes (7,9) in the basin (4); - a pump (10) for supplying water to the one or more irrigation pipes; - a discharge line (13); - a water storage facility (11), wherein the pump draws water from the water storage facility and the drain pipe returns water to the water storage facility, - a valve assembly; characterized in that the valve assembly comprises a combined supply and discharge valve (80), which valve comprises: - a housing (81); - a main cylinder (82) in the housing, which main cylinder has an axis (82a), optionally a horizontal axis; - a pump inlet (83) in connection with the main cylinder, which pump inlet is connected to the pump, - an irrigation pipe connection (85) in the housing, which is connected to the main cylinder (82) and on which the one or more irrigation pipes (7), 9) are connected; wherein a valve piston (86) is provided in the main cylinder, movable along the shaft (82a), the housing being provided with a seat (87) at one end of the main cylinder, an outlet connection (88) being provided in the housing, to which the discharge line (13) is connected, the outlet connection (13) being provided in an end part of the housing, on the side of the seat (87) remote from the main cylinder (82), the valve piston (86) reciprocating is movable between a closed position in which the piston engages the seat (87) and closes the outlet connection (88) from the master cylinder (82), and an open position in which the piston is away from the seat (87) so that the outlet connection (88) ) is in communication with the master cylinder (82) and with the irrigation pipe connection (85), and wherein a flow path for water is present between the valve piston (86) and the housing (81) such that water flows from the pump inlet (83) to the irrigation pipe connection (85) can pass when the piston (86) is in the closed position, the housing having an end cap (89) at the end remote from the seat that forms a closure of the main cylinder (82) so that between said end cap (89) and the valve piston (89) 86) a variable chamber (90) is formed which communicates with pump inlet (83), the valve (80) further comprising a restriction element (91) located at a location between the valve piston (86) and the housing (81) forms a restriction for the water supplied via the pump inlet (83), so that upstream of the restriction (91) a water pressure is created and / or energized, which water pressure brings and keeps the valve piston closed. Cultivation floor system according to claim 1, wherein the restriction element (91) is a stationary arranged rigid element element, which defines a fixed restriction surface, which surface is preferably smaller than the inner diameter of the pump inlet (83) ) The cultivation floor system according to claim 1 or 2, wherein the restriction element is provided between the outer circumference of the valve piston (86) and the surrounding part of the housing (81). The cultivation floor system according to claim 3, wherein the restriction element (91) is in the form of a ring arranged on the outer circumference of the valve piston, an annular gap being present between the ring and the housing. 5. Cultivation floor system as claimed in one or more of the foregoing claims, wherein the valve piston has a tubular section extending along the axis (82a), for example formed by a PVC pipe section, with a bore which is open at the side remote from the seat (87) end of the valve piston, the housing including an inlet tube (84) connected to the pump inlet, which inlet tube extends along the axis and extends into the bore in the tubular portion of the valve piston. The cultivation floor system of claim 5, wherein the inlet tube (84) has a mouth only at its axial end, so that the water sprays axially against the valve piston (86). Cultivation floor system as claimed in one or more of the foregoing claims, wherein reset means are provided, for example one or more springs, for example one or more tension springs (95), which return the valve piston to the open position when the supply of water is stopped at the pump inlet. 8. Cultivation floor system as claimed in one or more of the foregoing claims, wherein the end part of the valve provided with the seat is designed as a T-piece made of plastic, for example a T-piece made of PVC, the one sleeve receiving a pipe piece that receives the main cylinder (82), the other sleeve forms the irrigation pipe connection (85), and a third sleeve forms the outlet connection (88). Method for operating a cultivation floor system according to one or more of the preceding claims, wherein for supplying water to the cultivation floor (2), water is supplied via the pump (10) to the pump inlet (83) of the combined supply and drain valve (80) through which the piston (86) is pressed in its closed position on the seat (87), so that the water supplied via the irrigation pipe connection (85) and the one or more irrigation pipes (7,9) into the basin (4) ), which supply is stopped when the water in the basin (4) has reached a desired water level, and wherein - after the valve piston has been moved to its open position - the water via the one or more irrigation pipes (7,9), irrigation pipe connection (85), and the outlet connection (88) flows out of the basin (4) to the water storage (11).