NL8701732A - Culture system using mat - has water-absorbing mat accommodated in holder and extending above water layer in reservoir, with mat made of culture medium - Google Patents

Abstract

The system comprises a water impermeable reservoir (2) having a layer of water (11). A water absorbing mat (9) is accommodated in a holder (23). The mat extends above the layer of water and rests on at least one mat support coming out above the layer of water. The mat and the mat support are manufactured from a culture medium. The mat forms with the mat support(s) a monoblock. Side walls of the mat suppor(s) which reach out above the water diverge from each other in a direction away from the layer of water.

Description

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Ned. including 87.01732 P HP / bh / Rw-25 £ -1- CULTIVATION SYSTEM AND A MONOBLOCK FOR APPLICATION THEREOF.

The present invention relates to a cultivation system in which a mat is used as the cultivation medium.

The mat, for example of mineral wool, acts as a support for the plant, and as a water storage and also provides a matrix in which the roots root. The mat is placed in a reservoir, in which a layer of water is incorporated. The reservoir can consist of a layer of water-impermeable material, wholly or partly enveloping the mat, or of a substantially form-retaining gutter or container.

The plant roots absorb air and water from the mineral wool mat. It has been found on further investigation that the plant from the cultivation system can supply itself mainly with sufficient water via the roots present in the water layer, and can supply it substantially completely with oxygen via the roots present in the cultivation medium. This insight offers the possibility of increasing the volume of available water of the cultivation system, without this being accompanied by an increase in the volume of mineral wool, or the moisture content thereof.

This is achieved with the cultivation system according to the invention, in that it comprises: a water-impermeable reservoir containing a layer of water; Means for maintaining the layer of water in the reservoir; a water-absorbing mat received in the holder, which extends above the layer of water and rests on at least one mat support extending into the layer of water, wherein the mat and the mat support are manufactured from a cultivation medium.

Requirements for the cultivation system are that the mat extends freely above the layer of water and that it communicates capillary via the support or supports. Thus, the plant roots can grow out of the mat and the supports into the layer of • 8801732 ft -2- · * water and water is sucked in the reverse direction from the layer of water into the mat. However, the additional advantage is achieved here that the total moisture, but in particular the moisture in the top layer of the mat, decreases and the oxygen content increases. .

As a result, a possibly undesired, too large amount of water in the cultivation system does not lead to disastrous consequences (only temporarily a higher humidity in the mat), but moreover a larger water supply is created which considerably improves the safety of the cultivation system.

It is desirable for technical production reasons that the mat with the mat support (s) preferably form a monoblock.

According to a favorable embodiment, side walls of the mat support projecting upwards from the layer of water diverge in a direction from the water layer, wherein preferably two side walls of a mat support diverge at an acute angle to the water surface. It is thus achieved that the part of the mat which lies freely above the water layer can only be supplied with water by lateral water transport. Moreover, since the interface with the layer of water is relatively small, transport through this boundary layer is also limited, so that the mat also becomes relatively drier in the desired sense.

The monobloc mat with mat supports is given sufficient self-stability, if the side walls preferably project from a bottom surface.

Various types of mat supports are possible, for example molded pillars can be used. For production technical reasons, however, it is preferred that, according to a first preferred embodiment, the mat support extends in the longitudinal direction of the mat or, according to a second embodiment, a number of mat supports in the width direction of the mat spread over the length of the mat. stretch out.

It is particularly advantageous if the side walls of the mat support and mat supports, respectively, with the side walls of the mat connecting thereto lie in a common plane.

Cutting losses are avoided as much as possible if further preferably the monoblock is cut from a cultivation medium blanket 5 and a cutting plane forms a plane of symmetry with an adjacent monoblock. A further desired increase in the water supply in the reservoir can be obtained if the mat support or mat supports preferably rest (s) on an elevation (s) extending below the water level over a part of the height of the water layer.

The use of a gutter can be dispensed with if the reservoir is formed by a strip of flexible, water-impermeable material and is modeled into a gutter shape with modeling means. In this connection it is advantageous that the elevation is separated from the layer of water by the strip of flexible, water-impermeable material. The elevation is thus located outside the reservoir and does not need to undergo a sterilization operation prior to cultivation, or material can be used which, in principle, cannot be sterilized or only partially. This also applies if a gutter is used.

According to another preferred embodiment it is favorable that the monoblock rests in at least one holder.

In various preferred embodiments, the monoblock has a cross-sectional shape of an isosceles triangular or isosceles straight triangle directed downward at the apex angle, or of an isosceles trapezoid or rectangular trapezoid directed downward at the shorter parallel side.

Finally, the invention also relates to the monoblock per se described above which is intended for use in the cultivation system according to the invention.

Said and other features will be elucidated on the basis of a number of embodiments of the cultivation system and the monoblock according to the invention. 8801732 i.

-4- *, which exemplary embodiments will be discussed with reference to the accompanying drawings.

In the drawing: figure 1 is a perspective view of a section 5 of a first cultivation system according to the invention; figures 1a and 1b each show a variant of the cultivation system of figure 1, wherein the monoblock rests in at least one container; figures 2 and 3 each show a different embodiment of the cultivation system according to the invention; figure 4 shows a part of a blanket of mineral wool with cutting lines along which the blanket is cut into monoblocks according to the invention; Figures 5, 6 and 7 each show variants of the monoblocks 15 according to the invention; figure 8 shows on a different scale a cross section of yet another cultivation system according to the invention; and figure 9 shows a monoblock according to the invention which forms a variant of the cultivation system of figure 8.

Figure 1 shows the cultivation system 1 according to the invention. The cultivation system comprises a reservoir 2 which is formed by a strip of water-impermeable plastic which lies partly on a substrate 4. lateral edges 5 and 6 are laid over rigid rods 7 and 8 arranged parallel to each other at a fixed height 25 above the substrate. these bars 7 and 8 rest, via the edges 5 and 6, in a monoblock 9 triangular in cross section.

The monoblock 9 comprises a lower support 10 which extends into a layer of water 11 present in the reservoir 2. The upper, remaining part 12 of the monoblock 9 extends above the layer of water 11. The part 12 which is the equivalent of the original growth mat is only in contact with the layer of water 11 via the part 10 capillary.

The two long side walls 13 and 14 diverge mutually with respect to the water surface 15 and each enclose an acute angle (45 °) therewith.

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Means 16 for maintaining the layer of water 11 comprise a central water pipe 17, from which water 19 is supplied by means of a dropper 18 to the plant 20 which is placed with the growth block 21 on the monoblock 9.

Plant roots thus root the monoblock 9 and part of the roots continues into the layer of water 11. Thus, compared to the known systems, the water capacity relative to the volume of rock wool is increased in this case by approximately 50%. The increase in water capacity offers greater safety against disturbances in the water supply, while, furthermore, due to the triangular monoblock shape, a temporary excessive water dose does not lead to disastrous consequences.

Figure 1a shows a variant. This cultivation system 22 comprises an "MM-shaped holder 23 which is provided with slots 24. The height of the water layer 11 is such that the part 25 of the monoblock 9 extends into the water, so that the part 26 located above the part 25 of the monoblock capillary is supplied with water In this case, the edges 5 and 6 of the strip 3 are passed over iron wire 80, the sole purpose of which is to provide a reservoir 2 in which a sufficiently high water level can be maintained.

In the variant according to Fig. 1b, the cultivation system 22 'comprises a number of nMn-shaped holders 23, in which the monoblock 9 rests through the strip 3 of water-impermeable material. Only the part 25 of the monoblock 9 extends into the layer of water 11. Between successive holders 23, the strip 3 deflects towards the substrate 4 and there forms an additional available water volume. In this variant, the containers 23 do not belong to those parts of the cultivation system that have to be sterilized.

Figure 4 shows a preferred manner in which the monoblocks 9 of Figure 1 and 1a are cut from a blanket 27 of mineral wool. The blanket has a height h of 15 cm and is successively halved in height by cutting according to the cutting plane 28, after which the triangular monoblocks 9 are formed by cutting according to the cutting surfaces 29 and 30, each with an angle of 45 °. enclose with the top surface 31 or the bottom surface 32. In this way 5 monoblocks can be provided which do not give rise to cutting losses.

The monoblock 33 of figure 5, an isosceles steppedium, and the monoblock 34 of figure 7, a rectangular steppezium can each also be manufactured from a mineral blanket 27 without significant cutting losses 10, because the cutting surfaces, also side walls 35, 36 and 37, respectively, 38, form a plane of symmetry for the monoblock to be cut next to it from the blanket.

Figure 2 shows a cultivation system 39, in which the reservoir 40 is formed by an upwardly open gutter 41, the bottom 42 of which is provided with an elevation 43 which extends below the water surface 44. The monoblock 45 is located with the lower support part 46 below the water surface 44 and draws water 20 for the entire monoblock 45. The part 47 of the monoblock 45 adjacent to the part 46 has side walls 48 and 49 which extend over the water layer 11 up to the gutter walls 50 and 51. Part 52 adjoins part 47. Due to this elevated part 52, a further reduction / increase of the water content / oxygen content at the top of the monoblock 45 is realized. Nevertheless, sufficient water is available for the plant 53 because it extends with its roots through the monoblock 45 into the layer of water 11. The cultivation system 39 has the advantage of a further increased water volume as a result of the use of the elevation 43.

The height of the water layer 11 is realized with means not shown, for example in this case with a supply pipe with one or more overflows. A temporary increase in the water layer as a result of whatever disturbance 35 does not lead to disastrous consequences, because the average moisture content in the monoblock 45 is certainly lower at the top.

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Figure 3 shows yet another cultivation system 54 according to the invention. In this case, in comparison with system 1 of figure 1, a monoblock 55 which is an isosceles staircase in cross section is used. The monoblock 55 comprises a support part 56 which rests with a support surface 57 on an elevation 58 in the form of a beam, a row of stones or the like, which is placed on the ground 4 and over which the strip 3 is laid. The mat part 59 has side surfaces 60 and 61 which diverge in an upward direction from the bottom surface 57 and from the water layer 11 and connect at the height of the rods 7 and 8 to the top surface 62 on which the growth block 63 with the plant 64 stands.

In the measuring system 54, the advantages of the simple measuring system of figure 1 are combined with the increased water volume of the measuring system 39 of figure 2.

Figure 6 shows a monoblock 87 whose side walls 65 and 66 are not in a box.

The total height of, for example, the monoblocks 33, 81 and 34 and figures 5-7, for example, have a height of 7.5 cm, a width for the bottom surface of 2 - 5 cm and a width for the top surface of, for example, 10 - 15 cm. The length is optionally 1-2 meters.

Figure 8 shows a cultivation system 67 according to the invention, in which a growth mat 68 rests on a number of supporting blocks 69 arranged along its length, each made of mineral wool. The support blocks are placed in a layer of water 11 of the reservoir 70 formed by a strip 71 of flexible material which is passed over the iron rods 7 and 8. The growth mat 48 is capillarily connected to the layer 11 via the supports 69 in a liquid-communicating manner. .

Because the roots 72 of the plant 73 continue to grow the growth mat 68 and the supports 69, the growth mat 68 with its separate supports 69 obtain a good mutual relationship.

For example, the growth mat 68 has a height of 2.5 cm and the supports 69 have a height of 7.5 cm. Despite the minor

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Nevertheless, rock wool volume of the growth mat 68 allows optimum cultivation because the roots can reach the water layer 11 via the supports 69 and sufficient water is available for the plant 73. The primary advantages of the cultivation system according to the invention are thus achieved. Preferably, the plates 73 are placed above the supports 69. If the growing mat 68 is thicker or the weight of the plants permits, it is also possible to place a plant between two supports on the mat 68. The ratio of available water volume to rock wool volume increases by approximately 25-30%. With a slope percentage of 1.5% for the substrate 4, it is possible that the growing mats 68 have a length of 2 meters. It is thus possible to increase the water buffer without the growth mat 68 becoming too wet.

Finally, figure 9 shows another monoblock 74 according to the invention, which consists of a mat part 75 and a number of mat supports 76 arranged underneath the length of the mat and extending in width direction under the mat 75. This monoblock 74 is surrounded by a waterproof cover 77. When used in one of the cultivation systems described above, it is a requirement that the water level is always below the bottom surface 78 of the mat 75.

Although the cultivation system and the monoblocks have been described in the specification as made of mineral wool, it will be appreciated that any suitable water-wettable cultivation medium can be used, such as: 1. mineral wool, such as rock wool, glass wool, and the like ; and 2. plastics, in particular foam plastics, such as polyphenol foams, polyurethane foams.

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Claims (15)

Cultivation system, comprising: a water-impermeable reservoir containing a layer of water; means for maintaining the layer of water in the reservoir; and a water-absorbing mat received in the container, which extends above the layer of water and rests on at least one mat support extending into the layer of water, wherein the mat and the mat support are made of a cultivation medium. Cultivation system according to claim 1, characterized in that the mat with the mat support (s) form a monoblock. Cultivation system according to claim 1 or 2, characterized in that side walls of the mat support (s) protruding from the layer of water diverge in a direction from the layer of water. Cultivation system according to claim 3, characterized in that two side walls of a mat support each enclose an acute angle with the water surface. Cultivation system according to claim 3 or 4, characterized in that the side walls project from a bottom surface. Cultivation system according to claims 1-5, characterized in that the mat support extends in the longitudinal direction of the mat. Cultivation system according to claims 1 - 5, characterized in that a number of mat supports extend along the length of the mat in the width direction of the mat. Cultivation system according to claims 1-7, characterized in that the side walls of the mat support and mat supports, respectively, with the adjoining side walls of the mat 30 lie in a common plane. Cultivation system according to claim 8, characterized in that the monoblock is cut from a cultivation medium blanket and a cutting plane forms a plane of symmetry with an adjacent monoblock. Cultivation system according to claims 1-9, characterized in that the mat support or mat supports rest (s) on an elevation (s) extending below part of the height of the water layer under <88017: 32 -10- ι. . 11. Cultivation system according to claim 9, characterized in that the reservoir is formed by a strip of flexible, water-impermeable material and is modeled into a gutter shape with modeling means. Cultivation system according to claims 10 and 11, characterized in that the elevation is separated from the layer of water by the strip of flexible, impermeable material. Cultivation system according to claims 1 - 12, characterized in that the monoblock rests in a container. Cultivation system according to Claims 1 to 13, characterized in that the monoblock is in cross-section in the form of an equilateral triangle or isosceles straight triangle facing downwards with the apex angle downwards, or of a shorter parallel side facing downwards isosceles trapezoid or rectangular trapezoid. 15. Monoblock consisting of a mat with one or a number of mat supports intended for use in the cultivation system according to claims 2-14. 8801732