NL1013090C2 - Hydroponic equipment. - Google Patents

Description

Short designation: Hydroponic equipment

The invention relates to a hydroponic device comprising a substantially rectangular cultivation tank and at least one pump for circulating cultivation liquid flowing through the cultivation tank.

5 Hydroponic systems in which the roots of plants are placed in a circulating culture fluid have become increasingly popular in the recent past. Known hydroponic systems have made plant cultivation possible in the factory, so that the production by means of hydro-culture has not only become usable but also efficient.

When a known hydroponic device of the type mentioned in the preamble is used, the culture liquid flows continuously along the roots of the plants and provides them with the necessary nutrients and oxygen. Oxygen is introduced into the broth by the pump. The culture fluid enters the propagator through an inlet at one end, flows along the roots of the plants and exits the propagator at the other end. The culture liquid then flows into a culture liquid reservoir and from there is pumped back into the culture tank by the pump.

The known hydroponic device has a culture fluid reservoir, an inflow tube connecting the culture fluid reservoir via the pump to one end of the cultivation tank, and an outflow tube connecting the cultivation tank on the other end to the culture fluid reservoir. This rather complicated and inevitably expensive setup requires an effort in terms of energy consumption and increases the price of the final product. Furthermore, in the prior art hydroponic system described above, the plants tend to grow unevenly because nutrients and oxygen are concentrated in the culture fluid at the end of the culture tank where the inflow tube is connected. The plants at the other end of the propagator near the outflow tube tend to receive a lower nutrient concentration.

The object of the present invention is to obviate the drawbacks of the known hydroponic equipment.

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This object is achieved by a hydroponic device of the type mentioned in the preamble, which is characterized by at least one partition wall arranged in the longitudinal direction of the propagation box and a seed bed foot arranged on the upper part of the partition wall, wherein an absorbent sheet is the seedbed foot is laid and hangs down in troughs formed by the dividing wall in the propagator.

The construction of the hydroponic device is simple and ensures an even plant growth.

Preferred embodiments of the hydroponic device according to the invention are set out in the subclaims.

The invention will be further elucidated in the following description with reference to the drawing, in which:

Fig. 1 shows a side view of a known hydroponic plant,

Fig. 2A and 2B each show a cross-sectional view of a known hydroponic system,

Fig. 3A shows a top view of a hydroponic device according to the invention, with one pump arranged outside the cultivation tank,

Fig. 3B shows a top view of a hydroponic device according to the invention, with two pumps arranged outside the cultivation tank, one at each end, and

Fig. 4 is a cross-sectional view of the hydroponic device shown in FIG. 3A, viewed in the direction of arrows A-A.

Fig. 1 shows a side view of a known hydroponic device. In this type of device, the broth flows continuously along the roots of the plants, providing the necessary nutrients and oxygen. To achieve this, seedlings are placed in a culture pack 1 and a pump 3 circulates the culture fluid along the seedlings. Oxygen is mainly introduced into the broth by the pump 3 which mixes air 4 into the broth. The broth flows about 15 to 30 meters through the cultivation tank 1, through an inlet at the <1> end and an outlet at the other end. When the culture fluid leaves the culture vessel 1, it flows back into a culture fluid reservoir 5. The pump 3 pumps the 40 culture fluid collected in the culture fluid reservoir 5 back to the culture vessel 1.

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Fig. 2A and 2B each show a cross-sectional view of a known propagator 1 with seedlings placed therein. Fig. 2A shows how seedlings in seedbeds 9 are placed in pots 7, which in turn are in holes in a cultivation board 8 5. Fig. 2B shows an arrangement in which large seedbeds 9 are placed directly on the bottom of the cultivation tray 1.

As shown in Fig. 1, the known hydroponic device has a culture fluid reservoir 5, an inflow tube 6A connecting the culture fluid reservoir 5 via the pump 3 to one end of the culture tray 1, and an outflow tube 6B connecting the culture tray 1 the other end connects to the broth reservoir 5. This rather complicated and inevitably expensive configuration requires an effort in terms of energy consumption and increases the price of the final product. In known hydroponic plants, the plants tend to grow unevenly because nutrients and oxygen are concentrated in the broth at the end of the nursery where the inflow tube is connected. The plants at the other end of the propagator, near the outflow tube, tend to receive a lower nutrient concentration.

Fig. 3 depicts the overall construction of two embodiments of a hydroponic device according to the invention. Fig. 3A shows a top view of a device in which one pump is disposed outside the culture box, and FIG. 3B shows a top view of a device in which two pumps are positioned outside the culture box, one at each end.

The following describes how the invention has been carried out.

FIG. 3A shows a hydroponic device with a cultivation tank 21, which is, for example, 60 cm wide and 20 meters long and can receive a cultivation liquid with a depth of 10 cm. A seed bed foot 3IA supports the plants. A pump 23A takes in air 24 and mixes it into the broth. The seedbed foot 31A is mounted on a dividing wall 32A (see Fig. 4), which divides the nursery 21 into two troughs 27A and 27B, through which the broth flows.

The operation of the pump 23A causes the culture liquid to circulate through the cultivation tank 21 in the directions indicated by arrows F1, 40, F2, F3 and F4.

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The hydroponic device shown in Fig. 3B is similar to the hydroponic device shown in Fig. 3A. The cultivation tank 21 is, for example, 60 cm wide and 20 meters long and can receive a cultivation liquid with a depth of 10 cm. The seedbed foot 31B 5 is mounted on the dividing wall that divides the cultivation tray 21 into two troughs 28A and 28B. Two externally arranged pumps 23A and 23B take in air 24 and mix it in the broth. The divider {not shown) supporting the seedbed foot 31B forms two troughs 28A and 28B through which the broth flows.

The operation of the pumps 23A ep 23B ensures that the broth circulates: the pump 23A pumps the broth through the cultivation tank 21 in the directions indicated by the arrows F1 and F2 and the pump 23B pumps the broth through the cultivation tank 21 in the arrows F3: and F4 indicate directions.

Fig. 4 is a cross-sectional view of the breeding tank. 21 showing the seedbed foot 3A1 and dp dividing wall 32A, viewed in the direction of arrows A-A in Figure 3A. FIG. 4 shows how the propagator 21 is divided by a dividing wall 32A, which forms the support for the seedbed foot 3IA. The seedbed foot 3IA is covered with an absorbent sheet 33 (or absorbent felt) such that the edges of the absorbent sheet hang down into troughs 27A and 27B. A seedbed

2 5 2 9 is on the absorbent sheet 33 on top of the seedbed foot 3IA

placed. It is noted that the seed bed in Fig. 3B is placed in the same position, i.e. on top of the seed bed foot 31B, as the seed bed in Fig. 3A.

The absorbent sheet preferably consists of blotting paper. When plants are grown in a hydroponic device according to the invention as shown in Fig. 3A, the seed bed is placed on the absorbent sheet 33 on top of the seed bed foot 3IA and the operation of the pump 23A causes the culture liquid to flow through troughs 27A and 27B circu-35. When the plants are grown in a hydroponic device according to the invention as shown in Fig. 3B, the seed bed 29 is placed on the absorbent sheet 33 on top of the seed bed foot 31B and the operation of the pumps 23A and 23B causes the culture liquid to flow through the troughs 28A and 40 28B circulate.

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Once the seedlings are placed on the seedbed foot, the roots of the seedlings of the seedbed 29 on the seedbed foot 31A or on the seedbed foot 31B absorb culture fluid from the absorbent sheet 33, allowing the seedlings to grow. The absorbent sheet 33 extends into the broth in both troughs 27A and 27B or in both troughs 28A and 28B. Then the roots of the seedlings grow, reaching down on either side of the dividing wall 32A or 32B into the troughs and coming into direct contact with the broth. In this way, the roots of the seedlings absorb nutrients and oxygen that seep through the broth as it flows through the troughs, allowing the seedlings to grow into plants.

It should be noted that the above description of the hydroponic equipment indicates that the cultivation tank 21 is divided in two by the provision of one partition wall 32A or 32B. However, the number of partitions is not limited to one. The culture tank 21 may be divided by a plurality of partitions 32A or 32B to form a plurality of troughs through which the culture fluid circulates.

It is also noted that hitherto plants have been placed in two rows in one propagator, as shown in Figures 2A and 2B. However, in the present invention, the same number of plants can be placed on one seedbed foot 3IA or one seedbed foot 31B, but their trunks are arranged in two rows by staggering the plants to the left and right above the seedbed foot, thus saving space.

As explained above, the hydroponic device of the invention makes the use of complex flow paths unnecessary and its simple construction obviates the need for a broth reservoir. The device according to the present invention requires less energy - in fact much less energy - than known devices, because the liquid does not flow down into a reservoir and has to be pumped back to the water level in the breeding tank. The divider divides the trough into troughs and helps maintain a generally equal water level in both troughs. Energy is saved because, since the culture fluid is circulated, the water level remains fairly stable and less pumping energy is required.

Compared to the velocity of the liquid flow in known hydroponic equipment without dividing walls, the dividing wall hydroponic equipment can provide a faster culture liquid flow, because the culture liquid flows through a less cubic area, thus enabling even more energy savings. The roots of the plants grow downward on both sides of the divider in the broth, but there is still no difference in the average level of nutrients and oxygen absorbed from the broth. This means that the plants grow evenly, no matter where; they are in the propagator: placed.

In this way, by the hydroponic apparatus of the present invention, by simplifying the overall mechanism and functions, the circulation of the; culture fluid more efficient, the costs are reduced by energy saving, and in particular the plant growth is improved.

Because an externally arranged pump ensures that the broth circulates through the troughs, the broth flow and the mixing of oxygen in the broth can be precisely controlled.

Furthermore, when pumps are arranged externally at both ends of the culture tank, the mixing of oxygen in the culture liquid can be controlled even more precisely. In addition, by using blotter paper as an absorbent sheet, the culture fluid is absorbed more efficiently and the roots of the plants absorb more nutrients and oxygen from the culture fluid, thereby enhancing plant growth.

Claims (4)

1. A hydroponic device comprising a substantially rectangular cultivation box and at least one pump for circulating cultivation liquid flowing through the cultivation box, characterized by at least one dividing wall arranged in the longitudinal direction of the cultivation box and a seed bed foot arranged on the upper part of the dividing wall with an absorbent sheet placed over the seedbed foot and hanging down in troughs formed by the dividing wall in the propagator. 2. A hydroponic device according to claim 1, wherein at least one pump is arranged for circulating the culture fluid flowing through the troughs outside the cultivation trough. Hydroponic device according to claim 2, wherein the pump or pumps are each arranged on a short side of the cultivation tank. Hydroponic device according to any one of claims 1-3, wherein blotting paper is used as absorbent sheet.