DE4208954A1 - Cultivation system for young plants - has regulated supply of nutrient onto open-topped containers having top feed device, measuring device and water reservoir - Google Patents

Abstract

The substrate is supplied with a nutrient solution which seeps through the substrate body. The nutrient supply is regulated so that the maximum nutrient level appertaining to the plant is not exceeded. This maximum nutrient level and supply are selected so that during the growth period the air capacity above the nutrient solution amounts to 45 to 75%, preferably 50 to 70%. The open-top container (10) which is filled with swollen clay or slate has an associated top feed device (1) and measuring device as well as a water reservoir. ADVANTAGE - The ventilation improves the root growth.

Description

The invention relates to a method for Production horticulture of crops, of which parts of plants are removed, especially cut flowers, Mother plants and vegetables, with the one on their top open vessels filled with expanded clay and / or expanded slate and young plants are placed in this substrate body, and a device for production horticulture with at least one filled with expanded clay and / or expanded slate, on his Open top of the vessel.

In known hydroponic, i.e. H. ungrounded, culture process in production horticulture, nutrient solutions and / or water are used added in such amounts that a large part of the im Plant parts anchored to the substrate body with liquid is washed around. On the one hand, this leads to a wetting of the Substrate body and on the other hand, a large part of the im Existing plant parts from the air supply cut off. This grows both the roots as well the other parts of the plant are not optimal and there is sensitive plants even run the risk of shrinking.

The invention is therefore based on the object of a method and to provide a device for production horticulture, where both adequate nutrient and Water supply to those anchored in the substrate body Plant parts as well as adequate ventilation of the Substrate body can be guaranteed. This task solves the Invention according to the method specified in claim 1 and the device specified in claim 3. The Claim 2 describes an advantageous embodiment of the method and the claims 4 to 7 describe advantageous embodiments of the device.  

The method according to the invention is characterized in that that a nutrient solution is added to the substrate from above, which seeps through the substrate body, the Nutrient solution supply is regulated so that a plant-related maximum nutrient solution level in the substrate body is not exceeded.

The maximum nutritional solution level and the Nutrient solution supply chosen such that during the Growth period the air capacity above the nutrient solution 45 to 75%, preferably 50 to 70%.

Expanded clay granules, the material characteristics of which are given in Table 1, are preferably used to carry out the method according to the invention. The pure density, ie the density of the compact material, is uniformly 2600 g / dm ³ for all the specified grain sizes.

Table 1

The water content, the maximum air content when dry Material and the minimum air content at maximum  Water saturation of the individual grits can be according to the equations given below are calculated.

For the grits given in Table 1, this results the water content values listed in Table 2 and the maximum or minimum air content.

Table 2

The actual air content in one used Expanded clay filling depends on the moisture of the Material between the maximum and minimum air content a, but it should be noted that due to the Root penetration of the expanded clay fillings when used as Plant substrate the specified (theoretical) values for the minimum and maximum total air content to smaller Values are shifted out so that also with the named Grains the air capacity between 45 and 75%, and preferred the indicated preferred air capacity values between 50% and 70%.

The device according to the invention is characterized in that that they have a facility for adding a nutrient solution from above and has a measuring and posing device, which ensures that a predetermined maximum Nutrient solution level in the culture vessel is not exceeded.

Advantageously, the device according to the invention also arranged an overflow device, via which if applicable, the specified maximum Nutrient solution level in excess of the nutrient solution quantity is discharged becomes. The nutrient solution is expediently in one given defined excess from above onto the substrate, because through transpiration and evaporation a certain part of the Liquid is removed from the culture system. To the Nutrient solution levels should not drop to a low level will, since the loss through perspiration and Evaporation is not predictable in advance defined excess added. Through the Overflow device ensures that despite addition an excess of nutrient solution is the maximum Nutrient solution level never exceeded, but neither can be significantly below.  

Because the optimal maximum nutrient solution level in one Culture vessel different for different types of plants the overflow device is preferably in height infinitely adjustable. So it can be used for any kind of plant optimal maximum nutrient solution level easily on the culture vessel can be set.

According to a preferred embodiment of the device it represents a closed cultural system the nutrient solution emerging through the overflow device for example caught in a gutter or a pipe and returned to the device for adding the nutrient solution. The Repatriation can be done without machine support from a Inclination of the gutter or the pipe to the storage container with the nutrient solution. Should the storage container open are at a higher level than the overflow device, the excess nutrient solution must be made using a suitable Facilities, such as pumps, back in the Storage containers are returned. An advantage of closed cultural system can be seen in the fact that the Nutrient solution is optimally used.

In addition, it is also possible that the device represents an open cultural system. Then the seeps away excess nutrient solution in the soil that the culture system surrounds. Open culture systems consume more nutrient solution as closed systems, as part of it is unused in the ground seeps away, but they have the advantage that none Excess nutrient return facilities are needed.

Furthermore, it can be advantageous if in the device a water reservoir separated from the nutrient solution is available.  

The inventive method and the inventive Device have the advantage that above the Nutrient solution level the air capacity depending on the suction tension, Grain fraction of expanded clay or expanded slate and Degree of root penetration of the substrate body between 50 and 70% is. This good ventilation of the substrate body works has a positive effect on the root growth and thus also on the Growth of the entire plant.

Due to the constantly guaranteed maximum water level and the Constantly guaranteed air flow can never lead to Wet the substrate. Irrigation from above and the leakage of the nutrient solution through the Substrate body as well, a water reservoir in the vessel, if present, and the constant existing capillary rise in the On the other hand, substrate ensure good moisture penetration of the substrate body.

The good air flow in the substrate body, even after a long time Culture time, is determined by the structural stability of the substrate, d. H. expanded clay and / or expanded slate. A Densification of the substrate, as is the case with earth, Peat or other organic materials can occur is not in the substrate used according to the invention observed. It is even possible to use several substrates To use cultivation periods, where it is not harmful, if the substrate between periods, for example is disinfected by means of damping.

Will be a reuse on the part of the cultivator excluded, disposal on open land is for example by milling the substrate after previous shredding, or in the construction area without problems possible. There is therefore an environmental impact from the old substrate locked out.  

The device according to the invention contains at least one open top of the vessel. This vessel can preferably be trough-like or egg-shaped. It is preferred several of these vessels, all one below the other connected, one behind the other and / or next to each other being constructed. This makes it possible to use Vessels filled with different grain sizes can contain different types of plants, to use side by side. It is also possible for example in the case of pest infestation such as mycoses, bacteriosis or viroses to remove only the vessel that is infected. Then it can be re-contaminated with substrate after decontamination filled and returned to its original location will.

Those used in the method and device Expanded clay or expanded shale particles preferably have one Diameter from 1 to 12 mm. With certain cultures broken grains can be beneficial as these are one in the Larger surface area compared to unbroken grains exhibit. This will improve water retention of the substrate reached. In addition to expanded clay or expanded slate can be a lower percentage of for example Mineral fiber flakes, such as those made of rock wool, in the Planters should be available. Even a little can Proportion of organic substrate also in the planter are located. However, in order to understand the physical properties of the The substrate should not be changed too much Do not exceed a total of 5% by volume.

The invention is based on Embodiments explained in more detail.  

example 1

A container 10 with a content of 10 l and a closed bottom was used as the culture vessel, see FIG. 1. The round, conical container 10 had a height of 25 cm, a bottom diameter of 22 cm and a diameter at the top of 26 cm. At a height of 2.5 cm above the floor, the container 10 was provided with several bores of 1 cm in diameter, which formed the overflow device 11 . This ensured that there was a maximum of 1 liter of water in the container even after heavy irrigation.

After setting up, the container was filled with Lecaton Type E 4-8 mm to just below the upper edge and then rinsed with water to moisten the expanded clay sufficiently, fill up the water reservoir and, if necessary, rinse out substrate abrasion caused by transport. This rinse water was discarded and not returned to the system. After the rinsing process, there was approx. 1 l of water in the container, see the bottom dashed line in FIG. 1. The border area of the capillary water rise was just below the expanded clay surface at a height of approx. 17 to 20 cm of the container after about a week, see the two upper dashed lines in FIG. 1.

After the rinsing process, the container was ready to be planted. It were two rooted rose cuttings or two grafts placed in the container filled with expanded clay.

Fig. 2 shows five side by side, as described above, filled plant containers. The containers were supplied with a nutrient solution by spray nozzles (not shown) inserted into the substrate. To further moisten the substrate and to avoid salt accumulation on the substrate surface, there were sprayer 1 above the container with an impact nozzle, which can deliver 0.3 l of water per minute.

The containers were arranged in a drainage channel 2 without a heat-insulating effect, which had a gradient of approximately 1% in order to drain off the excess water. At the end of the drainage channel was a pipe 3 through which excess liquid was returned. The drainage channel 2 stood on a styrofoam plate 4 , below which there was still a fabric mat 5 .

Fig 3 finally. Shows two juxtaposed rows of containers with a therebetween vegetation heater 6 as well as a distribution pipe 7 with 1 inch (about 2.54 cm) in diameter for the supply of nutrient fluid.

Water was used to irrigate and prepare the nutrient solution used with the following characteristics:

From morning to evening there was 20 seconds every hour sprayed, the outside temperature was about 20 ° C. At More frequent spraying is required on hot days. During the Throughout the night there were only two sprays of the above duration mentioned. The irrigation was carried out in excess, whereby the surplus during the first two weeks after the Planting about 50%, then about 25%.

The conductivity of the nutrient solution used was included approx. 2.5 µs, the pH value between 5.5 and 6.6.

After about two months of growth, the Plant containers have an average air capacity above the nutrient solution of approx. 65%.

Example 2

The experimental setup was, as described above under Example 1, with the modification that instead of the drainage channel 2 without a heat-insulating effect, a channel made of foamed material was used, so that the styrofoam plates 4 were unnecessary. The change did not result in a change in the air capacity above the nutrient solution in the plant containers.

Claims (7)

1. horticultural production of crops from which plant parts are removed, in particular cut flowers, mother plants and vegetables, in which open vessels are filled with expanded clay and / or expanded slate and young plants are placed in this substrate body, characterized in that the substrate has a Nutrient solution is supplied so that it seeps through the substrate body, the nutrient solution supply being regulated in such a way that a plant-related maximum nutrient solution level in the substrate body is not exceeded. 2. The method according to claim 1, characterized in that the maximum nutrient solution level and the nutrient solution supply be chosen so that during the growing season the air capacity above the nutrient solution is 45 to 75%, preferably 50 to 70%. 3. Device for production horticulture, with at least one filled with expanded clay and / or expanded slate, open on its top vessel ( 10 ), characterized in that the device comprises a device ( 1 ) for adding a nutrient solution from above and a measuring and posing device which ensures that a predetermined maximum nutrient solution level in the at least one vessel is not exceeded. 4. The device according to claim 3, characterized in that it further comprises an overflow device ( 11 ), via which, if necessary, a nutrient solution quantity exceeding the predetermined maximum nutrient solution level is discharged. 5. Apparatus according to claim 3 or 4, characterized in that it is a closed culture system in which the nutrient solution emerging through the overflow device ( 11 ) is collected and returned to the device for adding the nutrient solution. 6. Apparatus according to claim 3 or 4, characterized in that it is an open culture system in which the nutrient solution emerging through the overflow device ( 11 ) seeps away in the vicinity of the at least one vessel. 7. Device according to one of claims 3 to 6, characterized characterized that they continue to have a water reservoir having.