DE19508145C1 - Improving plant-growing soils - Google Patents

Abstract

Method for improving plant-growing soils comprising incorporating a glass fibre fleece into the soil.

Description

The invention relates to a method for improvement a soil used for growing plants.

In the following, not only soils are meant to be under ground existing cultural areas are understood, but also composts or similar materials that are provided for application on such surfaces.

Since time immemorial, attempts have been made to lay the floors on the Agricultural land available to improve to increase plant yield. To this end, it is known to plant nutrients in the soil Feed form of fertilizer. Here, both natural Licher fertilizer used, for example in the Livestock farming in the form of animal excreta accrues, as well as mineral fertilizers, which are handling linguistically referred to as artificial fertilizers.

Over time you have been using such Fertilizers achieve remarkable yield increases can. Despite the application of such fertilizers persist but sometimes significant differences in usability of individual areas, which among other things on under  different soil qualities. Also an increase in fertilizer application does not always result to a corresponding increase in earnings. On Too much fertilizer also leads to ge make sure that precipitation rinses out the nutrients and to pollute waters.

The invention is therefore based on the object of that are used to cultivate plants.

This object is achieved in that glass fiber fleece is worked into the soil as an additive.

Here one makes use of the knowledge that for Well-being of a plant, which in turn is in one precipitates higher yields, not just one proper supply of plant nutrients. Rather, what is important is a well-coordinated one Combination of physical, chemical and mechani properties, such as air volume, rootability, mechanical stability lity and the nutrient ratios belong. Through the The addition of glass fiber fleece allows the pore volume increase, reduce the storage density, the mecha increase the stability of the soil and the soil improvement. Glass fiber fleece exists for the largest Part made of inorganic glass in the form of fibers is present, which are bonded together with a binder they are. The main raw material for such glasses is Quartz sand. When the glass fiber fleece is weathered in the Soil is practically the same as a result Effect as if sand had been added. During the However, the glass fibers of the fleece are weathered in able to structure the soil slightly, but noticeably to change so that the desired positi The characteristics of the soil are more pronounced. The Using a fleece makes handling easier. in the  The glass fibers are non-woven in a bound form before, so that the handling of individual fibers ent falls. The bound form of the fibers, in which the company statistical distribution in all directions the structure of the Soil accordingly.

A glass fiber fleece is preferably used, whose binder has a high urea content points. The binder therefore contains a high content of nitrogen, so that the glass fiber fleece not only for mechanical and physical improvement of the soil serves, but at the same time a certain contribution for nutrient supply.

The glass fiber fleece is preferably used prior to incorporation into pieces with a maximum extension of 40 mm crushed. In particular, its greatest extent is 30 mm or less. There are small fleece Flakes are available with relatively little effort can be worked into the soil and there too lead to a relatively even distribution. Also spreading is made easier because the smaller ones Pieces easier to handle.

The glass fiber fleece is preferably in the region of incorporated into the top 10 cm of the bottom. this is the Room where most of the cultural roots or crops. If the verb you want soil remediation, d. H. the change in its structure tur, is achieved there for most purposes sufficient.

The glass fiber fleece is advantageously used in an amount of 30 to 350 g / m² incorporated. This is a relative one small amount. The share of fiber  fleece in the floor then lies in the alcohol range. Yet is this small amount sufficient to achieve a sustainable to improve the soil.

The glass fiber fleece is preferably used prior to incorporation sprinkled on the floor. One divides the one then bring in two steps. First, the glass fiber fleece spread out and thus evenly distributed. Here, the uniformity of the distribution can be control pretty well. In a second step the distributed glass fiber fleece is then inserted into the ground is working. Conventional can be used for both steps use agricultural techniques and equipment.

In a preferred embodiment, the glass fa servlies, for example, as bales or piles of zer smaller pieces loaded onto a manure spreader and with it on the ground. A shit spreader is used in most agricultural areas drives available to those at cattle farming natural fertilizer accumulating on agriculture spreading usable areas. Of course you can use other devices accordingly. Required is just one way to get the nonwoven pieces, so a solid to spread over the desired area len.

Advantageously, it is also brought into the ground Help of a disc harrow. The disc harrow penetrates about depending on the setting, 10 cm deep into the floor and leads to a certain upheaval in this upper layer tongue, d. H. to a small extent, parts of the Bottom from top to bottom or from bottom to top spent. The floor becomes something at the same time crumbled. In this way it is possible to use the Glasfa servlies with the desired uniformity over the Distribute depth in the ground. At the same time  here still the possibility of the small pieces of the Fleece shred even further what the decay accelerated.

The glass fiber fleece is preferably introduced after a growing season. The fleece can then by the next planting start to ver smell. This will be done over a longer period of time Nutrients released, which are then used for the new planting available.

The invention is illustrated below by means of examples described in connection with the drawing. Here in shows

Fig. 1, the pore volume of the experimental variants,

Fig. 2 shows the percentage decrease in storage densities and

Fig. 3 shows the average CO₂ production.

To investigate the effect of the glass fiber fleece who uses eight different substrates, namely five Soils and three composts according to the following table:

Glass fiber fleece was mixed into each substrate, which had been chopped into pieces, the largest dimension of which was in each case 30 mm. A quantity corresponding to approx. 1500 kg / ha was once entered into substrates 1 to 5 . In a second trial, the amount corresponded to 3000 kg / ha. This corresponds to 150 or 300 g / m². In the case of composts (substrates No. 6 to 8), the amount was reduced due to the low density of the composts, namely with substrate No. 5 (Bk) to 800 and 1600 kg / ha and with substrates No. 7 (Rk) and 8 (ST) at 400 or 800 kg / ha. For reasons of simplification, in the fol lowing the variant with the lower nonwoven portion with the index 5 and the substrate with the higher nonwoven portion with the index 10, that is S₅, S₁₀ or Us₅, Us₁₀, etc. Substrates mentioned without an index are the respective zero variants, i.e. samples without the addition of fleece.

Each substrate was used to determine the pore volume filled in five 100 cc plug-in cylinders. To the Simu lation to approach reality became the test sub strate condensed to its natural density. At the compost became the shaken storage density determined.

The piercing cylinders were down with a thin fleece covered with fabric, as paper filters would have torn.  

The filled piercing cylinders were placed on a sand bed placed and within a week to the top edge slowly saturated with water. Then they were at various suction tensions (pF values). After setting the balance in the individual Suction voltages were used to determine the water content.

The water binding intensity of the soil is above all a function of pore size. It is marked Binding intensity through the water tension must be wound to drain a floor. The Water tension is related in cm water column (WS) wise as a decatic logarithm pF (p = potential, F = free energy of the water) of the water column presses. The determination of the pore size distribution in the Soil is based on conversions of the water tension curve, which is in balance with the water content of the soil indicates different water tensions.

The pore size distribution primarily determines what Soil and air budget of the soil. One differentiates Fine pores (<2 µm), in which the water with <15 bar (pF 4.2) is recorded. This water is there no longer available to the plants (dead water). The Water in so-called central pores (10 to 0.2 µm; pF 2.5 to 4.2) and narrow coarse pores (50 to 10 µm; pF 1.8 up to 2.5), on the other hand, is available to plants. The coarse pores (<50 µm; pF <1.8) usually contain air, because the Water seeps away very quickly. These pores serve there primarily ventilation.

The pF values 1.0, 1.5 and 1.8 were based on ceramic Plates determined using the vacuum method, the pF value 2.5 in the overpressure process in a "Soil moisture" ap parature. The determination of the water content according to pF 2.5 by drying by drying at 105 ° C this gave  Dry weight (Tg). The current storage density was determined from the dry weights minus tare.

To determine the pF value 4.2, moistened Fresh material in plastic rings (1.5 cm high, through knife 2.5 cm) pressed and in the overpressure process in the "Soil moisture" apparatus drained at 15 at.

The different water contents of the filters in the individual pF values and the dry weight of the filter are in the calculation of the water content of the samples received. The volume was corrected with fine sand.

The physical properties of soils are essential pore volume or pore size distribution lung determined. Depending on the soil texture and Bo the structure different.

As can be seen from FIG. 1, the proportion of the pore volume increases with the addition of fleece. Since the root space, especially the rootability and ventilation of the soil is improved. The pore volume is shown in the following table.

When the fleece is applied in the floor, the floor voucher takes lumens too. The coarse pores are increased, fine and Central pores remain essentially constant.

The next factor could be demonstrated that the mechanical stability of the soil improves.

Driving, stepping on and working on floors can be too Soil compaction and thus depending on the soil conditions to more or less clear changes in the air and water balance. Since a fleece addition too interferes with the floor structure, should by pressure set experiments on the effects on structural stability be assessed.

For this purpose, the soil and compost were turned Sample material taken. The sample material became something filled with saturation in the piercing cylinder and to 0.06 bar (pF 1.8) drained. Except for the coarse pores, everyone stayed other pores filled with water. To unwanted wall row The material was then used to minimize exercises into a wide, flat stick cylinder (diameter 12.3 cm, height 1.9 cm) and filled with 26 N / cm² charged. This corresponds approximately to the wheel load of one heavy tractor. The settlement became after 1, 15, 60 and read 120 minutes and based on the starting converted to percent.

The temporal settlement behavior showed a similar progression in all test variants. In the beginning, the settlement was the strongest in all variants and decreased over time. After two hours of loading, the percentage increase in storage density was smaller, the greater the addition of nonwoven, as can be seen from FIG. 2. The changes in the storage density are shown in figures from the following table.

It can be observed that the increase in storage density in all fleece variants is lower than in the zero variants. The through the fleece incorporation achieved loosening of the soil and thus the low re storage density is essentially preserved. The Stability gets bigger.

Soil breathing was another quality factor tries. Soil breathing is defined according to the biological oxidation of organic substances through molecular oxygen. Here arise as End products CO₂ and water. Since the carbon with approx  50% represents the largest share of the organic substance the extent of carbon turnover is considered a reliable feature for recording the overall activity of the aerobic soil organisms. Soil breathing as biological The process depends on the microorganisms and theirs general living conditions. It responds quickly on tillage and cultivation methods and was therefore relatively common for the assessment of okotoxilogi effects of environmental chemicals and crop protection means used (Beck, Th. (1984): Influence of the land management of soil life - VDLUFA publications series, 16, congress volume 1985: 31-46).

To check how a nonwoven can be added to the biolo effect has been tested in the laboratory Equality of external conditions, such as temperature and moisture, which detects potential activity. This will result in food quality results and determined the nutrients and allow a relati comparison of the test variants with each other.

20 g of soil (substrates 1 to 5 ) or 10 g of compost (substrates 6 to 8 ) were weighed into plastic bowls, moistened to 60% of the maximum water capacity and placed on stands in 1 liter grooved glass jars, on the bottom of which 40 ml 0.1 N NaOH solution were filled. The sealed jars were incubated at 30 ° C for 6 weeks. After 2, 9, 17, 23, 37 and 44 days the unused sodium hydroxide solution was titrated from red to colorless with 0.1 N HCl with the addition of 10 ml of 1N Bacl₂ solution and phenolphthalein as indicator solution.

The average CO₂ production in µg per gram and day is shown in Fig. 3.

In the case of the test substrates S, Us and Ts, soil breathing is generally at a very low level due to the very low nutrient contents, low pH values and very small amounts of easily degradable organic substances. The breathing intensity in the sandy substrate (S) is 20.4 µg in the zero variant, in the 5 variant it is approximately the same at 19.6 µg and increases in the 10 variant to 37.1 µg CO₂ _* g ^{- 1} _* d ^-1 on.

In the silty substrate (Us) the CO₂ production reaches 47.6 µg in the zero variant, doubles to 95.6 µg in the 5 variant and is still 51.7 CO₂ _* g ^-1 in the 10 variant _* d ^-1 .

The acid clay (Ts) has a very low value of 5.4 µg in the zero variant, but increases to 68.1 and 55.9 µg CO₂ _* g ^-1 _* d ^-1 in the fleece variants.

Overall, CO₂ production was higher in the basic mineral substrates. In the clay (La) it was 77.9 µg in the zero variant, 127.1 µg in the 5 variant and 133 µg in the 10 variant. In the clayey material (Ta) it was 98.4 µg in the zero variant and in the 5 variant and rose to 152.7 µg CO₂ _* g ^-1 _* d ^-1 in the 10 variant.

The composts have high overall values due to the high content of inorganic substance. However, acid black peat (ST) only reaches about 1/5 of the values of the other two composts. CO₂ production increased with the addition of nonwovens. In the zero variant it was 205 µg, in the 5 variant it was 290 and in the 10 variant it was 315 µg CO₂ _* g ^-1 _* d ^-1 .

The basic composts show the same tendency. In organic compost (Bk) the CO₂ production reached 1202 µg in the zero variant, the 5 variant 1405 µg and the 10 variant 1356 µg CO₂ _* g ^-1 d ^-1 . In bark compost (Rk) the CO₂ production in the zero variant was 1448, in the 5 variant and in the 10 variant 1600 µg CO₂ _* g ^-1 _* d ^-1 .

An increase in the coarse pore volume has a positive effect on the air budget and increases the receptivity Soil for rainwater. Associated with it is a reduction in surface runoff, also a reduction in susceptibility to erosion and increasing the water available to plants. An ab of the narrow coarse and middle pores that the plant-available water is usually not desirable. When using the fleece water capacity generally remains in soils equal. The fleece creates more volume and increases it Coarse pores, all other pore sizes remain un changed.

A reduction in storage density leads to a better rootability and better air supply of the plants, since both the air volume and the Air exchange between soil and atmosphere increased becomes.

Noticeable improvements result in silty-leh moderate floors (floors no. 2 and 3). These are condensed sensitive to compaction since the compressibility increases the proportion of fine grains increases. An increase in coarse pores volumens should therefore favorably affect the air budget and affect the infiltration properties. Slack ge floors tend to ver due to their unstable structure slurry. The fine aggregates disintegrate at Starkre conditions and the subsequent drying leads to shrinkage stung. The resulting surface compaction interrupts gas exchange, hinders penetration of precipitation and thus reinforces the surfaces outflow. These phenomena could be reduced by the addition  not completely prevented by glass fleeces, however be drastically restricted. It could be watched be that when drying in the zero variants Rißbil occurred, but not in the fleece variants. So here by adding a fleece next to one Improvement of the infiltration also in the case of crack formation possible risk of groove erosion can be reduced.

The addition of glass also has an effect on clay soils fiber fleece positive because there is a loosening of the Soil results. Especially in already compressed gusts it is therefore advisable to add a fleece.

Claims (9)

1. A method for improving a soil used for growing plants, characterized in that glass fiber fleece is incorporated into the soil as an additive. 2. The method according to claim 1, characterized in that that a glass fiber fleece is used, the bin demittel has a high urea content. 3. The method according to claim 1 or 2, characterized records that the glass fiber fleece before incorporation into pieces with a maximum extension of 40 mm is crushed. 4. The method according to any one of claims 1 to 3, characterized characterized in that the glass fiber fleece in the area the top 10 cm of the bottom is worked in. 5. The method according to any one of claims 1 to 4, characterized characterized in that the glass fiber fleece in a Quantity of 30 to 350 g / m² is incorporated.   6. The method according to any one of claims 1 to 5, characterized characterized in that the glass fiber fleece before the one work is sprinkled on the floor. 7. The method according to claim 6, characterized in that the glass fiber fleece as a bale or pile shredded pieces loaded on a manure spreader and is applied to the ground with it. 8. The method according to any one of claims 1 to 7, characterized characterized in that the introduction into the ground with With the help of a disc harrow. 9. The method according to any one of claims 1 to 8, characterized characterized in that the introduction of the glass fiber fleece takes place after a growing season.