BE1026508B1 - A bentonite-containing soil improver - Google Patents

Abstract

In a first aspect, the invention relates to the use of a bentonite-containing derivative of a drilling slurry, wherein said derivative is used as, and / or incorporated in a bentonite-containing soil improver. In a second aspect, the invention also relates to a soil improver comprising a bentonite-containing derivative of a drilling slurry.

Description

A BENTONITE-CONTAINING SOIL IMPROVERS

TECHNICAL DOMAIN

The invention relates to soil improvers. The invention also relates to the further processing of derivatives of a bentonite-containing drilling slurry.

STATE OF THE ART

A so-called slurry shield is often used for directional drilling. For this purpose, a bentonite-containing drilling mud is pumped through the drill string to the drilling front. There the slurry mixes with excavated soil to form a drilling slurry. Then, the drilling slurry flows along the outside of the drill string to the entry or exit point of the bore, discharging the excavated soil. The drill slurry forms a slurry shield that lubricates the drill string and stabilizes the borehole.

Incidentally, some of the released drilling slurry can sometimes be purified for reuse. For example, it is passed through a sieve in a first step, where a coarse fraction (> 4mm) of mainly gravel, peat balls and clay balls is split off. Further purification (e.g. via cyclonage and / or centrifuge) leads to an enriched bentonite residue which, if necessary supplemented with water and pure bentonite, can be reused as a drilling mud. Other fractions with a lower content of bentonite, and / or with an excessively high extension with other fine particles are discharged and dumped in the form of bentonite-containing sludge.

Apart from the above, bentonite can be used as a soil improver for improving soil quality.

CN 107 032 933, for example, describes a soil improver with a content of 40% to 45% bentonite. Other components include straw, volcanic ash, fermented cow dung, earthworms and flaxseed residue.

Furthermore, EP 2 209 757 describes a soil improver with a water-swellable material matrix based on an organic polymer. This is supplemented with inorganic solid particles, for example with bentonite particles.

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However, bentonite is an expensive raw material. Soil improvers with a high bentonite content are therefore rarely, if ever, used in a professional context. The present invention seeks to overcome one or more of the above problems. The invention also contemplates a more inexpensive, high-performance bentonite-containing soil improver. Preferably, this soil improver can be manufactured with a composition that is reproducible and / or easy to control.

SUMMARY OF THE INVENTION

In a first aspect, the invention relates to a use according to claim 1, of a bentonite-containing derivative of a drilling slurry. In particular, the said derivative is used as, and / or incorporated in a bentonite-containing soil improver.

The invention also provides for the reuse of bentonite from drilling slurries (= a typical waste product from ground drilling). Such a soil improver would at least be able to increase the moisture-retaining capacity of the soil, as well as to counteract the leaching of minerals. It is important that the excavated soil also contains its own lutum particles and silt particles during a soil drilling. Thus, these particles are also present in the resulting drilling slurry. Preferably, such particles are at least partly comprised by the above derivative of the drilling slurry. They also contribute to the soil-improving effect of the soil improver. The present use makes it possible to utilize these particles after all, instead of having to be removed and dumped at a high cost.

In a further or alternative embodiment according to claim 5, the soil improver comprises two or more batches of bentonite-containing derivatives of drilling slurries. This makes it possible to better stabilize and / or control the composition of the final soil improver.

In a further or alternative embodiment according to claim 8, the soil improver further comprises one or more humus components. Such humus constituents, in combination with bentonite (and any other lutum particles) in the soil improver, can form a clay-humus complex, with a positive synergistic impact on the soil quality.

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In a second and a third aspect the invention relates to a bentonite-containing soil improver according to claim 16, and a method for producing a bentonite-containing soil improver according to claim 20.

DETAILED DESCRIPTION

The invention relates to a use of a bentonite-containing derivative of a drilling slurry, as well as a soil improver comprising such a derivative.

Unless otherwise defined, all terms used in the description of the invention, including technical and scientific terms, have the meaning generally understood by those skilled in the art of the invention. For a better assessment of the description of the invention, the following terms are explicitly explained.

One, de and in this document refer to both the singular and the plural unless the context clearly assumes otherwise. For example, a segment means one or more than a segment.

When around or around this document is used with a measurable quantity, a parameter, a duration or moment, and the like, variations of +/- 20% or less, preferably +/- 10% or less, more at preferably +/- 5% or less, even more preferably +/- 1% or less, and even more preferably +/- 0.1% or less than and of the quoted value, insofar as such variations apply in the described invention. However, this should be understood to mean that the value of the quantity by which the term is used approximately or round is itself specifically disclosed.

The terms include, include, consist of, consist of, include, contain, contain, encompass, encompass, content, contain are synonyms and are inclusive or open terms that indicate the presence of what follows, and do not exclude or prevent the presence of other components, features, elements, members, steps, known from or described in the prior art.

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Quoting numerical intervals through the endpoints includes all integers, fractions, and / or real numbers between the endpoints, including these endpoints.

Soil types can be classified, among other things, on the basis of their grain size composition, in percent by mass of the mineral fraction. A possible classification, applicable to large parts of Belgium and the Netherlands, is based on the following texture classes of particle sizes: lutum (particles with a diameter of less than 2 μm), silt (particles of between 2 μm and 63 μm), sand (particles of between 63 μm and 2 mm) and gravel (particles larger than 2 mm). For example, based on its lutum content, a soil type can be referred to as heavy clay (> 50%), moderately heavy clay (35-50%), light clay (25-35%), heavy clay (17.5-25 %), moderately light sand (12% -17.5%) and very light sand (812%). Soils with a lower lutum content, for example, are classified according to their silt content. Still other suitable classification systems are known to those skilled in the art.

In accordance with the foregoing, sand is a sediment consisting mainly of particles with a diameter between 63 μm and 2 mm. On the other hand, clay mainly consists of small particles, less than 2 μm. Bentonite is a natural clay. Depending on the dominant element, bentonite can be more specifically referred to as potassium bentonite, sodium bentonite, calcium bentonite and aluminum bentonite. I.h.b. swells sodium bentonite sharply when wetted, allowing the material to absorb its own mass of water several times. It can also form a gel-like suspension. The use of bentonite for drilling slurries is based, among other things, on these properties.

In addition to the mineral fraction, agricultural soil typically also has a fraction of organic matter, also referred to as humus. This was caused by the decomposition of vegetable and animal material. On the basis of the chemical extractability, humus is often divided into three so-called humus components: humine, humic acid and fulvic acid. Sandy agricultural soils can contain 3-6% of organic matter. For clayey agricultural soils this is 1-6% of organic matter.

A soil conditioner is a substance or composition designed to improve its quality when applied to a soil, and preferably on

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BE2018 / 5555 longer term. Soil improvers are known to increase the moisture retention capacity of the soil, to prevent mineral leaching, to reduce the sensitivity to sludge, to increase the organic matter content, to influence the pH and / or to be more resistant. making the soil against structure decay. Soil improvers for this and other applications are known per se by the skilled person. In particular, soil improvers are not only used to improve the agricultural quality of agricultural land; they also find application on lawns, in parks, and on sports and recreation fields. The invention is not limited to any of these.

In a first aspect, the invention relates to a use of a bentonite-containing derivative of a drilling slurry. In particular, the said derivative is used as, and / or incorporated in a bentonite-containing soil improver.

As mentioned above, sand mainly consists of particles with a grain size between 63 μm and 2 mm. Typically these are small boulders formed by erosion. Sandy soils have good water permeability. A drawback is that on the other hand they have a low moisture-holding capacity, and that minerals and the like typically leach more easily in sandy soils. However, also in loamy soils and even in clay soils, an important mineral leaching can take place. Clay mainly consists of smaller lutum particles (<2 μm) that are chemically formed. These particles have a plate-like structure with a negatively charged surface. As a result, clay soils are better able to retain water and minerals dissolved in it. Minerals are therefore less likely to rinse out, and they remain available to the plants for longer. Generally speaking, clay soils are more fertile than sandy soils. In dry periods they are also better able to retain water, i.e. they have a greater moisture holding capacity.

Bentonite is a natural clay with exceptional moisturizing properties. In particular, bentonite can swell strongly when wetted (especially sodium bentonite), and it is well able to adsorb ions from eg minerals (especially calcium bentonite). Now, the invention provides for the reuse of bentonite included by drilling slurries, which are a typical waste product from soil drilling. In particular, at least one bentonite-containing derivative of a drilling slurry is reused as, and / or incorporated in a bentonite. 2018/5555

BE2018 / 5555 containing soil improver. In a possible embodiment, the drilling slurry as a whole is used directly as a soil improver. In other possible embodiments, only parts of the drilling slurry are used as a soil improver, or at least processed together with additives into a soil improver. Initially, the invention is not limited to any of these.

Preferably, the above-mentioned bentonite comprises at least sodium bentonite or at least sodium-activated bentonite obtained, for example, by sodium activation of calcium bentonite. After all, the strongest improvement in the soil was found for sodium bentonite and sodium-activated bentonite.

Such a soil improver would at least be able to increase the moisture-retaining capacity of the soil, as well as to counteract the leaching of minerals. The soil improver can be applied to any soil (e.g. clay soils, loam soils, sandy soils and / or other soils). However, the greatest effect was recorded on sand and loamy sand, given the low moisture holding capacity of these soils.

Previously, drilling slurry was a waste product that had to be removed and landfilled. The present invention makes it possible to reuse this relatively inexpensive waste product, which is available in large quantities, for improving the soil. Consequently, the primary sources of bentonite can be better utilized. Incidentally, the bentonite used in ground drilling is typically of very high quality. For example, it does not contain any toxic contaminants, so that the soil quality would not be compromised during soil drilling. This is particularly the case for ground drilling in drinking water areas. In addition, when drilling through an already pure soil, the resulting drilling slurry will not contain any impurities. Preferably, the soil improver can therefore be applied without restriction to any soil, without risk of contamination. Optionally, any contaminants are split from the drilling slurry or eliminated by means of corresponding purification processes.

According to a further or alternative embodiment, the soil improver is applied at a dose of at least about 2 tons of bentonite per hectare, preferably more than 2 tons / ha, further preferably more than 3 tons / ha and with further

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BE2018 / 5555 preferred more than 4 tons / ha: for example about 5 tons / ha, about 10 tons / ha or about 15 tons / ha.

It is important that the excavated soil also contains its own lutum particles and silt particles during a soil drilling. Thus, these particles are also present in the resulting drilling slurry. Due to their size and / or composition, these particles, when added to the soil conditioner, will further contribute to its effect (increased moisture holding capacity, better mineral retention, ...). In a possible embodiment, the aforementioned derivative of the drilling slurry comprises at least a part of the lutum and / or silt particles originating from the excavated soil. Current use makes it possible to utilize these particles after all, instead of having to be removed and dumped at a high cost.

In a possible embodiment, the aforementioned derivative also comprises further additives originating from the excavated soil. For example, the drilling slurry in a soil drilling in calcareous soils will contain many calcium-containing compounds. Preferably at least a portion of these compounds are included by the aforementioned derivative. The resulting soil improver then has a liming effect, as described below. According to another example, the drilling slurry will also contain a large part of organic matter in a soil drilling in, for example, peat-rich areas. Preferably, at least part of that organic matter is therefore included by the aforementioned derivative.

According to a further or alternative embodiment, the derivative comprises at least a sludge fraction. Coarser fractions of e.g. gravel have slightly greater civil stability, so that they can sometimes be left at the site of the borehole. However, this is not the case for sludge fractions (of small particles); typically it must be dumped in specially designed basins. In addition, the sludge fractions usually have a higher content of bentonite. It is therefore advantageous that the derivative comprises at least one or more such sludge fractions. The term sludge and its derivative terms, as used herein, refer to a water-saturated mixture of predominantly lutum and / or silt particles.

According to a further or alternative embodiment, the aforementioned derivative is cleaved from a coarser fraction of the drilling slurry. Thereby the derivative

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BE2018 / 5555 enriched in smaller particles (e.g. lutum and / or silt), which contribute to the effect of the soil improver.

In a non-limiting example, a coarser gravel fraction (> about 2 mm) was split off from the drilling slurry. The aforementioned derivative is then (from) the remaining part of the drilling slurry. Preferably, the derivative still comprises at least part of the lutum, silt and / or sand fractions, originating from the drilling slurry. In another non-limiting example, a coarser sand-gravel fraction (> about 63 μm) was split off from the drilling slurry. The aforementioned derivative is then (from) the remaining part of the drilling slurry. Preferably, the derivative still comprises at least part of the lutumen silt fractions from the drilling slurry. The invention is not limited to any of these. Alternatively, for example, the derivative may comprise one or more coarser fractions of the original drilling slurry.

According to a further or alternative embodiment, the derivative is cleaved from a water fraction of the drilling slurry. An advantage is that the derivative then comprises a greater weight percentage of bentonite, relative to the total weight. The splitting off of a water fraction can be done, for example, by means of pressing and / or filtration. According to a further embodiment, the derivative is obtained by pressing and / or filtering a sludge fraction.

Important differences in composition can exist between drilling slurries from two different soil bores, and even between successive batches of drilling slurry from the same soil drilling. For example, the composition of the resulting drilling slurry will depend on the excavated soil, which in turn varies with a change in soil layers. Of course, this also causes variations in the composition of the resulting drilling slurry. In addition, the composition of the drilling mud, drilling slurry and / or excavated soil is monitored regularly or even continuously. This allows the soil drilling to be optimally controlled (e.g. by changes in the viscosity of the drilling mud). On the one hand, it ensures that the composition of the drilling slurry obtained can be estimated at least partly. On the other hand, this adjustment of the drilling process causes an additional variation in the obtained drilling slurry, e.g. in terms of bentonite content.

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According to a further or alternative embodiment, the soil improver comprises two or more batches of bentonite-containing derivatives of drilling slurries. The present invention thereby makes it possible to manufacture a soil improver with a composition that is reproducible and / or which is easy to control. This, through a well thought-out combination of different batches of drilling slurry with an at least partially known composition. In a non-limitative example, a generic soil improver can be formed, with the composition as constant as possible.

According to a further or alternative embodiment, said batches have been selected, taking into account their composition, an intended cultivation crop and / or an intended destination soil. Optionally, an analysis of the soil on which the soil improver will be applied is taken into account. In a non-limitative example, a soil improver can be made to measure, with contents of different components located close to desired values. Optionally, the composition is further fine-tuned by adding pure components.

According to a further or alternative embodiment, the soil improver further comprises one or more additives. This makes it possible to further expand its soil-improving effect.

According to a further or alternative embodiment, said additives comprise one or more humus components. For example, the additives can include humine, humic acids and / or fulvic acids. Addition of this can stimulate the absorption of nitrogen and phosphorus by plants. Also important is a possible synergistic effect of the bentonite (and any other lutum particles) with the added humus components; together they can form a clay humus complex. Such complexes stabilize the soil against erosion, among other things. Clay-humus complexes also provide greater airiness of the soil and stimulate soil life. The mineral nutrients are also better retained. This generally results in greater soil fertility.

According to a further or alternative embodiment, the said additives comprise calcining substances. Such liming materials are, inter alia, included with agricultural lime, which is known to the skilled person. According to a non-exhaustive

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BE2018 / 5555 example concerns a mixture comprising calcium carbonate, calcium oxide and / or calcium hydroxide. The effect of liming is that the acidity of the soil decreases, making the soil more airy. It also counteracts the acidifying effect of acid rain and some fertilizers. As mentioned above, the derivative of the drilling slurry may already comprise calcining substances.

According to a further or alternative embodiment, said additives comprise a spice mixture.

According to a further or alternative embodiment, the said additives comprise mineral fertilizers or fertilizers. The additives may include nitrogen (N), phosphorus (P) and / or potassium (K) fertilizers. The additives may include compound fertilizers, for example, any mixture of the foregoing, such as NPK fertilizers, NP fertilizers and / or PK fertilizers, according to desired / appropriate ratios. Such mixed fertilizers play a major role in agriculture and horticulture. The addition of fertilizers - in a general sense - to the soil improver, already allows to meet the fertilizer requirement for a subsequent growth period. Together with the other components of the soil improver, these can be spread in the same pass. In a possible embodiment, the fertilizers are added, taking into account an intended cultivation crop and / or an intended destination soil.

According to a further or alternative embodiment, said additives comprise biostimulants. These are active molecules and / or micro-organisms that influence natural processes in the soil and / or in plants. In addition, they help the plant with the absorption of nutrients. In this way they have a positive influence on the growth and development of the crop. In addition, biostimulants can increase the resistance of the plant to various stress factors, such as drought. Preferably, the additives include biostimulants that increase plant resistance to drought. These biostimulants show a synergistic effect (in terms of drought resistance of crop and soil), when combined with the bentonite in the soil improver.

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According to a further or alternative embodiment, said additives comprise root stimulants. These have a synergistic effect with the humic and fulvic acids.

According to a further or alternative embodiment, said additives comprise biological components such as biological pesticides. Preferably, the soil improver can be composed entirely of biological components. Further preferably, the present invention allows to formulate both biological and non-biological soil improvers.

According to a further or alternative embodiment, said additives still comprise trace elements.

In an agricultural context, not only the optimally administered amount of bentonite, but also, among other things, the optimum acidity and the optimally administered amount of humus components strongly depend on the soil type and the intended agricultural crop. According to a further or alternative embodiment, at least one additive is included in a specific amount, which amount is determined on the basis of a composition of the aforementioned derivatives or derivatives, on the basis of an intended cultivation crop and / or on the basis of an intended destination soil. This makes it possible to very precisely regulate the moisture holding capacity, the acidity and the availability of nitrogen and phosphorus, according to the cultivation crop / destination soil.

According to a further or alternative embodiment, the said additives comprise nutrients, minerals and / or trace elements that are necessary for specific crops in the vegetable and fruit cultivation, or in certain soil types. These are then preferably added, taking into account an intended cultivation crop and / or an intended destination soil.

According to a further or alternative embodiment, said additives still comprise rubble, e.g. soil rubble, stone rubble and / or concrete rubble. It is preferably fine rubble, with a diameter of at most 2 mm, more preferably less than 2 mm. Debris is a cheap filling material. This allows the soil conditioner to be spread more evenly.

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In a second aspect, the invention relates to a bentonite-containing soil improver. In particular, the soil conditioner comprises a bentonite-containing derivative of a drilling slurry. Preferably said soil conditioner is in accordance with the above-described use. The same characteristics can be adopted and the same advantages can be repeated.

According to a possible embodiment, the soil improver has a clay content of at least 1% and at most 100%, further preferably at most 90%, more preferably at most 80%, more preferably at most 70%, more preferably at least 2%, more preferably at least 3%, more preferably at least 4%, more preferably at least 5%, and further preferably at least 10%. In a non-limiting embodiment, the soil conditioner comprises between 5% and 40% clay based on the total dry matter weight. Montmorillonite (a major constituent of bentonite) preferably occupies at least part of this lutum content. More preferably, however, at least another portion of the lutum comes from the ground excavated during drilling, rather than from the bentonite in the drilling mud. According to a possible embodiment, the soil improver has a bentonite content of at least 1% and at most 100%, more preferably at most 80%, more preferably at most 60%, more preferably at most 40%, more preferably at most 20%. According to a non-limiting embodiment, the soil conditioner comprises between 1% and 12% bentonite based on the total dry matter weight.

According to a possible embodiment, it concerns a biological soil improver.

According to a further or alternative embodiment, the soil improver is substantially liquid. An advantage is that the water from the drilling mud can also be reused. In particular, that water should not be discharged or purified. Such a liquid soil conditioner could be administered in a similar manner as slurry. Possibilities are surface fertilization or fertilizer injection (e.g. via a trench coulter fertilizer, a sod fertilizer or a trailing hose fertilizer). It is not necessary to dry out, filter and / or press the drill slurry to a substantially solid form. Optional stabilizers (e.g. fatteners)

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BE2018 / 5555 added to stabilize the soil improver, eg to prevent settling of a solid fraction.

According to a further or alternative embodiment, the soil improver is substantially solid, e.g. granular or powdery. An advantage is that the bentonite content is higher. The soil improver can also be transported at a relatively lower cost for the same amount of bentonite.

According to a further or alternative embodiment, the soil improver further comprises one or more humus constituents, liming substances, fertilizers, a herbal mixture and / or trace elements. In addition, the same benefits as above can be retained.

In a further aspect, the invention further relates to a method of producing a soil conditioner, in accordance with the use described herein. The same characteristics can be adopted and the same advantages can be repeated.

In what follows, the invention is described by means of non-limiting examples illustrating the invention, which are not intended or should be interpreted to limit the scope of the invention.

Example 1

According to a non-limiting example, the drilling slurry obtained from a borehole consists of about 70% water and about 10% bentonite (relative to the total weight). The drilling slurry is now pressed, with separation of pressurized water. The compressed water is purified and then discharged. The remaining substantially solid fraction still contains approximately the same absolute amount of bentonite. This fraction is now used directly as a soil improver, at an amount of approximately 15 tons of bentonite per hectare.

Example 2

In a non-limiting example, the present soil conditioner comprises about 13% clay (including bentonite) and about 54% clay, relative to the total weight. The remaining components include sand, gravel and water. When

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BE2018 / 5555 administered at a dose of 1.5% on a sandy bottom (with a sand fraction of approx. 80%), the moisture holding capacity increases by approx. 2%.

In an alternative example, the sand and gravel fractions were separated by filtration, centrifuge and / or cyclonage.

Example 3

According to a non-limitative example, the present soil improver is substantially liquid. It has a bentonite content of 10-15% (relative to the total amount of dry matter), supplemented with humic acids and fulvic acids, as well as with a concentrate of herbal extracts.

Example 4

According to a non-limitative example, the present soil improver is solid, in particular granular or powdery. The soil improver comprises about 10-15% of bentonite (relative to the total amount of dry matter), with added granules of humic acids and fulvic acids, as well as a concentrate of various herbal extracts.

It is believed that the present invention is not limited to the embodiments described above and that some modifications or changes to the described examples can be added without revaluating the added claims.

Claims (20)

CONCLUSIONS A use of a bentonite-containing derivative of a drilling slurry, characterized in that the said derivative is used as, and / or incorporated in a bentonite-containing soil improver. The use according to the preceding claim, characterized in that the derivative comprises a sludge fraction. The use according to any one of the preceding claims, characterized in that the derivative is cleaved from a coarser fraction of the drilling slurry. The use according to any one of the preceding claims, characterized in that the derivative is split off from a water fraction of the drilling slurry. The use according to any one of the preceding claims, characterized in that the soil improver comprises two or more batches of bentonite-containing derivatives of drilling slurries. The use according to preceding claim 5, characterized in that said batches are selected, taking into account their composition, with an intended cultivation crop and / or with an intended destination soil. The use according to any one of the preceding claims, characterized in that the soil improver further comprises one or more additives. The use according to preceding claim 7, characterized in that said additives comprise one or more humus components. The use according to any of the preceding claims 7 and 8, characterized in that said additives comprise calcareous substances. The use according to any one of the preceding claims 7 to 9, characterized in that said additives comprise a herbal mixture. The use according to any one of the preceding claims 7 to 10, characterized in that said additives comprise mineral fertilizers. The use according to any one of the preceding claims 7 to 11, characterized in that said additives comprise biostimulants. The use according to any one of the preceding claims 7 to 12, characterized in that said additives comprise root stimulants. The use according to any one of the preceding claims 7 to 13, characterized in that said additives comprise biological components. The use according to any of the preceding claims 7 to 14, characterized in that at least one additive is included in a specified amount, 2018/5555 16 BE2018 / 5555 which quantity has been determined on the basis of a composition of the aforementioned derivatives or derivatives, on the basis of an intended cultivation crop and / or on the basis of an intended destination ground. 16. A bentonite-containing soil improver, characterized in that the soil improver comprises a bentonite-containing derivative of a drilling slurry. The soil improver according to the preceding claim 16, characterized in that the soil improver is substantially liquid. The soil improver according to preceding claim 16, characterized in that the soil improver is substantially granular or powdery. The soil improver according to any one of the preceding claims 16 to 18, characterized in that the soil improver further comprises one or more humus constituents, liming materials, fertilizers, a herbal mixture and / or trace elements. A method of producing a bentonite-containing soil improver, characterized in that the soil improver is produced on the basis of a bentonite-containing derivative of a drilling slurry.