DE20315770U1 - Building material for e.g. foundations comprises a self-hardening mixture rock granules, gravel, silt, clay materials and recycling material, an additive material functioning as a binder and a biodegradable additive material - Google Patents

Abstract

Building material comprises a self-hardening mixture rock granules, gravel, silt, clay materials and recycling material, an additive material functioning as a binder and a biodegradable additive material.

Description

The invention relates to a building material, consisting of an initial temporarily liquefied, itself hardening Soil additives mixture from aggregates, Recycled material and / or from excavated soil, which by adding Additives in liquefied Form can be introduced and installed and its essentials Properties that can be changed according to the individual uses are or artificial can be created.

The building material is especially for the foundation, backfilling or showering of Builders, line or cable shafts, for fillings, for cavity fillings, for roads, paths and Dams as well for the Suitable for embedding pipes, ducts and cables.

The building material is advantageously used when installing or filling difficult to access Areas in civil engineering, such as B. when complex laying different Media lines (dirty water, rainwater, mixed water, gas, ELT, Drinking water, telecommunications, district heating, etc.) in narrow trenches in inner city Areas where to minimize the trench width and thus the excavation the media lines are essentially vertically aligned or light offset one above the other be relocated as well as for new developments. There is a need the cavities existing between the media lines the filling of the media lines completely and solidify without settling. In known solutions according to the prior art this is done by placing each individual media line in the trench with a suitable one Material for example earth building materials, such as gravel, sand, gravel, compactable excavation material etc.) filled and then this is compressed. Because of the spatial cramped installation conditions compression is rarely successful. It regularly arises badly compressed gusset areas to voids below the pipes, the later mechanical load (e.g. when driven over by road vehicles) to settlement phenomena and subsequently to cracks and breaks in the media lines can.

The building material also finds more Applications such as in the construction of ramparts and dams that protect against flooding serve.

Building materials are known which can be introduced in liquid form by means of pumps in trenches and channels. The disadvantages of these known liquid fillers (twilight) are that the liquid filler has to be made from defined sands with a predetermined and optimized sieve line, hardens relatively slowly (up to several days) and, after hardening, has a strength that is so high, that in certain load situations and laying conditions (e.g. inadequate coverage and / or inadequate backfilling) there is subsequent, sometimes time-delayed damage to the installed pipelines due to uncontrolled load and vibration inputs from the loaded surface. This is the case, for example, if, due to the high strength, the vibrations of road traffic are introduced into the road base in such a way that they reach the pipeline zone largely undamped. This takes place, for example, when the uniaxial compressive strength of the solidified excavation has a compressive strength of> 0.7 N / mm ² after it has hardened and the surrounding soil corresponds to a soil class 3.

Another disadvantage of the known Systems more fluid Verfüllstoffe consists in the fact that under certain environmental conditions (e.g. too high concentrations of water-soluble salts, high levels humic components in excavated soil etc.) very slowly (e.g. degree of hardening after several days <10 %) to not harden and their delayed hardening Ultimate strength often does not correspond to the notified and required value. On The main disadvantage of the known liquid fillers is the very low Cure and the fact that the hardening due to several stochastically influencing factors determined within technologically predetermined time intervals he follows. This prevents sensible and economical installation technologies several lines one above the other in a reasonable period of time with these previously known building materials, because the waiting times until sufficient consolidation becomes too uneconomical Lead to downtimes would.

Liquid filling materials are also known the base of sands with defined sieve lines and bentonite additives (so-called "soil mortar"), which are indeed immediate after backfilling under curing achieve the required final strength. Because of chemical interactions of clayey soil mortar with the adjacent substances or with the sand added to the soil-mortar mixture However, there are regular technological disruptions to sand and groundwater constituents Construction progress as a result of the delayed or unscheduled expiration Curing.

From the DE 197 17 763 C1 is a process for the production of backfilling materials from crushed concrete, masonry, mortar, roof tiles or mixtures thereof, which are crushed to grain sizes <40 mm, whereby the crushed concrete, the masonry, the mortar, the roof tiles or the mixtures thereof with 10 to 50 mass% water, with 0.5 to 5 mass% clay-soda mixture and with 1 to 10 mass% cement or hydraulic lime. The backfill mass created in this way is for the foundation, backfilling or overfilling of structures, cable or cable ducts, for fillings, for streets and paths as well as for single beds suitable for pipes, ducts and cables if the above-mentioned hindrances to the hardening process do not occur due to the bentonite (clay) base used.

Disadvantages of this solution are that the chemical interactions already mentioned affect the setting process can negatively influence and only a relatively narrow range of sands and gravel for the Manufacturing can be used. So this solution excludes the use of excavated materials out. Furthermore, these solutions are sensitive to temperature and also tend to excrete water heavily.

From the DE 198 51 256 C2 is a process for solidifying pollutant-containing, dusty to coarse-grained, non-hydraulic waste materials, earth materials, loose rock or recycled building materials, in which an aqueous suspension is first produced from 50 to 100 g of clay powder per 1 liter of water by intensive mixing. Subsequently, the waste materials, soil materials or the recycled building material are mixed with the prepared aqueous suspension. This is followed by curing and solidification of the mixture, 10 to 40% by mass of clay powder suspension and 1 to 10% by mass of inorganic binder being added to the mixture. Activated concrete is preferably used as clay powder. Cement and / or fly ash is preferably used as the inorganic hydraulic binder. In order to control the hardening process, your mixture is advantageously added to any clay powder binder as a setting accelerator or retarder.

Disadvantages of this solution are the difficult to control setting process and its uncontrollable subsequent hardening as well as the fact that here, in addition to the often very slow to sometimes the liquid mass does not solidify at all even a relatively narrow range of sands and gravel for manufacturing Can be used. Here, too, there is occasional liquefaction based on the addition of activated bentonite and cement as Binder. Due to chemical interactions with the neighboring ones Areas or with the soil or groundwater contained in the soil these mixtures sometimes show disturbances during curing. silty, loamy and clayey soils can with this method based on bentonites not in a technical usable form liquefied become. So this method is not suitable for all occurring Excavation masses in an economical and technically feasible form to liquefy temporarily and as material for the trench filling with the requirements for pipe storage and wrapping available put.

Methods for temporary soil liquefaction, based on the addition of cement suspensions. Such mixtures have the property of post-hardening, so an afterthought Access to such cables is often very difficult and also the vibration and load transmission in such solidified areas takes place undamped and can lead to damage or destruction.

In particular, there is none yet Method of temporary liquefaction, the processing of silty or very clayey soils in liquid form allows. So it happens regularly when using known components liquefaction severe forms of shrinkage when the excavated soil is silty and / or has clay-containing components. The fatigue strength suffers from this of the processed material. So far, such floors have either be replaced or they are limed up, making them mechanically compactable. The However, the disadvantage of this method is that it is often very strong and especially uncontrolled and uneven post-hardening of such limed soils due to chemical reactions of the lime with those contained in each soil Minerals.

The object of the invention is that To eliminate disadvantages of the known prior art and one Building material for use as a liquid Verfüllstoff to propose, the building material should be made from any excavated soil, recycling material, Sands, gravel and other suitable bulk materials can be produced and a targeted adjustment of the final and fatigue strength and a precise control of the curing behavior over the Time, as well as other desired Material properties such as Thermal insulation, watertightness, controlled density etc. with short overall technological setting times enable.

Likewise, those used in Excavated soil contains soil constituents and / or the absorbed Ground and surface water no influence on the mechanical properties of the hardened building material as well as the hardening process and have the setting speed. Also the ones used Components of the building material no additional ecological pollution of the soil and the groundwater.

According to the invention the object is achieved by a building material with the characteristics of the main claim. advantageous Further developments of the invention are the subject of the related Dependent claims.

The innovative building material consists of earth materials with and without mineral aggregates and similar inorganic-mineral waste materials. The material is composed in such a way that the liquefied soil material can be self-compacting, in particular as filler material for pipeline trenches, cavities, or for securing the position when complex piping of several pipes is stacked and slightly offset above one another. The innovati ve building material is also suitable for the production of waterproof layers for flood protection structures and for securing existing dyke structures.

In addition to the earth components there is Building material from a mixture of one or more inorganic-mineral Binders and at least one biodegradable additive based on plants, but also additional inorganic components may contain. Other mineral additives are also so applicable, depending on the desired additional Properties such as Density reduction or water impermeability. These components of the mixture are made flowable with the addition of water and mixed intensely. The viscous mixture is then installed. The hardening and solidification of the building material takes place in one depending on the setting freely adjustable period from a few minutes to several Hours. Despite the proportion of water that enables the system to flow, and helps that the building material after your hardening machinable with simple mechanical means (e.g. a spade) and easily dismantled if necessary is when hardening no shrinkage or subsidence of any significant size, so that no unwanted cracks and voids are created. Another The advantage is that the hardened building material is a variable adjustable water permeability exhibits and also change or produce other important properties in a targeted manner to let. Since the strength of the material can also be adjusted, the material for both the pipe bedding and wrapping be used in the case of the properties already described arrives, but also for special fillings are used with high strength.

In addition to known earth materials, the building material also recycled materials such as concrete, masonry components, mortar, roof tiles or mixtures as well as substances with or without mineral aggregates and inorganic, mineral waste materials added as base material become.

A particular advantage is in the possibility already described, sandy to silty and clayey, so any earth materials the immediate excavation.

As inorganic-mineral binders advantageous cement, lime, plaster and / or natural and artificial Puzzolane used. In addition to the known, good strength properties these substances through comparatively low procurement costs out. Likewise leads the use of these substances at no additional burden on the ecological System.

As an biodegradable additive plant-based cellulose products are advantageous, organic Fibers and / or surfactants etc. used. These organic additives, z. B. on a cellulose basis or using similarly acting, water-retentive Fabrics and / or swellable Materials directly affect the water retention capacity of the Building material. This ensures a homogeneous distribution of the added water in the Soil mix allows. The building material thus remains during of curing evenly flowable without the usual Tendency to water ("bleeding"). Furthermore, this is a homogeneous and controllable setting behavior guaranteed. The excess to Achieving fluidity and Mixing water added for self-compaction is mostly temporarily absorptive through the organic and / or mineral additive and later partly crystalline bound by the binder. The organic matter also causes a change the surface tension of the water, which improves the flowability, the frictional forces of the Water become large enough to overcome gravity and it doesn't become a natural one Segregation comes more.

Due to the beneficial effects of the organic additive, only small amounts of inorganic-mineral binders, such as. B. Lime (EN 459 / DIN 106), cement according to EN 196 or alumina cements are required as strength-building components. The inorganic-mineral binders also allow the pH of the liquid soil to be set in a targeted manner. The combination of the inorganic-mineral binders also causes a reduction in the surface tension of the water and consequently a reduction in the flowability and a controlled initiation of the hardening process. This process is completed when the desired, adjustable final strength is reached. The setting speed, the achievable final strength and other important and desired properties are determined in a determinate manner by the type and amount of the binder components used in combination with the additive. The amounts of the additives mentioned above are, for example, between 1 kg / m ³ and 40 kg / m ^{3 of} liquid soil to be produced, the individual nature and composition of the soil having a corresponding significance.

With the innovative building material there is the possibility of liquefying all z. Z. Known earths, soils, sands, gravel, clays and recycling materials. The most important properties of the hardened building material, such as EV ₂ value, uniaxial compressive strength, bending and tensile strength or the vibration damping behavior of the hardened building material, are set by the targeted combination of the addition materials and the change in the proportions of the mixture components. In addition, there are other relevant properties of the building material, such as water permeability, pH value, thermal insulation, abrasion resistance against excess water, its density, color Exercise etc. can be influenced directly by compound and mixing ratios.

The invention is described below three embodiments set out and explained in more detail by drawings.

Show it:

l : An inner city trench for the laying of several essentially vertically aligned media lines in a sectional view,

2 : A schematic representation of the technology of pipe laying and trench filling with the building material according to the invention

3 : In a highly schematic representation, the cross section of a dam for flood protection with a dike elevation (dam crown made of building material according to the invention) and a dike seal under water with leakage protection technology,

4 : A dam to protect settlement areas at the time of its renovation by means of a core made of RSS liquid soil, made from the old material of the core, which improves the stability of the dam, its resistance to soaking and pressing water, as well as its susceptibility to dike breakage when water overflows,

5 : The use of the innovative building material "RSS - Liquid Soil" for the renovation of dikes at risk.

The 4 and 5 show the possible uses of the innovative building material "RSS - liquid floor" in the area of acute and preventive flood protection.

4 shows the possibility of using the material to quickly and watertightly increase the dike crown and to reinforce and seal the dike if it threatens to soak. The material can reinforce both the dike surface on the land side and the water side, as it hardens under water and can be left in place with a special technology when applied on the water side despite the flowing water.

5 shows the use of the innovative building material "RSS - liquid floor" for the renovation of dikes at risk of function.

Example 1:

In 1 are multiple media lines M (Supply and disposal lines), shown slightly offset one above the other in a narrow pipe trench.

With such a type of installation the following problems arise:

- How should the for the trench filling filler used in classic installation compacts without settling become ?

- How can be avoided in such work that the already routed and therefore below-lying lines during compression of the earth that over it laid cables covered by the force from above are damaged?

- How can be an afterthought Access e.g. for additional house connections when closing a gap each line can be secured at any depth without the overlying ones Influencing lines or difficult and expensive security measures to require?

- How can such a narrow pipe and pipe trench be realized, if usually already for the with classic trench filling necessary compaction process an appropriate working width for the needed Technology is required?

- How can Areas of poor compression or even cavities due to poor accessibility of the compression areas and especially the gusset area of the pipes can be avoided?

- How can Additional expenses for building due to space constraints of the narrow trench and thus cost increases can be avoided ?

- How can with insufficient laying depths and therefore not sufficient frost protection for e.g. the drinking water pipe is still the existing deep space for the complex Laying frost-prone Enough media?

- How can on top of each other horizontal lines in time for subsequent access recognized and correctly classified according to the respective cable type become ?

- How Such a system can be high and high in the future Probability of increasing environmental protection requirements e.g. the safety of the underground conditions against polluting Meet wastewater ?

- How can be ensured that such a construction with one another arranged and apparently fixed supply and disposal lines nevertheless flexible with user requirements that may change in the future can react?

- How can with different ownership, the different Operator with such a solution live without additional Friction with possible construction work or have to put up with the operation of the networks?

The answer to all of these questions gives the innovative building material "RSS - liquid floor" and the one with its Possible use Technologies that can already be seen in part from the illustration above are.

So is l removable that the sidewalk G kept line-free and can be used as a later assembly and work area for lateral access to the installed media lines.

The technology of pipeline construction is in 2 represented schematically: The innovative building material "RSS - liquid floor" can be used in a ready-mixed concrete plant or in another external mix equipment as well as on site. This production can be carried out either continuously or batchwise as in the example shown. In the example shown, the excavation was sampled and the composition of the soil-specific compound was determined on the basis of the analysis values. The results are made available to the respective mixing plant. There it is either introduced as a mixture of water and compound into the mixing vehicle (concrete mixing vehicle) or brought dry into the mixing room without water. As a second step, the relevant soil is added to the mixing room, which is followed by the binder. In the example described, the liquid soil mass mixed according to the specified recipe is brought from the mixing vehicle to the installation in a highly viscous form. There, point supports have already been made from manually strengthened earth material or with specific system-specific aids and the necessary pipes have been laid.

The delivered and highly viscous Liquid soil is used for the position stabilization applied selectively to the pipes laid and sets quickly in the highly viscous form. He also becomes Making the higher Lock that uses the backfill area separate from the installation area and thus decouple technologically. In order to become unnecessary waiting times avoided and the work process accelerated enormously. The liquid soil then required for the refilling of the grave is introduced in a fluid manner and fills so all existing rooms including the gusset area of the pipe support. We fill in the filling level fixes the laser that is used to lay the next pipeline Determine altitude helps. When the bottom height is reached the next Management is the backfill process canceled.

To the technology of pipe laying to be flexible and not big ones street areas longer Tearing up time to have to, the innovative building material "RSS - Liquid Floor" can set quickly can be set. This is how it works after a relatively short time from e.g. 2 hours, about the one just filled Area the next To lay the line.

The filled trench area is in the present Case secured by sheeting. The shoring is still in a liquid state of the building material "RSS - Liquid Soil" can there are no cavities in the trench edge areas either. The excavator can operate mostly over the respective trench due to the narrow and built-in trenches and so all the necessary operations such as setting the sheeting, laying the pipes and pulling the sheeting carry out.

Embodiment 2

3 shows in a highly schematic representation the cross section of a dam for flood protection. By applying the innovative building material "RSS - liquid floor", an increase in the dam crown can be achieved within a very short time 1 be made. On the soaking dam area 3 a layer of the building material can also be applied. These applications serve in particular to actively protect settlement areas against the ingress of floods at the time of acute flood risk.

Effect:

The core of the dam crown from the innovative Building material "RSS - liquid floor" is immediately impermeable to water and off. The landfill waterproof Building material "RSS liquid floor" acts as a closed Mass and is connected and homogeneous.

Benefits:

Large amounts of building material can be very quickly with almost everywhere existing technology (e.g. concrete mixers and concrete pumps) to everyone brought anywhere and installed.

The rapid production of large masses of building material is over the almost everywhere existing systems possible (e.g. concrete mixing plants etc.) possible.

The innovative building material enables easy and quick removal of the material after use.

The building material is a significantly cheaper material (including of installation on site) as the current method of installation with Sandbags. The cost of the still unfilled alone sandbags are higher than the cost of the building material with transportation and installation on site. taking the sandbags first to the filling location transported and there usually by hand must be brought to the place of need.

The innovative building material can be found at Harden water influence without problems and is independent of the weather used.

Example 3:

4 and 5 show examples of possible uses of the innovative building material "RSS - liquid floor" in the area of acute and preventive flood protection through preventive measures or inexpensive dike renovation or new construction if necessary.

4 shows the possibility of the innovative building material for the quick and watertight increase of the dike crown 4 and to reinforce and seal the dike if it threatens to soak. The building material can strengthen both the dike surface on the land side and the water side, since it hardens under water and can be left in place despite the flowing water using a special technology for water-side application.

5 shows the use of the building material for the renovation of dikes at risk of function. An analogue can be used for the new construction of dikes Technology. In the present case, the core of the dike, which often and especially in younger dykes consists of inferior and water-permeable material, is milled out or excavated in a built-in trench and liquefied in a homogenized form, made watertight and in liquid form e.g. B. reintroduced into the core area of the dike by means of pumps.

Despite the very cost-saving construction method still a quality the measure achieved that is not possible with classic construction methods and building materials. The core is waterproof and also improves the statics of the dike. However, the innovative building material "RSS - Flussigboden" secures the dike also against dike breakage, because its high abrasion resistance itself with insufficient dyke height and flooding the dike the usual shot channels in the area the dike crown, from which dyke breaks quickly develop helps to avoid. exemplary Mixtures for the use of the building material for dike renovation and renewal are below specified.

The specific composition is thereby from the respective place of use of the building material and the local one depending on geological and hydrological conditions:

Mix 1:

• Sand 0/2 = 840 kg / m ³
• Surcharge 2/8 = 840 kg / m ³
• Quicklime = 100 kg / m ³
• Cement = 45 kg / m ³
• Water = 280 kg / m ³
• Additive = 0.60 kg / m ³
• Strength after 28 days = approx. 0.55 N / mm ²

Mix 2:

• Sand 0/2 = 750 kg / m ³
• Grain 2/8 = 750 kg / m ³
• Cement = 66 kg / m ³
• Alumina cement = 9 kg / m ³
• Water = 340 kg / m ³
• Limestone flour = 150 kg / m ³
• Additive = 0.50 kg / m ³
• Strength after 28 days = 0.45 N / mm ²

B

mit Baustoff verfüllter Graben (schraffiert)

F

Fahrspturen

G

Gehweg

M

Medienleitungen

RW

Regenwasser

SW

Schutzwasser

T1

Setzen des Verbaus nach Laservorgabe

T2

Setzen der Punktauflager

T3

Rohreinbau auf Punktauflager

T4

Setzen der Haltungsbänke, beginnend mit der „Begrenzungsbank" (bis über

Sohlhöhe RW)

T6

Verfüllung der Rohrleitungszone der SW-Leitung bis zu Sohlhöhe der RW-

Leitung mit Hilfe von Laser und Zollstock

TG

Ziehen des Verbaus bis zur Sohle RW (da Verbau 2-teilig) wird der obere Teil

gelöst und seitlich gelagert

1

Dammkrone

2

Deichverstärkung

3

Deichabdichtung unter Wasser mit Leckwehrtechnik (statt Sandsäcken)

4

Deichkrone

5

aufgenmmener Deichkern, zu innovativem Baustoff verarbeitet,

wasserundurchlässig eingestellt und als Wassersperre wieder eingebaut

6

Betonsteine

7

Deichfuß

8

aufgenommener Deichteil, zu Baustoff verarbeitet, wasserundurchlässig

eingestellt und wieder flüssig verfüllt

9

unter der Oberfläche des Baustoffes eingegossene, hochfeste und kleinmaschige

Kunststoffarmierung (analog Panzergewebe bei Putzflächen)

LIST OF REFERENCE NUMBERS

B

trench filled with building material (hatched)

F

Fahrspturen

G

side walk

M

media lines

RW

rainwater

SW

protection of water

T1

Setting the sheeting according to laser specifications

T2

Set the point supports

T3

Pipe installation on point support

T4

Setting the holding banks, starting with the "boundary bank" (up to

Sole height RW)

T6

Filling the pipeline zone of the SW line up to the bottom height of the RW

Management with the help of laser and folding rule

TG

Pulling the sheeting up to the RW sole (since sheeting is in two parts) becomes the upper part

loosened and stored on the side

1

dam

2

dike reinforcement

3

Dike sealing under water with leak protection technology (instead of sandbags)

4

Deichkrone

5

Recorded dike core, processed into innovative building material,

set impermeable to water and reinstalled as a water barrier

6

concrete blocks

7

dike foot

8th

absorbed dike part, processed into building material, impermeable to water

adjusted and backfilled liquid

9

cast in under the surface of the building material, high strength and small mesh

Plastic reinforcement (analogous to armored fabric for plaster surfaces)

Claims (30)

Building material for the foundation, backfilling or overfilling of structures, backfilling of conduit and / or cable shafts, for fillings, roads and paths as well as for the bedding of pipelines and supply lines and / or complete backfilling of, channels and trenches or the combination of the aforementioned applications, Consisting of an initially liquefied, self-hardening mixture of aggregates, gravel, silt, loamy or clayey materials, recycling material and / or any excavated soil, at least one additive that acts as a binder and at least one biodegradable additive or a mixture of such additives on vegetable or Mixing base, the specific water binding, liquefaction and adjustment of individual material properties enable the hardened building material. Building material according to claim 1, characterized in that as an inorganic-mineral binder cement, lime, gypsum and / or natural and / or artificial Puzzolane can be used. Building material according to claim 1, characterized in that as ecological degradable additive based on organic cellulose, organic Fibers and / or substances containing surfactants are used. Building material according to one of claims 1 to 3, characterized in that that to avoid water secretions and achieve high stability anti-sedimentation a water-binding agent on vegetable Base is added. Building material according to claim 4, characterized in that the water-binding agent is a gelling agent or a methyl cellulose, Carboxylmethylcellulose, plastic dispersion or a fine substance or a combination of the above additives with stone powder is. Building material according to claim 5, characterized in that the amounts of the water-binding agent are variable and dependent on to be liquefied in each case Material and the desired properties are. Building material according to one of the preceding claims, characterized characterized that the water-binding agent with a proportion from 0.1 - 1.00 M% is added based on the weight of water. Building material according to one of the preceding claims, characterized in that to improve the flowability and self-compaction and thus to change the infiltration value K _f (resistance to the infiltration of water) of the building material, a fine material, in particular the finest stone powder or finely ground residues of industrial production, natural and artificial pozzolana or combinations of inorganic stone powder with the finest plastic dispersions etc. is added. Building material according to one of the preceding claims, characterized in that the fine substance is added in a proportion of 30-300 kg / m ^{3 of} liquid soil. Building material according to one of the preceding claims, thereby characterized in that the processing contains more fine substances (silty) Liquefying soils acting substances are added. Building material according to claim 10, characterized in that as liquefying acting substance naphthalenes, surfactants, polyacrylates and / or polycarboxylates or similar acting additives are added. Building material according to claim 10 or 11, characterized in that the liquefying acting substance in concentration ranges of <= 4 mass% is added to the dry weight, the mass fraction of the required structural or technological properties, like viscosity or pupability is determined. Building material according to claim 1 or 2, characterized in that as a inorganic-mineral binder a mixture of Cements according to EN 196 and / or alumina cements and / or deleted or burnt lime depending of the ones you want Properties, especially of the final strength to be set is added. Building material according to claim 1 or 2, characterized in that the ultimate strength of the hardened Building material through the targeted combination of the named binders, Additives and agents etc. is set so that it is the Solubility class (soil class 3 - 4) corresponds and no relevant post-hardening takes place. Building material according to one of claims 1 to 14, characterized in that the building material or at least one component of the mixture is colored with suitable pigmentation agents. Building material according to one of claims 1 to 15, characterized in that your mixture setting accelerators be added. Building material according to claim 16, characterized in that lime, alumina cements (e.g. fondue Lafarge), soda, CaCl ₂ or phosphates or similar substances are added as setting accelerators. Building material according to one of claims 1 to 15, characterized in that the mixture retarders be added. Building material according to claim 18, characterized in that as a retarding agent finest stone powder, stearates or starch products or similar ones Substances are added. Building material according to one of claims 1 to 19, characterized in that that to adjust the water permeability of the building material pore-forming components and / or sealing, swelling components are added. Building material according to one of the above ten claims, characterized in that the finest rock powder or finely ground residues, also combinable with pore formers, are added as the finest constituents. Building material according to one of the preceding claims, characterized characterized in that cellulose products as sealing components, organic and / or inorganic fibers and / or clays added become. Building material according to one of the preceding claims, characterized characterized that the liquid Mixture for thermal insulation and / or modification the density of the building material void-forming substances or void-rich fillers be added. Building material according to claim 23, characterized in that for thermal insulation expanded clay and / or Styrofoam beads and / or air entraining agents or additives having an analogous effect are added. Building material according to one of the preceding claims, characterized characterized that your liquid Mixture for density reduction void-forming substances: or void-rich fillers be added. Building material according to one of the preceding claims, characterized characterized that to inhibit corrosion of the floor against metallic objects your mixture increases pH Substances are added. Building material according to claim 26, characterized in that Ca (OH) ₂ , K (OH), Na (OH) and / or buffer solutions are added to the mixture to inhibit corrosion. Building material according to one of the preceding claims, characterized characterized that the rigidity of the building material by adding solid and / or liquid, stiffness-reducing cavity generator is adjustable. Building material according to claim 28, characterized in that as a stiffness-reducing void formers the mixture expanded clay and / or Styrofoam and / or air-entraining agents or additives having a similar effect are added become. Building material according to one of the preceding claims, which the additives and additives mixed dry or as Dry mix can be provided, after thorough mixing water is added to the dry components.