DE202005014319U1 - Process to renovate and repair building foundations and insulate against water ingress by injection of sealing agent - Google Patents

Abstract

In a process to renovate and repair and insulate the foundations of a building against the ingress of moisture, a series of holes are drilled from inside the building foundations into the surrounding sub-soil. A semi-liquid agent is injected through the holes into the space around and under the building. The semi-liquid agent subsequently hardens and is a combination of silicon dioxide and an aluminium silicate.

Description

The present invention relates to buildings or building parts, in particular masonry, concrete parts and the like which are repaired, especially drained and / or moisture-insulated.

Buildings and Parts of the building, in particular underground, in contact with soil building or building parts are often exposed to moisture and / or salts exposed. As a result, not inconsiderable damage to the building often occurs.

Out This reason is the drainage of buildings or, more precisely said, the repair of damp and salt damaged masonry still a problem that is difficult to solve which again and again due to the generally prevailing uncertainty Discussions leads. Especially in the field of repair of old buildings this Work area plays a central role in many objects, It is also economical as well as for the individual homeowner a particularly important topic. A few years ago, the federal government in the context of the funded by her so-called monument research also launched a project on this topic. there could be gained valuable knowledge, which today a relative reliable assessment of the individual processes or process variants allow. After having given corresponding characteristics for each It is also possible to finance achievable objects to achieve.

If the theme of building drywall more appropriate with the term the restoration of damp and salt-damaged masonry circumscribed are, are exactly the two main cause of damage been called, namely the moisture on the one hand and the salts on the other. Because only if it succeeds in the moisture balance and in the salt balance to reasonably intervene in a building, a meaningful and economical problem solution can be achieved. It can you first notice that the entire problem always with the moisture absorption of the structures, especially in the ground-touched Foundation masonry area, begins. It is there in particular a capillary water absorption, which by pressure (eg leachate, Hangwater etc.) reinforced can be. Already the touch a non-sealed masonry with normally moist soil (ie soil with usual Soil moisture) may already suffice that enough moisture is capillary is taken in order to "get started" the actual problem. Get through the water intake then gradually also salts in the building material, which are distributed in the masonry and accumulate in the evaporation zones. With appropriate concentration then these salts can other mechanisms an additional Cause moisture penetration. In essence, here must the hygroscopic Water absorption and the condensation or condensation are addressed. In these mechanisms, the water is not initially taken up liquid, but stored as water vapor and liquefied in the pore system. It is basically So between a so-called "liquid water intake" on the one hand and a so to speak "gaseous water absorption" from the ambient air On the other hand, the weighting of the individual Mechanisms for each object is different. In detail can The following water intake mechanisms are distinguished, namely the Capillary water absorption without pressure, the water absorption under pressure (eg by seepage, slope or layer water), the hygroscopic Water absorption by salinity, water absorption by capillary condensation (Sorption) and the water absorption by condensation (condensation water).

The most important damage to the masonry caused by moisture and salt can be the following: frost damage, reduction of heat damping through water absorption and thus increased risk of condensation, shell formation due to hygroscopic swelling and shrinkage in the vicinity of building materials, salt damage due to crystallization, damage due to hydration Salts, damage caused by frost damage, increased equilibrium moisture due to hygroscopic effects, binder conversions and salt formation caused by the action of acidic exhaust gases (eg SO ₂ and SO ₃ ) on acid-sensitive binders (eg lime) and the associated driving phenomena during sulfate formation (For example, so-called "sulphate rubbing" by Ettringitbildung) and damage by microorganisms that can go on well-moistened building material surfaces ge very well. The above list is certainly not complete; however, it clearly shows the complex area that is addressed in the context of the present invention.

While in new construction projects underground parts adjacent to the ground can be provided with an outer insulating layer (eg of bitumen) or in problem areas with elevated groundwater levels a watertight concrete tub ("white bath") can be provided from the outset feasible only in new buildings, whereas in older or existing buildings or parts of buildings in the case of moisture damage subsequent measures for adequate sealing or repair, especially draining or moisture insulation, only with erhebli chem effort can be realized.

One Prior art method is that of moisture affected building parts, especially the basement area of the building, completely uncovered or auszuschachten and then apply a subsequent insulating layer. This process is very time consuming and costly, with the case problems with the bottom plate at high groundwater levels an external insulation at all is not feasible. In addition, must in case of damage the insulating outer layer or if there is an increase in groundwater, if necessary, improvements the insulating layer are made, which also only very problematic feasible are.

Farther So-called mechanical processes are known in which the masonry by sawing, by pruning, by wall exchange or underpinning as well separated or sealed by the ramming of corrugated sheets, etc. shall be. Such a procedure always provides a considerable Engaged in the masonry and can cause major problems in terms of Statics lead.

Of others are known as injection methods, which under Use of chemical materials are carried out immediately be injected into the existing walls under pressure or insulation of the masonry against moisture. A disadvantage of this However, the procedure is that in general not nationwide for one adequate insulation can be provided and beyond due to the materials used relatively large costs arise. Also, the application of such a method in the groundwater area not without problems.

Similarly, injection methods are known which operate with the inclusion of the surrounding soil and / or filling material for sealing, wherein a hardening substance is pressed under pressure into the soil and / or the filling material. Such a method is for example in the DE 102 21 528 A1 described. The disadvantage is that the materials mentioned there do not always ensure a permanent seal, especially not at high water levels. Another disadvantage is that the method described there must be carried out in several stages.

Finally are from the prior art also so-called multi-stage injection process first known Holes are to be entered into the dry-to-be-drilled masonry, which subsequently be filled with a particularly flowable injection mortar have to, followed by the injection of the actual active ingredient, in particular Silicone compounds or alkali silicates, with difficult Conditions, especially at high moisture levels and high relative humidities, the drug systems are activated have to. The disadvantage here are the relatively expensive active ingredients or Chemicals, in particular silicone microemulsions, as well as the multistage of the procedure.

To further details relating to dehumidifying and draining of building parts or Masonry can be particularly referenced on the masonry calendar 2001, 26th year, Ernst & Sohn Publisher for Architecture and Technical Sciences GmbH, Berlin, 2001, publisher: H.-J. Irmschler and P. Schubert, ISBN 3-433-01438-8, ISSN 0170-4958, Pages 225 to 254 "Dehumidification and drainage of masonry "(Helmut Weber, Ebersberg), as well as the literature reviewed there.

The The problem underlying the present invention is therefore therein, the repair, in particular the drainage and / or Moisture insulation of buildings and / or building parts, such as masonry, concrete parts (eg concrete walls, concrete ceilings, concrete floors, etc.) and the like, to improve that the aforementioned disadvantages The prior art at least largely avoided or at least toned down should be.

The Applicant has now surprisingly found that one can solve the above-described problem by using a curable suspension of a hydraulic binder in a so-called injection process, the suspension in addition to at least one hydraulic binder, in particular cement, preferably Portland cement, as well as water a combination of silica SiO ₂ and at least one alkali metal silicate. Such a suspension is suitable for draining or moisture insulation of damp or salt-damaged buildings or building parts, since an efficient sealing or insulation of the buildings or building parts concerned can be achieved in the context of a single-stage injection, at the same time achieving good strength after curing which at the same time contributes to an improvement in statics.

The subject matter of the present invention is thus a repaired, in particular drained and / or moisture-insulated building and / or building part, in particular masonry, concrete part and the like, which is obtainable by a repair process, in which initially hollow parts are to be repaired in the building parts space channels are introduced and subsequently into the cavity channels a curable suspension of a hydraulic binder is injected, wherein the curable suspension in addition to at least one hydraulic binder (and of course water) also contains a combination of silica SiO ₂ and at least one alkali metal silicate.

With In other words, the subject of the present invention are buildings and / or Parts of the building, in particular masonry, concrete parts (eg concrete floors, concrete ceilings etc.) and the like generated by the above-described method repaired, especially drained and / or moisture-insulated are.

Thus, the subject of the present invention is a building and / or building part, in particular masonry, concrete part and the like, wherein the building and / or building part repaired, in particular drained and / or moisture-insulated is characterized in that in the building and / or building part cavity channels are introduced, wherein in the cavity channels a curable suspension of a hydraulic binder, in addition to at least one hydraulic binder also contains a combination of silica SiO ₂ and at least one alkali silicate, preferably a water glass, injected and allowed to cure. As described below, the cavity channels are generally introduced in the form of bores. In this case, the cavity channels, in particular holes, introduced in such a way in the repaired building and / or part of the building that the cavity channels are generated by the repaired building parts through to the adjacent to the repaired parts of the building soil or created, so that the suspension through the Cavity channels through is injected into the adjacent to the building and / or part of the building soil.

According to a particular embodiment of the present invention, the present invention relates to a building adjoining and / or surrounded by earth and / or building part, in particular masonry, concrete part and the like, wherein the building and / or building part is repaired, in particular drained and / or moisture-insulated thereby in that in the building and / or building part cavity channels, in particular in the form of holes, are introduced through the repaired building and / or building parts through to the adjacent soil, in and through the cavity channels through to the adjacent soil a curable suspension of a hydraulic binder is injected such that the injected through the cavity channels suspension at least substantially completely covers the adjacent to the ground surface of the repaired building and / or building part, wherein the curable suspension next least s a hydraulic binder also contains a combination of silica SiO ₂ and at least one alkali metal silicate, and the injected suspension is subsequently allowed to harden.

The present invention applied repair method is suitable for use in relation to at least partially subterranean or at least partially adjacent to ground buildings or parts of buildings, ie for use in relation to such buildings or parts of buildings, which are in contact with soil, since the adjacent soil in the repair, in particular draining or moisture insulation, is included. Because the curable suspension of hydraulic binder, silica SiO ₂ and alkali silicate and water is injected through the cavity channels into the soil adjacent to the affected parts of the building so that there is a moisture barrier between the affected building part (eg masonry, concrete wall, floor slab, etc.). On the one hand and adjacent soil on the other causes, as described in more detail below.

in the Connection to the injection is allowed to cure the suspension, so that solidification the injected suspension, and in this way one alike Improvement of the statics is realized. It arises on the with the earth in contact with the ground to be repaired part of the building an insulating or separating layer, which is the building part to be repaired separated from the adjacent soil and due to their impermeability to water before further moisture and / or salts from the soil protects or shields.

As in the following even closer described, the cavity channels, in particular with regard to their number, their spatial Expansion, their arrangement or spatial distribution to each other etc. in such a way that the statics of the moisture and / or salt damage affected building and / or building parts not impaired becomes.

As described below, can with the invention used Repair procedures not just vertical moisture barriers be realized (eg on masonry of all kinds, concrete walls, etc.), but also produces so-called horizontal moisture insulation who the (eg on floor slabs, concrete floors, concrete floors, masonry of any kind, etc.).

In general, the cavity channels are introduced or vorgese in the form of holes hen. In this case, the cavity channels, in particular the bores, are introduced into the parts of the building to be repaired in such a way that the cavity channels, in particular bores, are produced or applied by the parts of the building to be repaired into the soil adjoining the parts of the building to be repaired, so that the suspension of the hydraulic binder , as defined above, is injected through the cavity channels into the soil adjoining the parts of the building to be repaired and in this way passes between the building part and the earth, thus forming an efficient, water-impermeable barrier layer ("insulating layer") after hardening , Thus, not only the previously applied cavity channels or bores are completely filled with the suspension, but the suspension is thus injected through the cavity channels or bores through to or virtually behind the surface of the part of the building to be repaired, so that the Suspension at least substantially completely covers the area adjacent to the ground surface of the repaired building part. In this way, the affected or repaired building part is completely separated from the ground. After curing of the suspension results in the affected building part against moisture and / or salinity insulating layer on the outside of the affected building part, ie the adjacent to the ground outside of the affected part of the building is completely shut off or isolated with respect to the adjacent soil; As a result, no new water can impinge or act on the building part, and the affected part of the building, z. B. the affected masonry, can thus dry out of residual moisture. Due to the fact that the adjacent soil is included in the injection so to speak, an additional stabilization of the static is achieved because the adjacent soil, so to speak generates a back pressure, which stabilizes the whole. After curing of the injected suspension results in an insulating moisture barrier between adjacent soil and affected part of the building.

By the use of the special suspension of hydraulic binder with the combination of silica and alkali silicate (s) will not only one impermeable, but also a structurally stable and strong separation or insulating layer in only one operation or in only one injection process created without it elaborate pre and / or Nachinjektionen with expensive specialty chemicals requirement.

in the In general, the method used according to the invention will be so carried out, that in the affected part of the building (For example, masonry, floor plate, etc.) a plurality of cavity channels, in particular Drilling, introduced or created. This is especially the number of cavity channels and / or the distance of the cavity channels to each other selected such that the through the cavity channels through to the soil injected into the suspension the ground adjacent area (ie the outside) of the part of the building to be repaired (For example, masonry, floor plate, etc.) at least substantially completely covered and in this way an efficient and full-surface moisture barrier or Insulation layer forms.

in the in general, the curable suspension used according to the invention injected in such an amount that the resulting, on the outside adjacent to the ground of the part of the building to be repaired Isolation or barrier layer has a thickness of 0.1 to 200 cm, in particular 1 to 100 cm, preferably 5 to 50 cm.

in the In general, the cavity channels, in particular holes, with diameters of 10 to 50 mm, in particular 20 to 30 mm, in the affected part of the building brought in. In this way it is ensured that the static not impaired is injected, but at the same time a sufficiently large amount of the suspension can be.

in the In general, the suspension is injected under pressure. It will in particular a pressure of at least 0.5 bar, in particular at least 1 bar, preferably at least 2 bar, more preferably at least 3 bar, created.

As previously described with the present invention both horizontal seals as Vertical seals can be realized. This is a big advantage of the present invention. In the case of horizontal seals can Also so-called floor panels of buildings are subsequently isolated, which According to the prior art, or at best only very limited possible. This must be one particular advantage of the present invention can be seen.

According to one particular embodiment of the present invention may be the injection of the curable Suspension a pre-injection of a mineralizer, in particular preceded by an alkali silicate. This can be especially true in the case of horizontal seals (eg floor slabs) would be an advantage especially at high groundwater levels. As a mineralizer can For example, the same alkali metal silicate are used as it in the context of the invention used curable Suspension is used. Of course, other mineralizers be used.

in the Within the scope of the present invention, those in the affected building introduced cavity channels, in particular holes, finally with a mortar, in particular a silicate mortar, be closed. After all it can also be provided on the inside of the building (ie on the away from the ground side of the affected building part) subsequently a finishing plaster (eg a so-called restoration plaster), where possible permeable to moisture should be, so that the residual moisture from the damp Building Feature, especially masonry, etc., can escape.

As described above, a special feature of the present invention is that for sealing purposes, a curable suspension of a hydraulic binder is used, which in addition to the hydraulic binder, in particular cement, preferably Portland cement, and of course water a combination of silica SiO ₂ and at least an alkali silicate. Due to the special composition, a barrier layer or insulation is produced in only one injection process, which at the same time is water-impermeable and, on the other hand, has sufficient stability or strength after curing.

What As far as the hydraulic binder is concerned, preferably cement, in particular Portland cement, for use. In this case will the invention used curable Suspension also referred to as so-called "cement slurry".

To the Concept of hydraulic binder can be referenced, for example be on Römpp Chemielexikon, 10. revised Edition, Georg Thieme Verlag Stuttgart / New York, Volume 1, 1996, pages 433/434, keyword: "binder", as well as the there Refereed literature. Accordingly, as hydraulic binders denotes such binders that set under water, such as z. As cement and lime while such binders that cure only in air ("air binder"), such as. As gypsum, anhydrite, etc., as so-called non-hydraulic binders are called. For further related details can be referred to the aforementioned reference.

As far as the term of the cement is concerned, reference may likewise be made to Römpp Chemielexikon, 10th revised edition, Georg Thieme Verlag Stuttgart / New York, Volume 6, 1999, pages 5049 to 5051, keyword: "Cement", and the literature cited therein , Cement is therefore the name for finely ground hydraulic binders, ie those mineral substances which harden stone-like under water uptake in air and even under water and are water resistant after curing. Cement consists predominantly of calcium silicates, calcium aluminates and calcium ferrites, ie of CaO with SiO ₂ , Al ₂ O ₃ and Fe ₂ O ₃ in different proportions, which "burn" the raw materials (eg limestone, clay, limestone marl, clay marl etc.) at temperatures up to approx. 1,500 ° C in clinker. For further details in this regard, reference may be made to the above references.

As for the Portland cement preferably used according to the invention, this is a hydraulic binder which consists of a finely ground mixture of Portland cement clinker and calcium sulphates (eg gypsum or anhydrite) and which, after mixing with water, both in the air and hardened under water and also keeps its strength under water ("water mortar"). For the preparation of Portland cement mixed z. As lime and clay-containing raw materials (eg., Limestone, clay, limestone, Tonmergel etc.) to each other such that the raw material mixture in addition to SiO ₂ , Al ₂ O ₃ and Fe ₂ O ₃ from the clay content between about 75 and about 79 Wt .-% CaCO ₃ contains. For further details in this regard, reference may be made to Römpp Chemielexikon, 10th revised edition, Georg Thieme Verlag Stuttgart / New York, Volume 5, 1998, pages 3530/3531, keyword: "Portland cement", as well as the literature reviewed there.

In general, the amount of hydraulic binder, preferably cement, in particular Portland cement, can vary widely in the suspension used according to the invention. In general, the hydraulic masterbatch used for the preparation of the suspension used according to the invention contains the hydraulic binder, in particular cement, preferably Portland cement, in quantities of 100 to 750 kg / m ³ , preferably 200 to 500 kg / m ³ . Nevertheless, it may be necessary, depending on the circumstances or application, to deviate from the aforementioned quantities.

In addition to the hydraulic binder, in particular cement, preferably Portland cement, and water and silicon dioxide SiO ₂ and at least one alkali metal silicate, the suspension usable according to the invention may additionally contain additives, in particular inorganic based additives, such as concrete additives and / or aggregates. The curable suspension used according to the invention preferably consists only of inorganic constituents, in particular only of the components hydraulic binder (in particular cement, preferably Portland cement), silicon dioxide SiO ₂ , alkali metal silicate and water. Provided Further additives should be provided, in particular concrete additives and / or concrete aggregates, these should be inorganic based. Herein, a great advantage of the present invention is to be seen as a purely mineral cement mixture or cement slurry is used which contains essentially no organic based additives, in particular no organically based concrete admixtures (eg no organically based concrete plasticizers, retardants, solidification and hardening accelerators, injection aids, concrete sealants and the like). This is a tremendous advantage, in particular with regard to the costs, but also with regard to the setting behavior.

With in other words, is the inventively used curable Suspension or cement slurry preferably pure mineral nature; such a purely mineral Suspension or cement slurry may, as previously described, optionally other inorganic based hydraulic Binder and inorganic based concrete additives and / or Inorganic based concrete aggregates contain, contains however, no organic based concrete admixtures.

Of the Concept of concrete admixtures designated according to DIN 1045 (07/1988) finely divided concrete additives, which affect certain concrete properties and as volume components to take into account. Mainly mineral admixtures, especially minerals, blast furnace slags, trass, Fly ash, bentonite, etc., as well as pigments or cement paints, such as z. As iron oxides, chromium oxides, titanium dioxides and carbon blacks. The term The concrete admixtures should not be confused with the concept of Concrete additive, as described below.

By contrast, the term concrete aggregates refers to aggregates of natural or artificial, dense or porous rock, in special cases also of metal, with particle sizes suitable for concrete production in accordance with DIN 4226, parts 1 to 4 according to DIN 1045 (07/1988). a distinction is made between concrete aggregates for heavy concrete (grain density above 3.2 kg / dm ³ , eg barite, magnetite, hematite, heavy metal slags, steel shot, steel chips, etc.), for normal concrete (grain density 2.2 to 3.2 kg / dm ³ , eg river gravel and sand, pit gravel and sand, chippings, crushed stone, metal slag, clinker fracture, asbestos, glass, steel, carbon and other fibers) and for lightweight concrete (grain density less than 2.2 kg / dm ³ , eg fine sand, lava rocks and sand, pumice stone, kieselguhr, tuffs, wood fibers, shavings, wool, flour, expanded mica, clay, pearlite, slate, fly ash, garbage slag, foamed plastic).

Of the Concept of concrete admixtures, as used in the invention is, referred to DIN 1045 (07/1988) concrete additives or Additives which by chemical and / or physical action the concrete properties (eg

processability, hardening or solidify); as volume fraction of the concrete, they are irrelevant. The concrete admixtures are not to be confused with the previously mentioned concrete additives. With the concrete admixtures one differentiates between the aforementioned Concrete admixtures, d. H. Concrete liquefiers, solidification retardants, Solidification and hardening accelerators, injection aids for prestressed concrete, Air bottoming agents, concrete sealants, etc.

by virtue of the fact that the used according to the invention curable Suspension, in particular cement slurry, without organic based additives or without organic based concrete admixtures, but still leads to an excellent insulating or sealing layer in a considerable extent Cost savings and sufficient strength of the resulting cured Moisture barrier achieved.

The Applicant has surprisingly found that it is precisely a curable suspension, which in addition to at least one hydraulic binder, in particular cement, preferably Portland cement, - and of course water - also contains a combination of silica SiO ₂ and at least one alkali silicate, to a particularly good moisture barrier or Insulation layer leads, which causes a long-term sealing of the subsequently repaired building. By incorporating the combination of silica and alkali silicate into the injected cement slurry, a particularly dense and thus water impermeable matrix of the resulting cured moisture barrier is achieved. The matrix of the resulting moisture barrier is densified by the incorporation of silica on the one hand and alkali silicate on the other hand, so that it becomes water-impermeable. The existing alkali metal silicate closes optionally existing residual pores and Restkapillaren, so that a water-tight barrier layer is realized against adjacent soil. The silica causes increased strength after hardening.

Without wishing to be bound by any particular theory, the thickening and strength-increasing effect of the silica can be explained by three effects: Since the silica particles are significantly smaller than the Ze grains of the suspension, they can fill part of the pore space between the cement grains, so that As a result, the structure of the cement paste becomes denser and higher strength and impermeability ("impermeability") is achieved. On the other hand forms silica by adding pozzolanic reaction with the calcium hydroxide, additional strength-enhancing calcium silicate hydrates (CSH), which are similar to the hydrated cement-containing CSH phases. Finally, the addition of silicon dioxide substantially improves the bond between aggregate on the one hand and matrix on the other hand, since the addition of silica reduces the calcium and ettringite content in the contact zone between matrix on the one hand and aggregate on the other hand.

The Incorporation of the silicon dioxide into the invention used curable Suspension leads Furthermore, that the Silica on the hydration process and the chemical reactions the cement clinker not only participates, but this crucial mitsteuert, whereby a moisture barrier or insulation with improved performance characteristics, in particular an improved Moisture barrier effect and strength or stability, arises.

The additionally On the other hand, existing alkali silicate can due to the good network and Kriechvermögens in possibly occurring superficial pores and capillaries invade and condense. The alkali silicate is thus special adapted to the complex chemistry of the suspension or cement slurry used. The alkali silicates react in contact with the cement through the environmental change and the formation is virtually insoluble Silicates. As a result, possibly occurring pores and Capillaries sealed so that water and salts can no longer penetrate. This seal is practically unlimited shelf life.

By the combination of silicon dioxide on the one hand and alkali silicate used On the other hand, thus, a complete subsequent sealing of parts affected by moisture and / or salt damage allows.

As far as the amount of silica SiO ₂ in the curable suspension used is concerned, this can vary within wide limits. In general, the silicon dioxide is SiO ₂ in an effective amount, in particular in an amount of 0.001 to 20 wt .-%, in particular 0.01 to 10 wt .-%, preferably 0.1 to 5 wt .-%, particularly preferably 0 , 1 to 3 wt .-%, based on the cement content of the suspension used (dry weight) used. Nevertheless, it may be necessary, depending on the particular case or application, to deviate from the abovementioned quantities.

In general, the silica SiO _{2 is used} in the form of a finely divided powder ("microsilica") or a suspension of a finely divided powder. Advantageously, more than 95% by weight, in particular more than 99% by weight, of the SiO ₂ particles used have diameters below 50 μm, in particular below 45 μm, preferably below 40 μm (sieve analysis). The SiO ₂ particles used preferably have a d _50% value ≦ 30 μm, preferably a d _50% value ≦ 20 μm.

The best results are obtained when the silica SiO ₂ in the form of a silica, in particular a preferably finely divided amorphous silica, and / or in the form of silicates, in particular finely divided precipitated silicates, preferably of magnesium, calcium, barium and / or aluminum, is used ,

Particularly good results are obtained if the silicon dioxide used SiO ₂ , in particular the silica and / or the silicates, a specific surface area (BET) of more than 50 m ² / g, in particular more than 75 m ² / g, preferably more than 100 m ² / g, more preferably in the range of 50 to 200 m ² / g.

Preferably used silica SiO ₂ , in particular silicic acid and / or silicate, has an SiO ₂ content, based on the silicon dioxide SiO ₂ , of more than 90% by weight, in particular more than 95% by weight, preferably more as 97% by weight. In addition, the silica used in substantially inert inorganic compounds of other metals, in particular oxides, such as. For example, alumina and / or iron oxide, and / or sulfates, such as. For example, alkali metal sulfates.

Advantageously, the silica used is SiO ₂ neutral, ie, more specifically, an aqueous suspension of the silica SiO _{2 used} has a pH of about 7.

Preferably used silica SiO ₂ has a true density in the range of 1.9 to 2.1 g / cm ³ .

The used, hardened with water curable suspension advantageously a water / cement value (W / Z value) ≦ 0.6, in particular, a W / Z value ≦ 0.5, preferably a W / Z value ≤ 0.45, on. In this way, the risk of segregation during the Compacting process and hardening minimized or eliminated.

What the invention used As far as alkali metal silicate is concerned, this may be in the form of a solution or suspension (eg in the form of an aqueous, alcoholic or aqueous-alcoholic Solution) used or added to the suspension.

The invention preferably used te alkali silicate is so-called water glass. The term "water glass" refers generally from the melt flow solidified, glassy, water-soluble potassium and / or sodium silicates (ie salts of silicas) or their viscous solutions or suspensions. In general, in the case of water glass, 1 to 4 molecules of SiO _{2 come} from one molecule of alkali oxide, which is why the soda and / or potassium water glasses are usually also characterized by the mass or molar ratio of alkali metal oxide (Me ₂ O) to SiO ₂ . Water glasses contain due to hydrolysis mainly hydrogen salts, such as Me ₃ HSiO ₄ , Me ₂ H ₂ SiO ₄ and McH ₃ SiO ₄ (with Me = K or Na). The water glasses are transparent in the pure state, colorless, as technical products by traces of iron bluish to greenish or yellowish to brown colored glasses that form with water at elevated temperature and pressure colloidal, clear, strongly alkaline solutions. In cold water, water glasses are insoluble, they are gradually neutralized by the CO _{2 of} the air, resulting in depending on the concentration of sols, gels or precipitates of silica. By addition of acids, silicic acid is initially obtained in the form of polysilicic acids as a clear to milky cloudy silica sol, which can be rapidly crosslinked with further What serabspaltung and formation of Si-O-Si bridges to silica gel. For further details on the concept of water glass can be referenced, for example, Römpp Chemielexikon, 10th revised edition, Volume 6, 1999, Georg Thieme Verlag Stuttgart / New York, page 4939, keyword: "water glass", as well as the literature reviewed there.

Preferably, the alkali metal silicate used for the surface treatment of the dried and hardened concrete surface, preferably water glass, of the general formula Me ₂ O · n SiO ₂ with Me = Na and / or K, where n is an integer or fractional number from 1 to 4, in particular from 2 to 3 (with the respective upper and lower limits included).

According to a preferred embodiment, the alkali silicate used, preferably water glass, a Me ₂ O / SiO ₂ ratio of 1: 1 to 1: 4, in particular 1: 2 to 1: 3, wherein Me ₂ O the alkali oxide, preferably the Sodium and / or potassium oxide, called the alkali metal silicate.

According to one particularly preferred embodiment is as alkali silicate a sodium and / or potassium water glass, in particular in the form of a solution or suspension used.

Silica hydrogels and / or silica xerogels may also be added to the alkali metal silicate. In this case, the Me ₂ O / SiO ₂ ratio can increase to a value of up to 1:12.

What the amount of alkali silicate (s), especially water glass, in the used curable Suspension or cement slurry As far as concerns, this can vary widely. In general is the alkali metal silicate in an effective amount, in particular in an amount of 0.001 to 20% by weight, preferably 0.01 to 10% by weight, particularly preferably 0.1 to 5 wt .-%, most preferably 0.1 to 3 wt .-%, based on the cement content of the suspension used (Dry weight), used. Nevertheless, it may be due to individual cases or may be required by application of the above Deviating quantities.

The present invention enables Overall thus an efficient seal or the realization a moisture barrier between the building and adjacent soil. The present invention is equally suitable for horizontal and vertical seals.

By the special procedure of the invention used Process and through the use of special curable Suspension or cement slurry let yourself the present invention also against oppressive and flowing water insert or carry out.

One particular advantage lies in the use of a purely mineral Suspension or cement slurry. This is especially for the sake of environmental and from a cost point of view of particular advantage. In addition, this leads equally to one additional Consolidation of the repaired building parts or foundations. It will be alike realized a ground and foundation stabilization. The injection the invention used Suspension leads thus additionally to increase the strength of the affected building parts, such as B. masonry, concrete surfaces Etc.

By the present invention can Surface locks Vertical seals and horizontal seals against penetrating or pressing or also fluent Water, against rising damp, against surface water etc. are realized.

By using the special suspension or cement slurry no further chemicals are needed. This generally allows for a one-step injection, as it were; This means that injections (eg complex pre-and / or post-injections) with other chemicals, in particular with silicones, etc., are not required, since even the injection with the suspension used according to the invention is sufficient, so that an efficient sealing of the affected building parts he is enough. Nevertheless, it is not excluded that, if necessary, re-pressing, especially in complicated building forms, are performed.

There an alkaline suspension or cement slurry is used acts the invention used Suspension with respect to reinforcements also protects against corrosion.

The The present invention will become apparent from the attached figures again closer explained. It shows:

1 in a sectional side view of subterranean or adjacent to ground building parts, which are repaired according to the present invention and provided with a moisture barrier, and

2 a plan view of cavity channels, in particular holes with injected suspension in the form of a so-called borehole grid.

1 shows in a sectional side view of the lower portion of a building (eg basement) with a bottom plate 1 , a masonry or a wall 2 and a blanket 3 , where bottom plate 1 and masonry 2 to a soil 4 adjoin.

In the to be repaired or trockenenzulegende base plate 1 and in the masonry to be repaired or drained 2 are a variety of cavity channels in the form of holes 5 introduced, in which under pressure the previously described curable suspension or cement slurry 6 injected under pressure. The holes 5 are in view of their number and their distribution so appropriate that the invention used suspension or cement slurry 6 through the cavities 5 through to the adjacent soil 4 can be injected so that the injected suspension 6 the outside, that is to the soil 4 adjoining surface of the bottom plate 1 and the masonry 2 , completely covered and there after curing a water-impermeable moisture barrier causes.

As is clear from the 1 Also, the area below the bottom plate can be 1 be provided with an insulating layer.

The 2 schematically shows the arrangement of the holes 5 in the form of a borehole grid, wherein the bores are arranged with respect to their number and distribution in such a way that the injected suspension or cement slurry 6 in the 2 not shown outer surface of the bottom plate 1 and the masonry 2 completely covered. This is achieved by the fact that - as in 2 shown - overlap the injection areas, so to speak, so that a secure, efficient and full-surface insulation can be realized.

Further Embodiments, modifications, variations and advantages of the present Invention are for the person skilled in the art readily discernible when reading the description and realizable without him while leaving the scope of the present invention.

Claims (29)

Repaired, in particular drained and / or moisture-insulated building and / or building part, in particular masonry, concrete part and the like, obtainable by a repair process, in which first cavity channels are introduced into the parts to be repaired and subsequently a curable suspension of a hydraulic binder is injected into the cavity channels, wherein the curable suspension in addition to at least one hydraulic binder also contains a combination of silica SiO ₂ and at least one alkali metal silicate. building and / or part of the building according to claim 1, characterized in that the cavity channels in shape be introduced from drilling. building and / or part of the building according to claim 1 and / or 2, characterized in that the cavity channels, in particular Holes are introduced in such a way to be repaired building parts, that the cavity channels through the repaired parts of the building through to the parts of the building to be repaired adjacent soil be created or applied, so that the suspension through the cavity channels through to the adjacent to the repaired parts of the building Soil is injected. building and / or part of the building according to one or more of the preceding claims, characterized that the Cavity channels especially the holes, are completely filled with the suspension, in particular, wherein the suspension in addition to the soil adjacent area the repaired building part at least essentially complete covered. Building and / or building part according to one or more of the preceding claims, characterized in that a plurality of cavity channels, in particular holes, is applied, wherein the number of cavity channels and / or the distances of the cavity channels to each other such be chosen so that the injected through the cavity channels suspension at least substantially completely covers the adjacent to the ground surface of the repaired building part. building and / or part of the building according to one or more of the preceding claims, characterized that the Cavity channels in particular holes, diameter of 10 to 50 mm, in particular 20 to 30 mm. building and / or part of the building according to one or more of the preceding claims, characterized that the Suspension is injected under pressure, in particular at a pressure of at least 0.5 bar, in particular at least 1 bar, preferably at least 2 bar, more preferably at least 3 bar. building and / or part of the building according to one or more of the preceding claims, characterized that one Horizontal seal and / or a vertical seal is achieved. building and / or part of the building according to one or more of the preceding claims, characterized that the Injection of the suspension a pre-injection of a mineralizer, especially precedes an alkali silicate, especially in the case of horizontal seals. building and / or part of the building according to one or more of the preceding claims, characterized that the Cavity channels in particular holes, finally with a mortar, in particular a silicate mortar, be closed. Building and / or building part according to one or more of the preceding claims, characterized in that the curable suspension of the hydraulic binder as cement hydraulic cement, in particular Portland cement contains, and / or that the aushärt bare suspension of the hydraulic binder is an aqueous based or aqueous alkaline Suspension and / or that the curable suspension of the hydraulic binder cement, in particular Portland cement, silica SiO ₂ and at least one alkali silicate and water and optionally additives, in particular inorganic based additives such as concrete additives and / or concrete aggregates, and / or that the curable suspension the hydraulic binder is a cement slurry. Building and / or building part according to one or more of the preceding claims, characterized in that the silicon dioxide SiO ₂ in an effective amount, in particular in an amount of 0.001 to 20 wt .-%, in particular 0.01 to 10 wt .-%, preferably 0.1 to 5 wt .-%, particularly preferably 0.1 to 3 wt .-%, based on the cement content of the suspension used (dry weight), is used. Building and / or building part according to one or more of the preceding claims, characterized in that the silica SiO _{2 is used} in the form of a finely divided powder or a suspension of a finely divided powder, in particular wherein more than 95 wt .-%, in particular more than 99 wt % SiO ₂ particles used have diameters below 50 μm, in particular below 45 μm, preferably below 40 μm, and / or in particular wherein the SiO ₂ particles used have a d _50% value ≤ 30 μm, preferably a d _50% value ≤ 20 μm. Building and / or building part according to one or more of the preceding claims, characterized in that the silica SiO ₂ in the form of a silica, in particular a preferably finely divided amorphous silica, or in the form of silicates, in particular finely divided precipitated silicates, preferably of magnesium, calcium, Barium and / or aluminum is used. Building and / or building part according to one or more of the preceding claims, characterized in that the silicon dioxide SiO ₂ , in particular the silica and / or silicates, a specific surface area (BET) of more than 50 m ² / g, in particular more than 75 m ² / g, preferably more than 100 m ² / g, particularly preferably in the range of 50 to 200 m ² / g, and / or that the silicon dioxide used SiO ₂ , in particular the silica and / or silicates, a SiO ₂ content , based on the silica used SiO ₂ , of more than 90 wt .-%, in particular of more than 95 wt .-%, preferably of more than 97 wt .-%, and / or that an aqueous suspension of the SiO used SiO _{2 has} a pH of about 7 and / or that the silica used SiO _{2 has} a true density in the range of 1.9 to 2.1 g / cm ³ . Building and / or building part according to one or more of the preceding claims, characterized in that a preferably pure mineral cement mixture, in particular Portlandzementmischung, is used as a hydraulic base mixture for the preparation of the suspension, in particular wherein the hydraulic base mixture in addition to cement optionally other inorganic based hydraulic binder , inorganic based concrete additives and / or inorganic based concrete aggregates and / or in particular wherein the hydraulic base mixture at least substantially no organic based concrete admixtures, in particular no organic based concrete liquefier, solidification retarder, solidification and hardening accelerator, injection aids, concrete sealant and the like. building and / or part of the building according to one or more of the preceding claims, characterized that the used aqueous suspension a water / cement value (W / Z value) ≦ 0.6, in particular, a W / Z value ≦ 0.5, preferably a W / Z value ≤ 0.45, having. Building and / or building part according to one or more of the preceding claims, characterized in that the hydraulic base mixture used for the preparation of the suspension contains as hydraulic cal binder in particular cement, preferably Portland cement, in particular in quantities of 100 to 750 kg / m ³ , preferably 200 to 500 kg / m ³ . building and / or part of the building according to one or more of the preceding claims, characterized that this Alkali silicate in the form of a solution or suspension, in particular in the form of an aqueous, alcoholic or aqueous-alcoholic Solution, is used. Building and / or building part according to one or more of the preceding claims, characterized in that the alkali silicate used corresponds to the formula Me ₂ O · n SiO ₂ with Me = Na and / or K, where n is an integer or fractional number from 1 to 4 , in particular from 2 to 3, and / or that the alkali silicate used has a Me ₂ O / SiO ₂ ratio of 1: 1 to 1: 4, in particular 1: 2 to 1: 3, wherein Me ₂ O den Alkali oxide, preferably the sodium and / or potassium oxide, called the alkali metal silicate. building and / or part of the building according to one or more of the preceding claims, characterized that as Alkalisilikat a water glass, in particular a sodium and / or Potassium water glass is used. building and / or part of the building according to one or more of the preceding claims, characterized that the Alkali silicate silica hydrogels and / or silica xerogels are added. Repaired, in particular dry and / or moisture-insulated, adjacent to or surrounded by soil building and / or building part, in particular masonry, concrete part and the like, in particular according to one or more of the preceding claims, obtainable by a repair process in which in the repaired building and / or or building parts first cavity channels, in particular in the form of holes are introduced through the repaired building and / or building parts through to the adjacent soil and subsequently injected into and through the cavity channels through to the adjacent soil a curable suspension of a hydraulic binder such in that the suspension injected into and through the cavity channels at least substantially completely covers the surface of the buildings and / or building parts adjoining the earth, the hardenable suspension being next to at least one hydraulic binder also contains a combination of silica SiO ₂ and at least one alkali metal silicate. Building and / or building part, in particular masonry, concrete part and the like, wherein the building and / or building part repaired, especially drained and / or moisture-insulated is characterized in that in the building and / or building part cavity channels are introduced, wherein in the cavity channels a curable suspension a hydraulic binder, which in addition to at least one hydraulic binder also contains a combination of silica SiO ₂ and at least one alkali metal silicate, preferably a water glass, injected and allowed to cure subsequently. building and / or part of the building according to claim 25, characterized in that the cavity channels in shape are introduced by drilling. building and / or part of the building according to claim 25 and / or 26, characterized in that the cavity channels, in particular Drilling, so in the repaired building and / or building parts are introduced that the cavity channels through the parts of the building to be repaired into the soil adjacent to the parts of the building to be repaired are generated or created so that the suspension through the cavity channels through to the building and / or part of the building adjacent soil is injected. building and / or part of the building according to one or more of the preceding claims, characterized that the Cavity channels especially the holes are completely filled with the suspension and the suspension also the surface adjacent to the soil of the part of the building to be repaired at least substantially complete covered and then cured is. Building and / or building part according to one or more of the preceding claims, characterized in that a plurality of hollow space channels, in particular holes, are applied, wherein the number of cavity channels and / or the distances of the cavity channels to each other are selected such that the injected through the cavity channels suspension is at least substantially completely covered and subsequently cured, the adjacent to the ground surface of the repaired building part , Surrounding and / or surrounding building and / or building part, in particular masonry, concrete part and the like, the building and / or building part repaired, in particular drained and / or moisture-insulated is characterized in that in the building and / or building part cavity channels, in particular in the form of holes through which buildings and / or building parts to be repaired are inserted into the adjacent soil, a curable suspension of hydraulic binder being injected into and through the cavity channels through into the adjacent soil such that it injects through the cavity channels Suspension, the at least substantially substantially completely covers the surface of the building and / or building part adjoining the ground, wherein the curable suspension additionally comprises, in addition to at least one hydraulic binder, a combination of silicon dioxide SiO ₂ and at least one A Lkalisilikat, and the injected suspension is allowed to cure below.