AEROGEL- AND/OR XEROGEL-BASED MASS FOR ADVANCED MANUFACTURING AND USE THEREOF

TECHNICAL FIELD

The invention relates to a high-porosity material-based composition, in particular for use as a printable and/or extrudable mass. Additionally, the invention is concerned with a workable composition, a hardened composition and a composite element produced from the high-porosity material-based composition. Further aspects of the invention are related to a method for producing a shaped body from the high-porosity material-based composition as well as the use of the high-porosity material-based composition as a printable mass in additive manufacturing, for digital casting, for producing a covering on a surface with a spray application technique, and/or as an extrudable mass for producing a shaped body by extrusion.

BACKGROUND ART

The building sector is responsible for around 36% of CO₂emissions and 40% of the energy use in Europe. Several countries have developed strategies to lower energy consumption. One focus is the promotion of energy efficiency in buildings. The main aim thereby is to reduce the energy consumption and CO₂emissions considerably in order to reach zero-energy buildings. Such a scenario requires an optimal use of energy resources and a further improvement of the properties of the thermally insulating layers or envelopes of buildings. The insulation materials on the market typically achieve thermal conductivity values (λ) of not less than 28 mW/(m·K), especially when inorganic binders are employed, a limitation linked to the additional need to meet mechanical requirements like mechanical strength.

A frequently encountered challenge in many applications is that non-standard shapes of the insulating elements are needed. In architecture, this includes complex curved walls that can, for example, be designed by computer algorithms to find the optimum solution for each surface, with regard to structures, shading elements, and other aspects. With the existing traditional construction technologies, such solutions are highly expensive, due to the costs of tailored molds and complex building processes. The problem is more intricate when multilayer elements are required, in order to include for example thermal and acoustic insulation or fire protection. Thus, digital technologies present an interesting potential of addressing these limitations in a cost-efficient way.

Besides architecture, thermal insulation is required in many other technical systems, such as pipe insulation of heating systems as well as cooling distribution systems. Another technology field in which functional layers are required, are elements, such as smart floors or advanced flooring systems, in which various utilities are embedded. Limited space for thermal insulation and complex shapes requirements are also a problem in automotive technology, for example in internal combustion engines placed next to heat-sensitive components like sensors or batteries. Similar requirements and limitations can be found in household equipment like for example electronic coffee machines and ovens. Other fields of application that deal with space limitations for thermal insulation and possibly also shape complexity may include aircrafts, aerospace or other conveyances and refrigeration.

All these applications can benefit from ultra-high performance thermal insulating materials. In this regard, aerogel-based composites have a high potential since aerogels represent a class of ultralight and thermally insulating materials. They also have an extremely high porosity which makes them particularly light weight.

The use of aerogels in architecture and construction is known from several publications. For example, WO 2014/090790 shows a dry blend for producing a thermally insulating rendering with 60-90 vol.-% of hydrophobized granular silica aerogel and 0.5-30 vol.-% of a purely mineral binder. The WO 2013/043882 shows a wallboard that includes an aerogel dispersed in a gypsum dihydrate. WO 2011/083174 describes a plaster containing aerogel to apply to a building surface to produce a thermally insulating coating. WO 2010/126792, as well as U.S. Pat. No. 6,080,475, show a composition including aerogel for low thermal conductivity, too. EP 2 142 718 B1 shows a tensioned multilayer architectural membrane structure comprising an aerogel, wherein the aerogel component represents one layer between at least two other layers of the membrane.

The disadvantage of the solutions described in these documents with regard to applications in architecture is that they are not suitable for producing free-forms and complex shapes, in addition to remaining limited by the combination of the material thermal insulation and strength.

At present, there is a high motivation for developing advanced manufacturing techniques. Advanced manufacturing techniques in particular include digital fabrication and additive manufacturing. Thereby, additive manufacturing methods turned out to be highly promising and advantageous.

“Digital fabrication” are meant to be techniques which make use of controlled, especially digitally controlled, set-on-demand processes for placing hardenable or curable building materials, such as e.g. mortar or concrete compositions. This includes in particular the control of the placing of the hardenable or curable building material depending on the strength evolution of the hardenable or curable building material, the object to be produced with the hardenable or curable building material and/or the formwork used during production. Especially, the placing is controlled based on a data model of the object to be produced.

For example, in “digital casting”, hardenable or curable building materials, such as e.g. mortar or concrete compositions, are casted in a formwork. Thereby, the structure of the formwork and/or the position of the formwork are chosen depending on the delivery rate of the hardenable or curable building material, the strength evolution of the hardenable or curable building material and/or the object to be produced. Preferably, in digital casting, the process is controlled, especially digitally controlled, based on a data model of the object to be produced and/or based on a data model of the formwork.

The term “additive manufacturing method” or “additive manufacturing” refers to methods in which a three-dimensional object or a shaped body is produced by selective three-dimensional deposition, application and/or solidification of material. In this process, the deposition, application and/or solidification of the material takes place in particular based on a data model of the object to be produced, and in particular in layers. In the additive manufacturing method, each object is typically produced from one or a plurality of layers. Ordinarily, an object is manufactured using a shapeless material (e.g. liquids, powders, granules, pastes, etc.) and/or a shape-neutral material (e.g. bands, wires) that in particular is subjected to chemical and/or physical processes (e.g. melting, polymerization, sintering, curing or hardening). Additive manufacturing methods are also referred to using terms such as “generative manufacturing methods”, “additive manufacturing” or “3D printing”.

Compared to conventional technologies, which are based on object creation through either molding/casting or subtracting/machining material from a raw object, additive manufacturing or 3D printing technologies follow a fundamentally different approach for manufacturing. The processes used in additive manufacturing have their conceptual origin in inkjet printing technology, extended to the third dimension and other materials. It is possible to change the design for each object, without increasing the manufacturing costs, offering tailor made solutions for a broad range of industries at different scales, including construction.

Depending on the materials and the way they are deposited for layer creation, several additive manufacturing methods are known:

- Extrusion based technique: Objects are built by the selective deposition of materials through a nozzle.
- Jetting based technique: Objects are built by the selective deposition of droplets of the built material.
- Binder jet based technique: Objects are built by the selective deposition of a glue or a binder to a powder by an inkjet print head.
- Sheet lamination based technique: Objects are built by binding together sheets of material (paper, plastic or metal) and cut by a laser cutter for each layer.
- Photopolymerization based technique: Layers are formed by solidifying a liquid photopolymer by a light source or laser that follows a path. Alternatively, an image per layer can be projected for faster production.
- Powder bed fusion based technique: The technique is similar to binder jet technique, but in this case a thermal energy (laser sintering) fuses the selected areas of the powder bed, melting the material to form each layer to achieve a specified shape.
- Direct energy deposition technique: The material is fused by melting during deposition.

Each of the mentioned additive manufacturing methods may use different raw materials either as dry powders, liquids or filaments. Raw materials typically used include glass, modelling clay, metal alloys, ceramics, photopolymers, thermoplastics, cement and so forth, depending of the industry sector, for example construction, automobile, medical, aerospace, industrial design and others. The size of the printed object can vary from millimeters to several meters or larger. The object can be typically post-processed to increase the quality finish or to achieve a fully functional and finished object.

Especially in the field of architecture, there are some advantages of using additive manufacturing methods. The flexibility to adapt dimensions and shape on demand is of high value for the building sector. Individualized construction elements of complex shapes become more and more popular in the field of architecture for esthetical and more importantly, functional reasons. It is possible to have individualized elements at low cost compared to classic manufacturing technologies because 3D printing is an additive single piece manufacturing technology with no need of for example molding or casting forms. Furthermore, elements can directly be manufactured from a 3D virtual model or a 3D scan of a real object by a specialized software creating sliced patterns (cross-sections) and instructions that are transferred to the 3D printer. Another cost reducing aspect is the smaller amount of raw material required compared to other technologies. The materials can be processed during 3D printing, by special print heads, placing the material where it is needed, with minimal waste. Additionally, the proportion of the raw materials can be selected on demand, in order to change the composition while printing, thus giving the possibility to print elements with gradients with regard to properties such as e.g. mechanical strength, thermal conductivity, acoustic transmission, translucency, and so forth.

However, the physical and chemical properties of hardenable or curable building materials such as e.g. mortar or concrete compositions, make the advanced manufacturing, especially additive manufacturing and digital fabrication, of shaped bodies very difficult. In particular, due to kinetics during the hardening and curing process and the thixotropic properties of such building materials, the use of advanced manufacturing techniques, especially additive manufacturing techniques, is sharply limited.

There is thus a need to develop new and improved solutions which reduce or overcome the aforementioned drawbacks.

DISCLOSURE OF THE INVENTION

It is an objective of the present invention to provide improved aerogel- and/or a xerogel-based compositions which are in particular suitable for advanced manufacturing, including but not limited to digital fabrication and/or additive manufacturing. Preferably, the compositions shall be suitable for use in other application techniques too. Especially, the compositions shall be suitable for producing ultra-high performance thermal insulating materials or composite elements for thermal insulation (superinsulation) with different scales or sizes. Preferably, in addition, the compositions shall be suitable for producing materials or elements with further improved properties such as high acoustic insulation, fire protection and/or safety. Especially, the compositions shall allow to produce insulation materials with lower thermal insulation values.

Surprisingly, it has been found that the problem of the invention can be solved by the features of claim 1. Thus, the core of the invention is a composition, in particular for use as a mass for advanced manufacturing, in particular a printable mass in additive manufacturing, comprising or consisting of:

a) 10-99.99 vol. %, especially 60-99.99 vol. %, in particular 80-99.99 vol. %, of a high-porosity material, whereby the high-porosity material is an aerogel and/or a xerogel
b) 0.001-5.0 vol. % of an organic binding promoter
c) optionally, balance to 100 vol. % of further components.

As it turned out, such compositions can be used in advanced manufacturing, especially in additive manufacturing or 3D printing, respectively, and/or in digital fabrication, in a very flexible and efficient manner. Thanks to the inventive compositions, hydration, setting times, strength gains, mechanical properties, thermal conductivity, and shrinkage properties can be achieved which are highly suitable for advanced manufacturing, especially additive manufacturing.

In addition, the compositions, besides their particular suitability for additive manufacturing, are highly suitable for use as an extrudable mass for producing a shaped body by extrusion. Moreover, the compositions can be formulated in a manner which is especially suitable for spray application techniques, as well as digital casting.

Also, the compositions can be formulated with a low content of mineral binders, such as e.g. hydraulic binders or cementitious binders. It is even possible to completely omit mineral binders in the composition. It was surprisingly found that this will further improve the insulating properties. Nevertheless, it is still possible to obtain good mechanical properties of the structures that are for example produced by additive manufacturing out of such compositions.

Specifically, the compositions allow for producing complex materials, e.g. multilayer materials and/or gradient materials. Also, it is possible to produce prefabricated or on-site elements by additive manufacturing of flat and/or free-form elements with complex shapes. Thus, the inventive compositions can be used as a “3D-printing ink” for producing aerogel- and/or xerogel-based superinsulating materials, composites and elements in digitally controlled robotic fabrication processes.

Furthermore, with the inventive compositions it is possible to provide materials, composite elements or building elements with ultra-high thermal insulation performance, in other words a superinsulation element, in particular an architectural constructional element, with an ultra-low thermal conductivity with a thermal conductivity value λ (lambda) below 160 mW/(m·K), preferably below 100 mW/(m·K), especially less than 40 mW/(m·K), in particular less than 20 mW/(m·K).

Further aspects of the invention are the subject matter of other independent claims. Especially preferred embodiments of the invention are the subject matter of the dependent claims.

WAYS OF CARRYING OUT THE INVENTION

According to a first aspect, the invention is concerned with a composition, in particular for use as a mass for advanced manufacturing, in particular a printable mass in additive manufacturing, comprising or consisting of:

a) 10-99.99 vol. %, especially 60-99.99 vol. %, in particular 80-99.99 vol. %, of a high-porosity material, whereby the high-porosity material is an aerogel and/or a xerogel
b) 0.001-5.0 vol. % of an organic binding promoter
c) optionally, balance to 100 vol. % of further components.

In particular, the composition is a dry composition. This means that with respect to the weight of the high-porosity material, a proportion of water in the composition is 0-2 wt. %, especially 0-1 wt. %, preferably 0-0.1 wt. %. Most preferred the composition is essentially or completely free of water.

Especially, the inventive composition is present in the form of a free-flowing powder composition.

In particular, a minimum amount of the high-porosity material, especially the aerogel, is >50 vol. %, especially >60 vol. %, in particular >70 vol. %, particularly >80 vol. %, for example >90 vol. %, especially preferred >93 vol. %.

In the present context, an “aerogel” is a porous particulate material, typically derived from a gel, in which the liquid component for the gel has been replaced with a gas. The aerogel can be silica-based, carbon-based, cellulose-based, (bio)polymer-based or metal based, or a combination thereof (hybrid aerogel). The porosity of the aerogel is above 50 vol. %, typically in the range of 90-99.98 vol. %.

Likewise, a “xerogel” is a porous particulate material, typically derived from a gel, in which the liquid component for the gel has been replaced with a gas. The xerogel can be silica-based, carbon-based, (bio)polymer-based or metal based, or a combination thereof (hybrid xerogel). However, in contrast to the aerogel, the porosity of the xerogel is significantly lower, in particular in the range of 15-50 vol. %.

According to a highly preferred embodiment, the high-porosity material is an aerogel.

A silica aerogel or a silica-based aerogel, respectively, can e.g. be derived from silica gel, by a modified Stöber process and/or by the method according to Kistler. Carbon-based aerogels can for example be created by pyrolysis in an inert atmosphere. Depending on the raw material different chemical syntheses are also possible and known to the person skilled in the art as well.

Especially, the aerogel is a hydrophobic aerogel. However, hydrophilic aerogels can be used as well.

Especially, the high-porosity material, in particular the aerogel, has a particle density of 50-300 kg/m³, in particular 70-200 kg/m³, preferably 140-170 kg/m³(measured at 20° C. and 1 atm). The “particle density” is meant to be the density of the individual particles making up the high-porosity material and is defined as the mass of the individual particles of the high-porosity material divided by the volume occupied by the particles considered. The volume includes particle volume and internal pore volume but not the inter-particle void volume. Thus, the term particle density is not to be confused with the bulk density or apparent density, which are defined as the mass of many particles divided by the total volume (including the inter-particle void volume) occupied by all of the particles considered.

According to a highly preferred embodiment, the high-porosity material is a silica-based aerogel especially a hydrophobic silica-based aerogel, with a particle density of 140-170 kg/m³.

Especially preferred, a volume proportion of the high-porosity material, in particular the aerogel, in the composition is 85-99.99 vol. %, most preferred 90-99.95 vol. %.

In particular, it is preferred that apart from the high-porosity material, in particular the aerogel, the volume proportion of all of the other constituents of the composition in dry state is lower than 7 vol. %, preferably lower than 3 vol. % and even more preferably lower than 1 vol. %.

Furthermore, it is preferred that, apart from the high-porosity material particles, all of the possibly present particulate constituents of the compositions have a particle size (d₉₅) between 10 nanometers to 1 millimeter, preferably between 15 nanometers and 100 micrometer and more preferably between 20 nanometers and 10 micrometers. Thereby, it is possible that the particulate constituents of these particle sizes are agglomerates as described below. However, when the composition is mixed with water, the agglomerates will fall apart and release the particles comprised therein.

Overall, such volume proportions and/or particle sizes will increase the thermal insulation properties of the composition or the materials produced thereof.

In the present context, an “organic binding promotor” is a substance which is capable of establishing a binding between high-porosity material particles, especially between aerogel particles, in the hardened composition.

Especially, the organic binding promotor comprises or consists of a surfactant, a block co-polymer, a fluoropolymer, a cellulose ether, carbohydrate starch ether and/or a redispersible polymer. Most preferred are surfactants and/or redispersible polymers.

According to a highly preferred embodiment, the organic binding promotor comprises or consists of a surfactant, especially selected from the groups of ionic surfactants, amphoteric surfactants and/or nonionic surfactants. An ionic surfactant can be a cationic surfactant or an anionic surfactant.

Anionic surfactants can for example include alkyl sulfates and/or alkyl ether sulfates, especially ammonium lauryl sulfate and/or sodium polyoxyethylene lauryl ether sulfate.

Especially, cationic surfactants can include, aliphatic ammonium salts and/or amine salts, in particular alkyl trimethylammonium and/or polyoxyethylene alkyl amine.

Amphoteric surfactants may for example include alkyl dimethyl betain, alkyl dimethyl amine oxide.

Nonionic surfactants can include glycerol fatty acid ester, propylene glycol fatty acid ester, sorbitan fatty acid ester, polyoxyethylene sorbitan fatty acid ester, tetraoleic acid polyoxyethylene sorbitol, polyoxyethylene alkyl ether, polyoxyethylene alkyl phenyl ether, polyoxyethylene polyoxypropylene glycol, polyoxyethylene polyoxypropylene alkyl ether, polyethylene glycol fatty acid ester, higher fatty acid alcohol ester, and/or polyhydric alcohol fatty acid ester.

Especially, block co-polymers can be selected from glycol based block co-polymers, in particular comprising blocks of polyethylene glycol (PEG) and polypropylene glycol (PPG). Especially, the block co-polymer is a triblock copolymer. For example, the block co-polymer can have the following structure: PEG-PPG-PEG or PPG-PEG-PPG.

In particular, an average molecular weight M_wof the block copolymer is 500-15,000 g/mol, especially 1,000-8,000 g/mol, preferably 3,000-7,000 g/mol. Such masses are understood to be taken before any possible cleaving or splitting of the copolymer during the processing.

According to a further preferred embodiment, the organic binding promoter comprises or consists of a redispersible polymer. In the present context, a “redispersible polymer” is a polymeric material which can disperse in water.

Preferably the redispersible polymer is based on one or more monomers selected from vinyl acetate, ethylene, vinyl alcohol, vinyl versatate, acrylate, styrene and/or acrylic ester. E.g. the redispersible polymer can be a poly(ethylene-vinyl acetate).

In particular, an average molecular weight M_wof the redispersible polymer is 100-10,000 g/mol, especially 200-6,000 g/mol, more preferably 250-3,500 g/mol. Such masses are understood to be taken before any possible cleaving or splitting of the copolymer during the processing

Preferably, a pH of the redispersed polymer in water (10 wt. % aqueous redispersion) is from 5 to 12.5, preferably from 5.5 to 12, even more preferred from 6 to 12.

According to a preferred embodiment, the redispersible polymer may contain mineral anti-block agents and/or water-soluble organic polymeric protective colloids, preferably with high molecular weight.

Water-soluble organic polymeric protective colloids can for example be selected from (i) natural compounds, such as e.g. be polysaccharides, (ii) synthetic oligomers, especially fully or partially saponified, (iii) modified polyvinyl alcohols, polyvinyl pyrrolidones and/or polyvinyl acetals. One or more polyvinyl alcohols can be for example be used together, if necessary with small quantities of suitable emulsifiers.

Other stabilizing systems for the redispersible polymers may include block copolymers of propylene oxide and ethylene oxide, styrene-maleic acid copolymers, vinyl ether-maleic acid copolymers, melamine formaldehyde sulfonate and/or naphthalene formaldehyde sulfonates.

Oligomers may be nonionic, cationic, anionic and/or amphoteric emulsifiers, such as e.g. alkyl sulfates, alkyl sulfonates, sulfates of hydroxylalkanols, alkyl and alkylaryldisulfonate, alkylaryl sulfonates, sulfonated fatty acids, phosphates and sulfates of polyethoxylated alkanols and alkylphenols, as well as esters of sulfosuccinic acid, quaternary alkylphosphonium salts, quaternary alkylammonium salts and/or polyalkoxylates.

However, redispersible polymers based on further and/or other monomers might be suitable as well.

According to a highly preferred embodiment, the organic binding promoter is a surfactant and/or a redispersible polymer whereas the high-porosity material is a silica-based aerogel, especially a hydrophobic silica-based aerogel. Thereby, preferably, the silica-based aerogel has a particle density of 140-170 kg/m³.

Preferably, the composition additionally includes 0.001-43 vol. %, especially 0.001-28 vol. %, preferably 0.001-16 vol. %, of a filler. The filler is chemically and/or physically different from the other constituents of the composition, especially from the organic binding promotor and from the high-porosity material present in the composition.

In the present context, the term “filler” is to be interpreted in a broad sense. Thus, the filler encompasses particulate materials with submicron-sized particles, micrometer-sized particles, millimeter-sized particles up to centimeter-sized particles.

The filler can be an inert material and/or a reactive material. An inert material is meant to be a material which does not react chemically with the other components of the composition under storage, processing and application conditions.

In terms of chemical composition, the filler can be an inorganic, organic, or inorganic-organic-hybrid material. In particular, the filler is a particulate material. Especially a maximum particle size of the filler is 10 mm, especially 5 mm, in particular 2 mm or 1 mm.

Especially, the fillers are chosen from mineral aggregates and/or organic aggregates.

In particular, the filler can be a non-porous, porous and/or expanded filler.

The filler can in principle have any kind of shape. However, according to a special embodiment, the filler is sphere shaped and/or the filler has a hollow shape. In case of a filler with a hollow shape, the filler can in particular be gas filled and/or evacuated. “Evacuated” means that the pressure in the hollow sphere shaped filler is lower than 1 atmosphere, especially lower than 0.5 atmospheres, in particular lower than 0.1 atmospheres.

Especially, the filler is hollow sphere shaped. In this case, the hollow sphere shaped filler can in particular be gas filled and/or evacuated.

For fillers with a hollow shape which are gas filled, a gas with thermal conductivity lower than air is preferably used. Suitable gases can e.g. be selected from a gas which, under standard conditions (T=20° C., p=1 bar), has a higher density than air. For example, argon and/or krypton can be used as a gas to fill hollow fillers.

However, air can be used as a gas to fill fillers with a hollow shape as well.

For example, mineral aggregates are chosen from: sand, limestone, artificial stone, quartz, fly ash, micro silica, metakaolin, silica fume, fumed silica, granulated blast-furnace slag, foamed blast furnace slag, volcanic slag, expanded clay, expanded shale, expanded slate, foamed glass, perlite, pumice, pozzolans, diatoms, vermiculite, norlite, ceramic particles, ceramic spheres, and/or porous silica.

In particular, ceramic spheres can be hollow, especially hollow and gas filled and/or hollow and evacuated, especially as described above.

Porous silica can be selected form all kind of grades, especially from macro to nano-porous silica.

An organic filler can be chosen from rubber, polystyrene, expanded polystyrene, extruded polystyrene and/or polyurethane foam.

In a further preferred embodiment, the composition additionally includes 0.001-25 vol. %, especially 0.001-5 vol. %, preferably 0.001-1 vol. %, of a binder. The binder is chemically and/or physically different from the other constituents of the composition, especially from the organic binding promoter, the filler, and the high-porosity material.

Preferably, the composition comprises less than 25 vol. %, especially less than 5 vol. %, preferably less than 1 vol. %, of a binder, especially of a mineral binder.

Preferably, the composition comprises less than 90 kg/m³, especially less than 50 kg/m³, preferably less than 25 kg/m³, of a binder, especially of a mineral binder.

In a further preferred embodiment, the composition comprises a volume proportion of the high-porosity material, in particular the aerogel, of 85-99.99 vol. %, most preferred 90-99.95 vol. %. and at the same time less than 5 vol. %, preferably less than 1 vol. %, of a binder, especially a mineral binder.

The expression “binder” especially refers to a substance which reacts in the presence of water to give a cured and/or hardened solid product.

Preferably, the binder is an organic binder and/or a mineral binder. However, mineral binders are most preferred. The expression “mineral binder” refers more particularly to a binder which reacts in the presence of water in a hydration reaction, to give solid hydrates or hydrate phases. This may be, for example, a hydraulic binder (e.g., cement or hydraulic lime), a latent hydraulic binder (e.g., slag), a pozzolanic binder (e.g., fly ash), or a non-hydraulic binder (gypsum or white lime).

The mineral binder comprises more particularly a hydraulic binder. Especially, the binder is selected from cementitious binders.

Preferably, the binder is selected from ordinary Portland cement (OPC), Portland cement, composite cement, calcium aluminate cement, calcium sulfoaluminate cement, magnesium oxide, cement comprising belite, especially in higher amounts than ordinary Portland cement, silicate cements, aluminosilicate-based cements, lime, gypsum, as well as combinations thereof.

It may, however, also be advantageous if the binder or the mineral binder comprises or consists of other binders. These are, in particular, latent hydraulic binders and/or pozzolanic binders. Examples of suitable latent hydraulic and/or pozzolanic binders include slag, flyash and/or silica dust.

However, according to another preferred embodiment, the composition is free of a mineral binder, especially a hydraulic binder, in particular a cementitious binder. This is especially beneficial in combination with a volume proportion of the high-porosity material, in particular the aerogel, in the composition of 85-99.99 vol. %, most preferred 90-99.95 vol. %. Further preferred, the composition additionally includes 0.00028-7.0 vol. %, especially 0.00028-1.4 vol. %, preferably 0.00028-0.28 vol. %, of an expansive agent. The expansive agent is chemically and/or physically different from the other constituents of the composition, especially from the organic binding promoter, the filler, the high-porosity material and the binder. In the present context, an “expansive agent” is an agent which reduces shrinkage of the composition during hardening, e.g. by controlling hydration and/or hardening times as well as the strength build up. This is helpful for advanced manufacturing, especially 3D printing, in order to provide enough strength during the manufacturing process, e.g. to the 3D printed material to support subsequent layers.

In particular, the expansive agent is an agent that can generate expansive products such as ettringite, magnesium silicate hydrate (M-S-H), portlandite and/or thaumasite.

Especially, the expansive agent is a compound, which is capable to react with silica and thereby generating an expansive product. For example, the expansive agent is a magnesium salt, e.g. magnesium oxide. In this case, the magnesium salt can react with silica to form magnesium silicate hydrates.

Especially, the expansive agent is a mineral based expansive agent.

Preferably the expansive agent comprises or consists of calcium aluminate, calcium sulfoaluminate, calcium sulfates, calcium carbonate, lime, magnesium oxide or combinations thereof.

According to another preferred embodiment, the expansive agent is selected from alumina powder, expansive soils and swelling clays. Swelling clays can comprise or consist of smectite, montmorillonite, bentonite, beidellite, vermiculite, attapulgite, nontronite, and/or chlorite.

Furthermore, other expansive agents, such as e.g. polymers that can for example be activated with rising temperature can also be employed.

According to a special embodiment, the binder as well as the expansive agent both comprise or consist of magnesium compounds, especially magnesium salts, in particular the same magnesium salt. For example, the binder as well as the expansive agent can comprise or consist of magnesium oxide. In this case, the magnesium salt or the magnesium oxide, respectively, can be used for shrinkage compensation and for generating a binding phase at the same time.

Preferably, the composition additionally includes 0.0001-0.0999 vol. %, especially 0.0001-0.05 vol. %, preferably 0.0001-0.02 vol. %, of a curing agent. The curing agent is chemically and/or physically different from the other constituents of the composition, especially from the organic binding promoter, the filler, the high-porosity material, the binder and the expansive agent. In the present context, a “curing agent” is a chemical compound which is capable of retaining water and/or reducing moisture content loss during early stages of the hardening of the composition. The proportions of the curing agent are given with regard to the curing agent before contact with water or with respect to the dry curing agent, respectively.

With a curing agent, it is even possible to use high proportions of water when mixing up the compositions for application without adversely affecting the mechanical properties of the hardened composition. This is in particular beneficial in 3D printing processes since mixed-up compositions with a high water content can be extruded and/or delivered though a nozzle more easily.

The above mentioned proportions of the curing agent contribute to enhance the mechanical properties of the hardened composition, in particular a better binding with negligible effects on total porosity and thermal conductivity can be obtained. Specifically, these agents give rise to a better matrix hydration and therefore improve the mechanical properties and reduce shrinkage cracking which is especially important for additive manufacturing and digital fabrication, in particular 3D printing.

Higher proportions of the curing agent can lead to a worsening of both mechanical and thermal insulating properties of materials produced from such compositions.

Especially, the curing agent is an internal curing agent. An internal curing agent is present within the composition during hardening.

Highly preferred, the curing agent is a water retaining additive, especially a super absorbing polymer (SAP).

In the present context a “super absorbing polymer” is a polymer capable of absorbing and retaining water. Preferably, the superabsorbing polymer can absorb water in an amount of at least 30, especially at least 100, preferably at least 300 times its weight.

For example, the super absorbing polymer is chosen from the group consisting of crosslinked sodium polyacrylates, crosslinked sodium acrylamide, acrylate copolymers, crosslinked sodium acrylate, acrylamide copolymers, copolymers of a compound comprising at least one group of the sulphonic and/or phosphonic type, hydrolyzed crosslinked starch, acrylonitrile copolymers, crosslinked maleic anhydride and ethylene copolymers, crosslinked carboxymethylcellulose, crosslinked polyethylene oxide, phosphoric acid grafted polyvinyl alcohol-based polymers, and mixtures thereof.

Furthermore, the composition preferably includes 0.001-15.0 vol. %, especially 0.001-5.0 vol. %, preferably 0.001-1.0 vol. %, fibers. The fibers are chemically and/or physically different from the other constituents of the composition, especially from the organic binding promoter, the filler, the high-porosity material, the binder, the expansive agent and the curing agent. Fibers might help to reduce shrinkage cracking during hardening of the composition.

Preferably, the fibers are selected from metal fibers, steel fibers, glass fibers, wood fibers, wool fibers, ceramic fibers, mineral fibers, carbon fibers, organic fibers, and/or synthetic polymer fibers, such as polypropylene fibers, aramid fibers, Kevlar fibers, and/or Nomex fibers.

The fibers can be in the form of individual fibers and/or in the form materials comprising interconnected fibers. A suitable material comprising interconnected fibers is for example mineral wool and/or glass wool.

According to a special embodiment, the fibers are in the form of mineral wool, especially selected from glass wool, ceramic wool, polycrystalline wool, kaowool, stone wool and/or rock wool.

Preferably, the fibers are non-flammable and/or fire resistant. These are for example fibers in the form of mineral wool, silica fibers, glass fibers, aramid fibers, Kevlar fibers, nomex fibers, steel fibers and/or carbon fibers.

Additionally, the composition preferably includes 0.001-5.0 vol. %, especially 0.001-1.0 vol. %, preferably 0.001-0.2 vol. %, opacificer. The opacifier is chemically and/or physically different from the other constituents of the composition, especially from the organic binding promoter, the filler, the high-porosity material, the binder, the expansive agent, the curing agent and the filler. An “opacifier” is a substance which is added in order to make the composition opaque. An example of an opacifier is titanium dioxide (TiO₂). However, other opacifiers can be used as well.

Other additional substances, e.g. for improving workability, shear behavior, setting kinetics and/or dimensional stability, in particular with respect to drying, can also be included in the composition.

A first highly preferred composition, in particular for use as a printable mass in additive manufacturing, comprises or consists of:

a) 60-99.99 vol. % of a high-porosity material, especially an aerogel
b) 0.001-2.0 vol. % of an organic binding promoter, especially selected from surfactants and/or redispersible polymers
c) 0.001-28 vol. % of fillers, especially selected from mineral aggregates
d) optionally, balance to 100 vol. % of further components.