Method for producing a hybrid material

A method for producing a hybrid material by crystallizing solutes onto fiber-containing carriers addresses environmental and resource issues in decorative textiles, offering sustainable, cost-effective, and recyclable solutions with high aesthetic quality.

EP4772692A1Pending Publication Date: 2026-07-08

Patent Information

Authority / Receiving Office
EP · EP
Patent Type
Applications
Filing Date
2025-01-07
Publication Date
2026-07-08

AI Technical Summary

Technical Problem

Existing decorative materials like glass and plastic crystals for textiles are environmentally unsustainable, resource-intensive, and difficult to recycle, with complex application processes that increase manufacturing effort and reduce textile lifespan.

Method used

A method for producing a hybrid material by crystallizing a solute onto a fiber-containing carrier material, such as textiles, using a crystallizable solution at controlled temperatures and mixing to achieve uniform crystal growth, followed by coating with sustainable materials.

Benefits of technology

The method reduces production complexity and cost, enhances sustainability, and allows for easy recycling while maintaining high aesthetic quality, making it suitable for industrial-scale production.

✦ Generated by Eureka AI based on patent content.

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Abstract

The invention relates to a method for producing a hybrid material, a hybrid material and a use of a hybrid material.
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Description

SUBJECT OF THE INVENTION

[0001] The invention relates to a method for producing a hybrid material, a hybrid material and a use of a hybrid material. BACKGROUND OF THE INVENTION

[0002] Decorative elements such as pearls and sequins have always been used in fashion for embellishments on clothing and accessories. Their structure, which refracts light, creates a unique aesthetic and lends garments and other textiles a particularly high-quality appearance with its luster. Traditionally, these decorative effects are achieved by using crystals, beads, or sequins made of glass or plastic, which are sewn or glued onto fabrics. Crystals, in particular, create a high degree of light refraction due to their ordered structure, making them sparkle brilliantly and enabling a very elegant design.

[0003] The most commonly used crystals in the high-end textile industry are glass crystals. These are often individually attached to the garment or accessory with a thread through a hole in the crystal. Plastic or resin crystals are less expensive alternatives to glass crystals, which also require a complex application process to the textile material. These materials share the characteristic of being highly visually appealing, but they are problematic from an ecological perspective and significantly increase the manufacturing effort of the hybrid material. Plastic crystals, in particular, are associated with negative environmental consequences, as these materials are difficult to recycle and can lead to microplastic pollution. While glass beads and glass crystals are durable, their production is energy-intensive, which increases their ecological footprint.Recycling these embellishments is complex because it requires a time-consuming process of separating the crystals, beads, or sequins from the textile material before the actual recycling. Furthermore, many conventional methods for attaching these decorations to textiles are resource-intensive and can shorten the textile's lifespan, as seams or adhesives can weaken the fabric structure or deteriorate over time.

[0004] With increasing awareness of sustainability and environmental protection, there is an urgent need for alternative approaches, particularly for textile decorations, that are both aesthetically pleasing and environmentally friendly. There is particular interest in new hybrid materials and manufacturing processes that are more sustainable, allow for easy recycling, require less manufacturing effort, offer high material flexibility, conserve resources, and / or improve product longevity. TASK

[0005] The object of the present invention is to provide a method for producing a hybrid material which at least partially, preferably completely, solves the above problems, in particular allowing a less complex and therefore more cost-effective and time-saving production of such a material and / or which is more sustainable and resource-efficient than the methods known from the prior art and / or which enables the production of a hybrid material which is easy to recycle and / or durable and / or which offers high-quality aesthetics. DESCRIPTION OF THE INVENTION

[0006] This problem is solved according to the invention in particular by a method for producing a hybrid material comprising a fiber-containing carrier material on the surface of which at least one crystal is arranged; comprising the following steps: a) Providing a crystallizable, preferably aqueous, solution comprising a solvent and a solute; b) Providing a fibrous, preferably textile, support material; c) Bringing at least a part of the fibrous, preferably textile, support material from step b) into contact with the crystallizable solution from step a) at a temperature of the crystallizable solution of ≥ 20 °C, preferably ≥ 30 °C; more preferably, preferably ≥ 40 °C; d) Crystallizing at least a part, preferably all, of the solute from the crystallizable solution into at least one crystal on the surface of the fibrous, preferably textile, support material brought into contact with the crystallizable solution in order to obtain the hybrid material.

[0007] A "hybrid material" (also called a composite material) is a material composed of two or more different materials. These materials can belong to different material classes. Hybrid materials are often characterized by improved mechanical, chemical, or physical properties, which can also include aesthetic properties, that would not be achievable with a single material, or not in the same way. In the case of the invention, the hybrid material comprises at least one crystal and a preferably textile substrate, but may also include other materials.

[0008] A "crystallizable solution" (also called "solution" here) comprises a solvent and a solute. Under suitable conditions (e.g., by cooling, evaporation of the solvent, or addition of a nucleation site), crystal formation can be observed, and the solute precipitates in the form of crystals.

[0009] A carrier material is a solid or flexible substrate comprising a fibrous material and serving as a physical base for receiving, supporting, or fixing other materials, substances, or active ingredients. It provides a suitable surface or structure on which specific processes or chemical reactions, in this case the crystallization of the substance contained in the crystallizable solution, can take place. Examples of carrier materials include a one- or two-dimensional textile structure, leather (especially vegan leather), feathers or hides, and scales. Preferably, the carrier material comprises or consists of bio-based and / or compostable materials. This also applies to the hybrid material as a whole.

[0010] A fibrous material is a material consisting of fine, elongated structures called fibers. The fibers can be of natural or synthetic origin. The fibrous material preferably comprises or consists of long and / or continuous fibers.

[0011] A "crystallite" is a single-oriented region within a crystalline material, i.e., a crystal, in which the atoms are arranged in a regular, crystalline structure. Crystallites frequently form in polycrystalline materials, where the entire material consists of many such crystallites bordering one another in random orientations. The boundaries between the crystallites, called grain boundaries, influence the mechanical and physical properties of the material. In contrast to polycrystalline materials, a "single crystal" consists of a single crystallite. According to the invention, the term "crystal" encompasses both single crystals and polycrystalline materials.

[0012] The inventive method significantly reduces the effort required to produce decorative materials with crystal applications. The individual sewing, gluing, or other application of separately manufactured crystals, for example glass or plastic crystals, can be completely replaced by the inventive method. This results in comparatively low production costs.

[0013] Furthermore, the process according to the invention is particularly energy-efficient. The production of the crystallites does not require any process step that consumes a particularly large amount of energy, such as a melting step, which is necessary for the production of glass crystals. This makes the process resource-saving and sustainable.

[0014] Furthermore, the high scalability is a particular advantage of the method according to the invention. While individually applied applications are difficult and / or costly and time-consuming to implement on a large scale, the present invention offers simple scalability and can also be used in industrial production.

[0015] Bringing at least a portion of the fiber-containing, preferably textile, carrier material from step b) into contact with the crystallizable solution from step a) at a crystallizable solution temperature of ≥ 30 °C, preferably ≥ 40 °C, improves the fiber bonding capacity, thereby positively influencing the crystallization of the dissolved substance and its adhesion to the carrier material. Particularly preferably, the crystallizable solution is heated to a temperature in the range of 60 to 100 °C, preferably 70 to 95 °C, and the carrier material is also contacted with the crystallizable solution within this temperature range. One of the significant advantages is the increased accessibility of the fibers for crystallization. Swelling increases the surface area of ​​the fibers, which facilitates penetration by the crystallizable solution and enables nucleation and crystallization even between the fibers.

[0016] In a preferred embodiment of the invention, the crystallizable solution is mixed at least sectionally, preferably continuously, during step d). Alternatively or additionally, the crystallizable solution is mixed at least sectionally, preferably continuously, for a period of ≤ 1 h, preferably ≤ 30 min, more preferably ≤ 10 min, and most preferably ≤ 5 or even 2 min before contact in step c). In a particularly preferred embodiment, such mixing takes place before contact, and no further mixing occurs subsequently in step d). This minimizes the number of crystallization nuclei.

[0017] Preferably continuous mixing of the crystallizable solution in step d) enables controlled crystallization by keeping the reaction conditions constant throughout the entire volume of the solution. This applies in particular to the temperature and the degree of saturation, or the concentration of the substance in the solution. Other conditions, such as pH value or additive distribution, are also kept homogeneous by the preferably continuous mixing.

[0018] The preferably continuous mixing thus prevents, for example, local supersaturation points that can lead to uncontrolled crystal formation. Furthermore, this results in uniform crystal nucleation, which enables uniform growth. This leads to crystal patterns with a particularly homogeneous appearance.

[0019] Preferably, mixing is carried out using at least one mixing device, which is particularly preferably placed within the crystallizable solution. Exemplary mixing devices allow for mechanical mixing of the solution, mixing of the solution by generating turbulence or shear forces, by shaking or vibration, or by ultrasound.

[0020] The mixing device can be implemented in various designs and can be based on either active or passive mixing principles. Active mixing devices use mechanical or electrical components such as agitators, screw mixers, turbines, or rotor-stator systems to achieve targeted mixing of the components.

[0021] Alternatively, the mixing device can also be designed passively, i.e., without moving parts, for example, in the form of a static mixer. In this variant, mixing is achieved through the fluid dynamics of the components and the integration of stationary mixing elements within the device. Such a passive device can be advantageous for achieving homogeneous mixing without generating excessive turbulence, which can negatively affect nucleation.

[0022] The process stability is also increased by the preferably continuous mixing, which prevents unwanted deposits on container walls or other container surfaces that come into contact with the solution. This ensures that the concentration or saturation level of the solution remains controllable, and thermoregulation, which occurs, for example, via the container walls, can be transferred to the solution without hindrance, thus saving energy costs.

[0023] Furthermore, the mixing device and / or the container in which the crystallizable solution is contacted with the carrier material can optionally be combined with additional functions, such as temperature control by a temperature sensor.

[0024] The mixing device is preferably selected from the group consisting of agitators such as propeller stirrers, paddle stirrers, or anchor stirrers; magnetic stirrers; or shaking machines, preferably linear shakers or orbital shakers. These mixing devices are easy to install and can be scaled relatively easily. They ensure constant mixing, which enables controlled crystallization and thus the production of a high-quality and uniform hybrid material.

[0025] Preferably, the mixing device is placed within the crystallizable solution. This is particularly preferred if the crystallizable solution is provided in containers in step a).

[0026] The crystallization according to the invention is particularly preferably carried out by means of the cooling method. Here, the solution capable of crystallizing is cooled over a preferably precisely controlled temperature-time profile. For this purpose, devices for temperature regulation, also called thermocouples, preferably heating and / or cooling plates, can be used, which are preferably located inside a container holding the solution capable of crystallizing or outside of it, preferably directly on the walls or the bottom of the container.

[0027] In particular, at least one heating plate is attached to the bottom of the container so that sedimenting crystals can be dissolved again, which allows for a sufficient concentration or saturation level of the solution during crystallization, since unneeded free crystals can be dissolved and are available for the production of the hybrid material.

[0028] In a preferred embodiment, the thermocouples are controllable and can be combined with temperature sensors. The temperature sensors can send constant feedback to a control element, which in turn controls the thermocouples to maintain a constant temperature or a specific temperature profile. This is particularly important for controlled crystal growth and a homogeneous appearance of the hybrid material.

[0029] Other sensors such as conductivity sensors (conductometers), pH meters, refractometers and / or ion-selective electrodes can also be used in the process according to the invention and, together with appropriate control devices, keep the conditions homogeneous during the controlled crystallization.

[0030] The process can be precisely regulated using the employed control elements, all process steps can be documented, and thus potential production errors can be minimized. This reduces the resulting scrap, which offers significant advantages for the sustainability of producing such hybrid materials. It also reduces production costs and increases efficiency.

[0031] In a preferred embodiment, the method comprises a further step e) in which the at least one crystal produced in step d) is coated. Coating is a process in which one or more layers of a material are applied to a surface to modify or improve its properties. Preferably, the coating is carried out by means of spray coating, dip coating, spin coating, or powder coating.

[0032] The coating is preferably applied with a polymer material, in particular a poly(meth)acrylate (PMA) such as polymethyl(meth)acrylate (PMMA). PMA and PMMA coatings are optically clear and offer high light transmission, which is why they do not obscure the advantageous characteristics of crystals and ensure high optical aesthetics. PMMA also forms a hard and resistant layer that protects against mechanical defects such as scratches and has hydrophobic properties, so that it repels water, which is advantageous against external influences such as humidity or moisture. The coating material is preferably selected from the following groups: Organic coating materials

[0033] Organic coating materials offer versatile protective and functional properties for solids, particularly against moisture, chemicals, or abrasion. Suitable materials can be selected from the group consisting of polyurethanes (PU), which create elastic and durable surfaces; epoxy resins, known for their high hardness and chemical resistance; silicone polymers, characterized by temperature and UV resistance; and acrylic resins, frequently used for decorative or weather-resistant coatings. Bio-based and / or compostable coating materials

[0034] Bio-based and / or compostable coatings offer sustainable alternatives to conventional materials and are therefore particularly preferred. Suitable materials can be selected from the group consisting of polysaccharides such as starch and cellulose, which are biodegradable and versatile; proteins such as casein and soy protein; as well as polylactic acid (PLA) and other bio-based polyesters, which are distinguished by high transparency and good mechanical properties. Inorganic coating materials

[0035] Inorganic coating materials offer excellent protection against heat, corrosion, and abrasion, making them particularly suitable for technical applications. Examples from this group include aluminum oxide (Al₂O₃) and zirconium oxide (ZrO₂) for wear protection, titanium dioxide (TiO₂) for UV protection and self-cleaning properties, and silicon dioxide (SiO₂), which serves as a transparent, chemically resistant protective layer. Metallic coating materials

[0036] Metallic coatings protect solids from corrosion, improve their mechanical properties, or provide electrical conductivity. Suitable materials can be selected from the group consisting of zinc and aluminum, precious metals such as gold, silver, and platinum; as well as copper and nickel, which are used in functional applications. Hybrid coating materials

[0037] Hybrid coatings combine organic and inorganic components to meet specific requirements. Examples include materials from the group consisting of sol-gel coatings made of silicates and organic polymers; nanostructured coatings containing nanoparticles such as titanium dioxide (TiO₂), zinc oxide (ZnO), or silicon dioxide (SiO₂), which offer improved mechanical, optical, or thermal properties; and hybrid polymers that combine chemical resistance and flexibility. Functional coating materials

[0038] Functional coatings impart specific properties to solids, such as self-cleaning, conductivity, or thermal insulation. Suitable materials can be selected from the group consisting of hydrophobic and superhydrophobic coatings, for example, based on fluorinated polymers; electrically conductive materials such as indium tin oxide (ITO) or graphene; heat-insulating layers, for example, based on ceramics or aerogels; and thermochromic or photochromic coatings, which change their properties depending on temperature or light.

[0039] Preferably, the substance dissolved in the crystallizable solution is a salt.

[0040] The salt is preferably selected from the following groups: Inorganic salts containing alkali and alkaline earth metal ions

[0041] Inorganic salts containing alkali and alkaline earth metals are particularly well-suited for crystallization due to their high solubility in water and clear crystal structures. Suitable compounds can be selected from the group consisting of nitrates such as sodium nitrate (NaNO₃), potassium nitrate (KNO₃), and calcium nitrate (Ca(NO₃)₂); chlorides such as sodium chloride (NaCl), potassium chloride (KCl), and calcium chloride (CaCl₂); and sulfates such as sodium sulfate (Na₂SO₄), potassium sulfate (K₂SO₄), and calcium sulfate (CaSO₄). Carbonates such as sodium carbonate (Na₂CO₃), potassium carbonate (K₂CO₃), and calcium carbonate (CaCO₃) also fall into this category. Transition metal salts

[0042] Transition metal salts are often colored and form interesting geometric crystal structures, making them particularly suitable for aesthetic applications. Examples of suitable compounds can be selected from the group consisting of sulfates such as copper sulfate (CuSO₄), nickel sulfate (NiSO₄), and zinc sulfate (ZnSO₄); chlorides such as iron chloride (FeCl₃), cobalt chloride (CoCl₂), and nickel chloride (NiCl₂); and nitrates such as silver nitrate (AgNO₃), iron(III) nitrate (Fe(NO₃)₃), and cobalt nitrate (Co(NO₃)₂). Aluminum salts and complexes

[0043] Aluminum salts and their hydrous complexes are particularly well-suited for crystallization and offer stable, symmetrical structures. Suitable compounds can be selected from the group consisting of aluminum sulfate (Al₂(SO₄)₃), potassium aluminate (KAl(SO₄)₂), known as alum, and ammonium aluminate (NH₄Al(SO₄)₂). Halides

[0044] Halide salts crystallize readily from solutions and often form clear, prismatic crystals. Suitable compounds can be selected from the group consisting of sodium halides such as sodium fluoride (NaF), sodium chloride (NaCl), and sodium bromide (NaBr); potassium halides such as potassium iodide (Kl) and potassium chloride (KCl); and magnesium halides such as magnesium chloride (MgCl₂). Organic salts

[0045] Organic salts, composed of organic acids and bases, are excellent candidates for crystallization and often exhibit interesting optical properties. Suitable compounds can be selected from the group consisting of acetates such as sodium acetate (CH₃COONa), potassium acetate (CH₃COOK), and calcium acetate (CH₃COO)₂Ca; formates such as sodium formate (HCOONa) and potassium formate (HCOOK); and citrates such as sodium citrate (Na₃C₆H₅O₇) and potassium citrate (K₃C₆H₅O₇). Double salts and complex salts

[0046] Double salts and complex salts often crystallize in symmetrical and aesthetically pleasing structures. Suitable compounds can be selected from the group consisting of alums such as potassium aluminum alum (KAl(SO₄)₂·12H₂O) and ammonium iron alum (NH₄Fe(SO₄)₂·12H₂O), as well as Tutton's salts such as magnesium ammonium sulfate (Mg(NH₄)₂(SO₄)₂·6H₂O) and zinc ammonium sulfate (Zn(NH₄)₂(SO₄)₂·6H₂O). Rare earths and their salts

[0047] Rare earth salts offer unique optical and crystallographic properties that make them particularly interesting. Suitable compounds can be selected from the group consisting of lanthanide salts such as lanthanum chloride (LaCl₃), neodymium nitrate (Nd(NO₃)₃), and europium sulfate (Eu₂(SO₄)₃), as well as yttrium salts such as yttrium chloride (YCl₃) and yttrium sulfate (Y₂(SO₄)₃). Hydrates and salts containing water of crystallization

[0048] Salts containing water of crystallization are particularly well-suited for crystallization because they often form clear and stable crystals. Suitable compounds can be selected from the group consisting of copper sulfate pentahydrate (CuSO₄·5H₂O), magnesium sulfate heptahydrate (MgSO₄·7H₂O), and zinc sulfate heptahydrate (ZnSO₄·7H₂O). Salts with special optical properties

[0049] Some salts exhibit optical properties such as fluorescence or birefringence and are ideally suited for specific applications. Suitable compounds can be selected from the group consisting of calcium fluoride (CaF₂), sodium fluoride (NaF), and lithium fluoride (LiF).

[0050] The salt is particularly preferably an alum, i.e., a sulfuric acid double compound with the composition MI< M III< (SO 4 ) 2 * 12 H 2 O, where M' represents a monovalent metal cation and M III< represents a trivalent metal cation. M' is preferably potassium or sodium, more preferably potassium. M III< is preferably aluminum, chromium, cobalt, or iron, more preferably aluminum or chromium, especially aluminum. Alums are skin-friendly substances that are also frequently used in deodorants and aftershaves. They are characterized by their antibacterial and anti-inflammatory properties, which is why they are particularly used in natural cosmetics. Thus, alums are also particularly suitable for textiles, as they generally do not cause skin reactions in the wearer. Furthermore, alums are sustainable substances because they occur naturally and do not need to be synthetically produced like plastics, for example.Furthermore, the growth time of alum crystals is relatively short compared to other crystals. Together, these properties are advantageous for the use of alum crystals in the production of a hybrid material according to the invention. Alums are also water-soluble, which makes them easy to recycle and thus further contributes to sustainability.

[0051] Preferably, the crystallizable solution contains potassium aluminum sulfate dodecahydrate (potassium alum) and / or chromium(III) potassium sulfate dodecahydrate (chromium alum). Particularly preferably, the crystallizable solution contains only one of the aforementioned substances. Potassium alum forms colorless, transparent, high-purity, cubic crystals, while chromium alum forms dark violet, octahedral crystals. Both substances lead to aesthetically pleasing crystals that can grow with good definition and offer an elegant appearance.

[0052] Preferably, the salt contains ≤ 1 atomic percent of metals with a density > 5 g / cm³. This corresponds to the definition of a "heavy metal" according to the textbook "Fachkundebuch Metall" (Metal Science Handbook), 56th edition, Europa Lehrmittel, p. 268: Table 1: Classification of non-ferrous metals. Examples include copper, iron, and zinc. Due to environmental considerations, the content of such metals in the hybrid material should be kept as low as possible.

[0053] In a preferred embodiment of the invention, the content of metals having a density > 5 g / cm³ is ≤ 0.5 atomic percent, particularly preferably ≤ 0.2 atomic percent, and most preferably ≤ 0.1 atomic percent. Preferably, the content of aluminum, lithium, beryllium, strontium, and boron is individually and / or summed within the aforementioned ranges.

[0054] In a preferred embodiment, the concentration of the dissolved, crystallizable substance in the crystallizable solution in steps a) and / or c) and / or d) is 0.1–1 g / ml, preferably 0.2–0.9 g / ml, more preferably 0.3–0.85 g / ml. Depending on the temperature of the solution, this can correspond to an unsaturated, saturated, or supersaturated solution.

[0055] Preferably the ratio of solute to solvent is 1:1 - 1:10, more preferably 1:2 - 1:8, more preferably 1:5 - 1:8 and most preferably 1:6 - 1:8 or even 1:7 - 1:8.

[0056] Preferably, an unsaturated solution is provided in step a), and / or step c), and / or step d). This allows for very controlled crystal growth, as crystal formation proceeds more slowly than with saturated or supersaturated solutions. Furthermore, unsaturated solutions are less prone to spontaneously forming crystal nuclei. Instead of many small crystals, fewer, larger crystals are more likely to form, which is particularly desirable for the decorative purposes of the hybrid material.

[0057] Preferably, the degree of saturation of the crystallizable solution in step a) and / or step c) and / or step d) is 60 - 95%, preferably 70 - 90%, more preferably 75 - 85%.

[0058] Preferably, step a) comprises the following sub-steps: a 1 ) Providing a mass m L of a solvent, preferably water; a 2 ) Weighing a mass mk of a crystallizable substance, preferably an alum, into the solvent; optional: a 3 ) Heating the solvent to a temperature TL ; optional: a 4 ) Mixing the solvent and the crystallizable substance.

[0059] In a preferred embodiment, the solvent is heated in step a) to a temperature TL of 70–95°C, preferably 75–90°C, more preferably 80–85°C. Preferably, the temperature is also within the above range, at least partially, in steps c) and d).

[0060] In another preferred embodiment, the solvent is maintained in a temperature range of 20-50 °C in steps a) and / or c) and / or d). This is particularly useful in the evaporation method, where crystallization takes place without active temperature changes by evaporating the solvent and thus increasing the concentration of the crystallizable substance at a largely constant ambient temperature.

[0061] In a preferred embodiment, the carrier material is a textile structure, preferably a one-dimensional textile structure. A one-dimensional textile structure has a linear shape and is extended in only one direction to a large extent. These can preferably be filaments, threads, yarns, twines, ropes, or cords.

[0062] Filaments, as defined in the invention, are continuous fibers made of natural or synthetic materials. Natural filaments, such as silk, occur in their original form, while synthetic filaments are produced by extrusion. They are characterized by a uniform, smooth structure and are particularly suitable for fine, uniform textiles. Filaments can be used individually or bundled into filament yarns to achieve different properties such as strength and elasticity.

[0063] According to the invention, threads are linear structures produced by spinning fibers or filaments. They consist of one or more fiber strands that are loosely or tightly connected. Threads are versatile and can be used for sewing, embroidery, or weaving. They are usually thin and flexible, but can exhibit varying degrees of strength and texture depending on the material chosen. Yarns are threads made from spun fibers, consisting either of short fibers (staple yarn) or filaments (filament yarn). They form the basis for most textile surfaces, such as woven and knitted fabrics. Yarns can be single- or multi-twisted to achieve specific properties.

[0064] According to the invention, twisted yarns are produced by the targeted twisting of two or more yarns together, resulting in a robust and durable one-dimensional textile structure. Twisting improves the strength, uniformity, and resistance of the material. They can offer particularly decorative effects when different colors or materials are combined.

[0065] Preferably, the one-dimensional textile structures comprise twisted or braided fiber materials. These offer a particularly large surface area for crystal attachment, thus ensuring stable growth across the entire structure.

[0066] Preferably, one-dimensional textile structures covered with crystals are used as starting materials for further processing into two- or three-dimensional textile structures. These two- or three-dimensional textile structures are preferably decorative textiles, especially lace. This enables the production of particularly high-quality and elegant textile embellishments that find a wide range of applications in the areas of clothing, fashion accessories, home textiles, and similar products.

[0067] Alternatively, the textile structure is a two-dimensional textile structure. A two-dimensional textile structure is a textile sheet that extends in length and width and has a small thickness. Preferably, the two-dimensional textile structure is obtained through techniques such as braiding, interlacing, weaving, felting, or interlacing.

[0068] In a preferred embodiment, the two-dimensional textile structure is at least partially, and preferably completely, in a form selected from the group consisting of nonwovens, knitted fabrics, woven fabrics (especially plain weaves), or twill fabrics such as denim, gabardine, twill, or serge; braids, nonwovens, or mixtures thereof. The two-dimensional textile structure is particularly preferably in the form of a woven or braided fabric. Crystal growth is influenced by the weave structure. A looser weave (e.g., plain weave or open twill weave) promotes the stability and growth of the crystals because the more open weave structure offers more space for crystal formation and enables better adhesion to the fiber surface. These weave types therefore favor uniform and stable crystal growth across the entire textile surface.

[0069] In contrast, a tight and stable weave (as in twill or satin weave) inhibits the penetration of crystals into the fabric and ensures slow growth. Such a weave means that the crystals can only form on one side of the fabric (if fully immersed in the crystallizable solution, the inside must be prepared accordingly). This significantly simplifies wearing the woven textile, as the crystal growth remains on the outer surface of the material, preventing the formation of bothersome crystals on the inside. This property is particularly advantageous when the textile is used for garments or accessories where comfort and visual appeal are important.

[0070] According to the invention, a nonwoven fabric is understood to be a structure made of fibers of limited length, continuous fibers (filaments), or cut yarns of any kind and origin, which have been joined together in some way to form a fiber layer and bonded together in some way. This excludes the interlacing or entanglement of yarns, as occurs in weaving, knitting, crocheting, lacemaking, braiding, and the manufacture of tufted products. This definition corresponds to the standard DIN EN ISO 9092. According to the invention, the term nonwoven fabric also includes felt fabrics. Films and papers, however, are not considered nonwoven fabrics.

[0071] For the purposes of this invention, braiding is understood to mean the regular interlacing of several strands of flexible material. The difference from weaving lies in the fact that in braiding, the threads are not fed at right angles to the main direction of the product.

[0072] Particularly preferred within the scope of the invention is the use of a textile structure in the form of a woven fabric. According to the invention, a woven fabric is understood to be a textile surface structure consisting of two thread systems, warp (warp threads) and weft (weft threads), which, when viewed from the woven surface, intersect in a patterned manner at an angle of exactly or approximately 90°. Each of the two systems can be composed of several types of warp or weft (e.g., ground, pile, and filler warp; ground, binding, and filler weft). The warp threads run longitudinally in the direction of the woven fabric, parallel to the fabric edge, and the weft threads run transversely, parallel to the fabric edge. The threads are joined to form the woven fabric primarily by friction. In order for a woven fabric to be sufficiently resistant to shifting, the warp and weft threads must usually be woven relatively densely. Therefore, with few exceptions, woven fabrics also have a closed appearance. This definition corresponds to the standard DIN 61100, Part 1.

[0073] In a preferred embodiment, the thickness of the two-dimensional textile structure is 0.1 to 10 mm, more preferably 0.1 to 5 mm, particularly preferably 0.1 to 2 mm, and most preferably 0.2 to 1 mm.

[0074] Alternatively, the textile structure can also be three-dimensional. Three-dimensional textile structures are textiles that, in addition to length and width, also possess a significant thickness (≥ 3 cm, preferably ≥ 5 cm) and thus offer particular aesthetic and functional advantages for garments. Examples include spacer fabrics, which create voluminous yet lightweight effects, or shaped knits, which assume three-dimensional forms during production. Their special properties allow for the realization of creative designs that can appear both voluminous and three-dimensional as well as soft and flowing.

[0075] The basis weight (grammage) of the substrate material, preferably the textile structure, is in a preferred embodiment 50 to 500 g / m², more preferably 65 to 450 g / m², particularly preferably 80 to 300 g / m², and most preferably 90 to 150 g / m². A low basis weight allows crystals to adhere particularly easily.

[0076] In a preferred embodiment, the carrier material, preferably the textile structure, has a segmentally varying basis weight. It preferably consists of several segments whose basis weight varies between the segments. The strength of crystal adhesion is influenced by the basis weight. The higher the permeability, i.e., the lower the basis weight, the better the crystal adhesion. This is at least partly due to the capillary effect, which ensures that in segments with a lower basis weight, the liquid of the solution can penetrate the fabric more intensively, allowing for more pronounced crystal formation.

[0077] In a preferred embodiment, the carrier material, preferably the textile structure, has a segment-varying basis weight, wherein the carrier material comprises at least two segments whose basis weights vary in a ratio of 1:2, more preferably 1:4, particularly preferably 1:5 and most preferably 1:10 to each other.

[0078] In another preferred embodiment, the surface of the support material, preferably the textile structure, is at least partially modified before contact with the crystallizable solution. Surface modification means that the surface is altered by external physical or chemical methods. Preferably, the surface modification is the result of mechanical processing, more preferably by roughening, grinding, or brushing, especially roughening. This also improves the adhesion of the crystals to the processed regions of the surface, thereby controlling the growth of the crystallites.

[0079] In a preferred embodiment, the method according to the invention comprises, as a partial step of step b), i.e., the provision of a fiber-containing carrier material, the impregnation of a linear textile structure and the production of the carrier material used in step b), which is a two- or three-dimensional textile structure comprising the impregnated linear textile structure.

[0080] Preferably, the linear textile structure is a textile structure selected from the group consisting of fibers, filaments, yarns, threads and yarns.

[0081] Impregnation is preferably carried out with a water-repellent impregnating agent, more preferably with a wax-based impregnating agent.

[0082] According to the invention, wax is understood to mean natural or artificially produced substances that are malleable at 20°C, solid to brittle-hard, have a coarse to fine crystalline structure, are translucent to opaque in color but not glassy, ​​melt above 40°C without decomposition, are slightly liquid (i.e., low viscosity) just above their melting point, have a strongly temperature-dependent consistency and solubility, and can be polished under slight pressure. This corresponds to the definition in Römpp Chemie Lexikon, 10th edition, 1999, Georg Thieme Verlag.

[0083] Waxes can be categorized as natural waxes, chemically modified waxes, and synthetic waxes. In a preferred embodiment of the invention, the wax material is selected from the group of natural waxes, particularly preferably from the group of vegetable waxes, in particular candelilla wax, carnauba wax, Japan wax, esparto grass wax, cork wax, guaruma wax, rice germ oil wax, sugar cane wax, ouricury wax, and montan wax.

[0084] In another preferred embodiment, the natural wax is selected from the group consisting of animal waxes and mineral waxes, in particular from the group consisting of beeswax, shellac wax, spermaceti, lanolin (wool wax), preen grease, ceresin, ozokerite (earth wax).

[0085] Natural waxes offer the advantage of not being petroleum-based and thus contributing to the sustainability and biodegradability of the hybrid material.

[0086] In another embodiment, the wax is selected from the group consisting of chemically modified waxes or synthetic waxes, in particular from the group consisting of montan ester waxes, sasol waxes, paraffins, hydrogenated jojoba waxes, polyalkylene waxes, polyethylene glycol waxes.

[0087] Alternatively, a silicone-based waterproofing agent can be used.

[0088] Preferably, the linear textile structure is treated by spraying, wash-in impregnation, or coating with the impregnating agent and / or by immersion in the impregnating agent. By impregnating with a water-repellent impregnating agent, parts of the textile structure that will later come into contact with the crystallizable solution can remain free from crystal nucleation, as long as the crystallizable solute is water-soluble. Nucleation of water-soluble crystallizable solutes preferably or exclusively occurs on polar surfaces, while non-polar surfaces are unable or less able to attach crystal nuclei. This allows for controlled crystal growth. Furthermore, it increases the material's resistance to external influences such as humid or wet environments.

[0089] This property can be used to integrate patterns and / or motifs into the hybrid material. For this purpose, at least two linear textile structures are preferably used, at least one of which is impregnated. A two- or three-dimensional textile structure is then produced from these linear textile structures, which is used for the further steps c) and d) of the process according to the invention. Preferably, the at least two linear textile structures are woven or braided together. In another preferred embodiment, an impregnated linear textile structure is used to embroider a pattern and / or motif onto a two- or three-dimensional textile structure. This creates more or less contiguous regions in which the impregnated linear textile structures are located within the final hybrid material.These regions are then largely or completely free of crystallites in the final hybrid material, while the remaining regions, which have non-impregnated linear textile structures, are covered with crystallites.

[0090] Alternatively, such pattern and / or motif formation can also be achieved by treating regions on the substrate, e.g., in the form of a textile structure, after step b) in such a way as to prevent crystal growth, preferably by making these regions inaccessible to the crystallizable solution, in particular by sealing. This can include the following process steps: applying boundary elements, preferably by gluing and / or sewing on boundary elements, in particular mold plates or even sections of the substrate itself; impregnating the region to be treated with a preferably water-repellent impregnating agent, in particular by waxing the region with wax or paraffin; foil plotting and / or applying chemical processes to seal the region, in particular nano-sealing and / or polymer-based sealing.This method has the advantage that precise patterns and / or motifs can be formed through crystal growth while simultaneously bringing the entire textile structure into contact with the crystallizable solution, for example, by immersion. While patterns and / or motifs can also be formed by adjusting the areas of the textile structure that come into contact with the solution, for example, through targeted wetting, these cannot achieve nearly the same level of precision as the methods described above.

[0091] Preferably, the fiber material of the carrier material is of plant or animal origin, or it consists of synthetic fibers made from natural polymers or polymers based on natural raw materials. This allows the proportion of natural components in the layered composite to be improved accordingly, thus enhancing its sustainability and biodegradability.

[0092] In a preferred embodiment, the carrier material comprises a natural fiber material, wherein the natural fiber material is preferably selected from the group consisting of seed fibers, bast fibers, leaf fibers, and animal fibers. Particularly preferred are those selected from the group consisting of cotton, animal wool, animal hair, silk, kapok, akon, poplar down, bamboo fiber, fiber nettle, hemp, hemp nettle, jute, urena, linen, ramie, kenaf, roselle, sunns, abutilon, pung, castor, sisal, abaca, curaua, fibe, ixtle fiber, arenga, afrik, hequen, fique, phormium, alfa, maguey, yucca, pitta, coconut, broom, hops, cattail reed, and bast.Natural fibers selected from the group consisting of cotton, animal wool, silk, and linen are particularly preferred, as these are high-quality materials with special properties such as excellent skin-friendliness, superior temperature regulation, and good breathability, and are also exceptionally sustainable. Cheviot, a firm, robust woolen fabric with a slightly coarse texture, is especially preferred, particularly in the form of a twill weave.

[0093] Preferably, the chemical fibers are selected from natural polymers or polymers based on natural raw materials. Particularly preferred are those selected from the group consisting of viscose, modal, lyocell, curpo, cellulose acetates, protein fibers such as casein fibers, polylactides, alginates, chitin, bio-based polyamides, polyesters, and polyisoprene.

[0094] In another embodiment, the chemical fibers are selected from synthetic polymers from the group consisting of polyesters such as PET or PBT, polyamide, polyimide, polyamide-imide, aramid, poly(metha)acrylates, polyacrylic, polytetrafluoroethylene (PTFE), polyethylene, polypropylene, polychloride, PVC, elastane, polystyrene, polycarbonate, polyvinyl alcohol, vinylal, polyphenyl sulfide, melamine, polyurea, polyurethane, polybenzimidazole, polybenzoxal.

[0095] In a particularly preferred embodiment, the solvent of the crystallizable solution comprises or is water, more preferably distilled water. According to the invention, distilled water is water that has been purified by distillation or demineralization to remove impurities such as salts, minerals, and other foreign substances. In another preferred embodiment, the solvent of the crystallizable solution is multiply distilled water, preferably double distilled (bi-distilled) water. The more multiple distillation stages, the purer the resulting water.

[0096] Particularly preferred is the solvent of the crystallizable solution a water-based solvent, i.e. a solvent with ≥ 50 wt.%, preferably ≥ 70 wt.% or even ≥ 90 wt.% water content.

[0097] Mixtures of water with a less polar substance such as ethanol, isopropanol, or glycerol are particularly suitable for controlling solubility. This slows down the crystallization rate, allowing for precise control of crystal growth and improving crystal quality.

[0098] Preferably, the conductivity of the solvent of the crystallizable solution (excluding the solute) at 25°C is 0.1–800 µS / cm, more preferably 0.1–200 µS / cm, particularly preferably 0.1–50 µS / cm or even 0.1–10 µS / cm, and most preferably 0.1–5 µS / cm. The lower the conductivity, the lower the ion content and thus the higher the purity of the distilled water.

[0099] Pure water is particularly suitable for the production of the hybrid material, as it promotes controlled crystallization. A lower concentration of dissolved salts or other substances increases the uniformity of crystal growth. Any substances present in the solvent, such as impurities, can disrupt crystal growth by causing local supersaturation or uncontrolled nucleation. Furthermore, a highly pure solvent allows for precise control of the saturation level of the crystallizable solution, thus achieving a high degree of reproducibility. The quality of the resulting crystallites can also be significantly improved by using highly pure solvents. Impurities in the solvent can be incorporated into the crystal structure during crystallization, leading to defects and potentially reducing the material's luster.

[0100] Preferably, in addition to the dissolved, crystallizable substance, a dye is added to the crystallizable solution, which influences the color of the resulting crystals, particularly preferably by incorporation into the crystal.

[0101] Furthermore, a growth modifier or nucleation inhibitor can be added to the crystallizable solution, preferably selected from the group consisting of polymers, surfactants, or chelating agents, particularly preferably sodium dodecyl sulfate (SDS) or ethylenediaminetetraacetate (EDTA). These additives prevent undesirable deposits in the crystal structure and / or prevent uncontrolled aggregation of the crystals.

[0102] The proportion of dye, growth modifier and / or nucleation inhibitor in the crystallizable solution is preferably 0.01 - 5 wt.%, more preferably 0.1 - 2 wt.%, particularly preferably 0.1 - 1 wt.% and most preferably 0.5 - 1 wt.%.

[0103] The simplest method for bringing the fiber-containing, preferably textile, carrier material into contact with the crystallizable solution is to immerse at least a part, preferably the entire carrier material. This is therefore a preferred embodiment of step c) of the method according to the invention.

[0104] Particularly preferably, the crystallizable solution is provided in step a) in a container such as a basin, tub, or dish. Subsequently, the support material provided in b) is at least partially, preferably completely, immersed in the crystallizable solution in step c). This allows for uniform wetting of the entire or at least the partially immersed support material and is therefore particularly efficient and scalable.

[0105] Preferably, the support material is immersed in the crystallizable solution for 2 to 140 h, or 1 min to 96 h; more preferably for 2 to 48 h, particularly preferably for 2 to 24 h, most preferably for 2 to 12 h, or even 4 to 8 h. The longer the support material remains in the solution, the larger the crystals that can form. However, excessively long immersion results in uneven crystal growth and a lack of homogeneity.

[0106] In another preferred embodiment, the crystallizable solution from step a) is brought into contact with the substrate from step b) by means of a screen printing process. For this purpose, the crystallizable solution is applied to specific areas of the substrate using stencils, resulting in precise, pattern-based crystallization and thus allowing for a wide range of design possibilities.

[0107] The crystallizable solution can also be brought into contact with the substrate by a spraying process. In this process, the crystallizable solution is applied to the surface of the substrate through nozzles or spray heads. This also enables pattern-based crystallization while simultaneously ensuring uniform wetting of the selected substrate areas.

[0108] In a particularly preferred embodiment, steps c) and d) proceed at least partially in parallel. Controlled crystallization occurs at least partially during contact with the support material.

[0109] Such embodiments, which include applying the crystallizable solution to the support material, for example by spraying or screen printing, preferably include a further step of cooling the support material to promote or initiate controlled crystallization on the support material. Preferably, the contact of the support material with the crystallizable solution and the cooling of the support material can be carried out in several cycles to enable greater crystal formation.

[0110] In a preferred embodiment, the crystallizable solution is applied to the substrate material via a nozzle, which is cooled. Preferably, the nozzle temperature is 1–40°C, more preferably 1–30°C, more preferably 5–20°C, and most preferably 5–10°C. The temperature of the crystallizable solution before entering the nozzle is preferably 70–95°C, more preferably 75–90°C, and more preferably 80–85°C. Due to the temperature drop in the nozzle, controlled crystallization begins during application, so the process can also be considered an additive manufacturing technique or 3D printing. The solution, which has already crystallized at least partially, is then applied to the surface of the substrate material, where further controlled crystallization of the solid from the crystallizable solution to at least one crystal takes place.This technique allows for the application of highly targeted and precise crystal-shaped patterns to the substrate, thus generating particularly high-quality and complex hybrid materials.

[0111] Crystals formed from crystallizable solutions have the property of being able to redissolve in the appropriate solvent. Thus, new raw materials can be generated from previously used and no longer needed hybrid materials or from rejects, which can then be used for controlled crystallization to produce a new hybrid material.

[0112] Preferably, step a) of the method according to the invention therefore comprises the following sub-step a 1 ): Dissolving at least one crystal of a hybrid material comprising a fiber-containing, preferably textile, carrier material on its surface with at least one crystal with a preferably aqueous solvent in order to obtain a crystallizable solution.

[0113] In particular, the dissolution of the at least one crystal in step a 1) is carried out by means of heat. By increasing the temperature of the preferably aqueous solvent, the solubility of the crystal increases, whereby it can be effectively at least partially, preferably completely, dissolved from the hybrid material.

[0114] In a further preferred embodiment, step a) of the inventive process after sub-step a 1 ) further comprises sub-step a 2 ): filtering the crystallizable solution from step a 1 ). This removes impurities and insoluble crystals from the solution, so that a pure crystallizable solution can be provided for the production of the hybrid material.

[0115] The filtration of the crystallization solution can be carried out using various methods and aids to ensure efficient purification. For example, vacuum filtration can be performed using a filter medium such as filter paper, fiberglass mats, or synthetic membranes with a suitable pore size. Alternatively, gravity filtration can be used. This is particularly gentle and prevents premature crystallization.

[0116] Additionally, and preferably, filtration can be carried out using membrane filtration to effectively remove the finest particles and impurities. For higher solids concentrations in the solution, pressure filtration can be used to increase the filtration rate and ensure effective separation. Particularly for sensitive crystal structures, filtration with sheet filters or ceramic filters may be preferred to minimize mechanical stress during the process.

[0117] The selection of the appropriate method and auxiliary materials is preferably based on the properties of the crystallization solution, including viscosity, solids content and chemical composition, as well as the specific requirements for the purity and quality of the crystals obtained.

[0118] The invention further relates to a hybrid material produced according to one of the methods as described in claims 1-9 and above.

[0119] The invention further relates to a hybrid material, in particular for use as a component of clothing and / or fashion accessories or as a clothing and / or fashion accessory, comprising: i. a fibrous carrier material comprising one or more fibers, and ii. at least one crystal which at least partially encloses the circumferential surface of one or more fibers to more than 30%, preferably completely.

[0120] The circumferential surface of a fiber refers to the outer surface that completely surrounds the fiber. It corresponds to the area formed by the circumference of the fiber along its length. According to the invention, a section of the circumferential surface, i.e., an area along a partial length, is covered to more than 30%, preferably more than 50%, and particularly preferably more than 70%. Preferably, such a hybrid material is produced according to the inventive method as specified in claims 1-9 and above.

[0121] The invention further relates to a hybrid material, in particular for use as a component of clothing and / or fashion accessories or as a clothing and / or fashion accessory, comprising: i. a fiber-containing carrier material comprising one or more fibers, and ii. at least one crystal having a coating, preferably a polymethyl(meth)acrylate coating.

[0122] The coating is preferably applied with a polymer material, in particular a poly(meth)acrylate (PMA) such as polymethyl(meth)acrylate (PMMA). PMA and PMMA coatings are optically clear and offer high light transmission, which is why they do not obscure the advantageous characteristics of crystals and ensure high optical aesthetics. PMMA also forms a hard and resistant layer that protects against mechanical defects such as scratches and has hydrophobic properties, meaning it repels water, which is advantageous against external influences such as humidity or moisture.

[0123] The hybrid material can have the additional properties defined in claims 11-14 and below.

[0124] The coating material is preferably selected from the following groups: Organic coating materials

[0125] Organic coating materials offer versatile protective and functional properties for solids, particularly against moisture, chemicals, or abrasion. Suitable materials can be selected from the group consisting of polyurethanes (PU), which create elastic and durable surfaces; epoxy resins, known for their high hardness and chemical resistance; silicone polymers, characterized by temperature and UV resistance; and acrylic resins, frequently used for decorative or weather-resistant coatings. Inorganic coating materials

[0126] Inorganic coating materials offer excellent protection against heat, corrosion, and abrasion, making them particularly suitable for technical applications. Examples from this group include aluminum oxide (Al₂O₃) and zirconium oxide (ZrO₂) for wear protection, titanium dioxide (TiO₂) for UV protection and self-cleaning properties, and silicon dioxide (SiO₂), which serves as a transparent, chemically resistant protective layer. Bio-based and / or compostable coating materials

[0127] Bio-based and / or compostable coatings offer sustainable alternatives to conventional materials and are therefore particularly preferred. Suitable materials can be selected from the group consisting of polysaccharides such as starch and cellulose, which are biodegradable and versatile; proteins such as casein and soy protein; as well as polylactic acid (PLA) and other bio-based polyesters, which are distinguished by high transparency and good mechanical properties. Metallic coating materials

[0128] Metallic coatings protect solids from corrosion, improve their mechanical properties, or provide electrical conductivity. Suitable materials can be selected from the group consisting of zinc and aluminum, precious metals such as gold, silver, and platinum; as well as copper and nickel, which are used in functional applications. Hybrid coating materials

[0129] Hybrid coatings combine organic and inorganic components to meet specific requirements. Examples include materials from the group consisting of sol-gel coatings made of silicates and organic polymers; nanostructured coatings containing nanoparticles such as titanium dioxide (TiO₂), zinc oxide (ZnO), or silicon dioxide (SiO₂), which offer improved mechanical, optical, or thermal properties; and hybrid polymers that combine chemical resistance and flexibility. Functional coating materials

[0130] Functional coatings impart specific properties to solids, such as self-cleaning, conductivity, or thermal insulation. Suitable materials can be selected from the group consisting of hydrophobic and superhydrophobic coatings, for example, based on fluorinated polymers; electrically conductive materials such as indium tin oxide (ITO) or graphene; heat-insulating layers, for example, based on ceramics or aerogels; and thermochromic or photochromic coatings, which change their properties depending on temperature or light.

[0131] Preferably the crystal comprises at least one crystallite, wherein the at least one crystallite has a diameter D Kx, where the diameter D Kx is 0.05 - 0.5 mm.

[0132] This size of crystallites has the advantage of forming particularly uniform and smooth surfaces, which is less common with larger crystallites. The crystallites in the hybrid material thus have a homogeneous appearance and a fine texture, resulting in a striking aesthetic effect with a high degree of elegance.

[0133] In a preferred embodiment, the at least one crystallite is part of a polycrystalline material, wherein the polycrystalline material has a diameter Dpx. The diameter Dpx is preferably 1 mm to 5 cm, more preferably 1 mm to 3 cm, more preferably 2 mm to 2 cm, and most preferably 2 mm to 8 mm. This gives the polycrystalline material an optimal size for a particularly aesthetic appearance without making the hybrid material too heavy and thus compromising wearing comfort.

[0134] Depending on their size, the crystallites can be determined using X-ray diffraction, electron microscopy, or light microscopy. Light microscopy is particularly suitable for the diameters specified here, as it is sufficiently precise and requires little effort. Image analysis software can be applied to digital images to determine the crystallite or crystal diameter. Suitable image analysis software includes ImageJ and MATLAB.

[0135] In a preferred embodiment, the at least one crystal that encloses more than 30% of the circumferential surface of one or more fibers, and / or one of the crystallites it comprises, has a transmission in the visible wavelength range of ≥ 30%, preferably ≥ 50%, more preferably ≥ 70%, and most preferably ≥ 90%. This allows the material to appear particularly high-quality.

[0136] In a preferred embodiment, the crystal and / or the hybrid material comprises a total set U with n crystallites having diameters D K1 , D K2 , ... - D Kn, where n ≥ 10, and wherein a subset A with k crystallites having diameters D K1 , D K2 , ... - D Kk has an average of the diameters D KA exhibits a standard deviation σ DKA ≤ D KA * 0.5, preferably σ DKA ≤ D KA * 0.4, where k is preferably 10.

[0137] The smaller the standard deviation, the more uniform the aesthetic appearance of the hybrid material, as homogeneous crystallites ensure consistent light reflection and the surfaces appear calm and elegantly glossy. A small standard deviation also increases material stability, as weak points in the material structure are reduced and less prone to delamination. However, an excessively small standard deviation necessitates process conditions that allow for very little variation. This would require extremely precise control and execution of the processes, which would significantly increase the effort, reduce efficiency, and consequently, drive up costs dramatically.

[0138] The standard deviation of the mean of the diameters σ DKA is therefore preferably σ DKA ≥ D KA * 0.02, more strongly preferred σ DKA ≥ D KA * 0.05 and most preferred σ DKA ≥ D KA * 0.1.

[0139] Preferably, the hybrid material has a total quantity U with n ≥ 50, particularly preferably n ≥ 200 and most preferably n ≥ 1000 crystallites.

[0140] In a preferred embodiment, the k crystals of the subset A are arbitrarily selected from the total set U. This results in a particularly homogeneous hybrid material, which is distinguished by its uniformity.

[0141] As previously described, light microscopy is particularly suitable for determining the standard deviation σ DKA of the mean diameter, as it is sufficiently precise and can be used with minimal effort. Image analysis software can be applied to digital images to determine the crystallite or crystal diameter and thus ascertain the size distribution.

[0142] The invention further relates to various uses of the hybrid material according to the invention. Crystallization on the substrate material is highly controlled by the inventive process, resulting in a particularly appealing, homogeneous appearance for the final product, the hybrid material. Therefore, it can preferably be used as a material for manufacturing a garment, a fashion accessory, or a decorative item. According to the invention, garments, also called clothing, encompass all materials that, as an artificial covering, more or less closely surround the body of a person or animal. This includes headwear, especially hats, and shoes. According to the invention, fashion accessories are understood to be accessories for clothing. These are preferably belts, gloves, fans, sunshades or umbrellas, bags, scarves, and jewelry.The hybrid material can also be used for home textiles such as curtains, pillowcases, blankets, throws, coverings or upholstery. EXAMPLES

[0143] The invention will now be further explained with reference to specific embodiments of manufacturing examples according to the invention for hybrid materials. Production example 1

[0144] Twelve liters of water were brought to a boil, and 1.5 kg of alum were gradually stirred in until completely dissolved, resulting in a clear, crystallizable solution. This solution was then kept at this temperature and stirred for another five minutes.

[0145] In the next step, a woven wool fabric (grammage: 300 g / m², natural wool, twill weave) was completely immersed in the crystallizable solution.

[0146] To create the pattern motif in a targeted manner, a portion of the woven fabric was covered with a plate before immersion, thus preventing certain areas of the fabric from being accessible to the crystallizable solution.

[0147] After immersion of the material, the temperature of the crystallizable solution was gradually reduced to 30 °C over a period of 10 hours. Once this temperature was reached, it was slowly lowered to a target temperature of 25 °C over a period of 24 hours using temperature control. This temperature was maintained for at least another 96 hours, during which intensive crystallization was observed. After this period, the hybrid material was removed from the crystallizable solution. Production example 2

[0148] 12 liters of water were brought to a boil, and 2.4 kg of alum were gradually stirred in until completely dissolved, resulting in a clear, crystallizable solution. This solution was then kept at this temperature and stirred for another five minutes.

[0149] In the next step, a woven wool fabric (grammage: 120 g / m², natural wool, twill weave) was completely immersed in the crystallizable solution.

[0150] To create the pattern motif in a targeted manner, a portion of the woven fabric was covered with a plate before immersion, thus preventing certain areas of the fabric from being accessible to the crystallizable solution.

[0151] After immersion of the substance, the temperature of the crystallizable solution was gradually reduced to 30 °C over a period of 10 hours.

[0152] Once this temperature was reached, the solution was heated to 40 °C for a short time (< 1 min) and then the temperature was lowered back to 30 °C. This cycle was repeated every 2 hours and carried out a total of five times to enable controlled and intensive crystal growth.

[0153] This cyclical temperature change optimizes crystal growth, resulting in the formation of dense crystals that can reach a diameter of up to 3 cm.

Claims

1. Proceedingsfor the production of a hybrid material comprising a fiber-containing, preferably textile, support material on the surface of which at least one crystal is arranged; wherein the process comprises the following steps: a) providing a crystallizable, preferably aqueous, solution comprising a solvent and a solute; b) providing a fiber-containing, preferably textile, support material; c) bringing at least a part of the fiber-containing, preferably textile, support material from step b) into contact with the crystallizable solution from step a) at a temperature of the crystallizable solution of ≥ 30 °C, preferably ≥ 40 °C; d) crystallizing at least a part of the solute from the crystallizable solution into at least one crystal on the surface of the fiber-containing, preferably textile, support material brought into contact with the crystallizable solution in order to obtain the hybrid material.

2. Proceedings according to claim 1, wherein the crystallizable solution is mixed at least sectionally, preferably continuously, during step d).

3. Proceedings according to one of the preceding claims, wherein the method according to step d) comprises the following additional step: e) coating the at least one crystal produced in step d), wherein the coating is preferably carried out with a polymethyl(meth)acrylate or poly(meth)acrylate.

4. Proceedings according to one of the preceding claims, wherein the preferably textile, fiber-containing carrier material has a surface structure with segment-varying grammage.

5. Proceedingsaccording to one of the preceding claims, wherein the fiber-containing, preferably textile, carrier material is a one-dimensional textile structure, preferably selected from the group consisting of filaments, threads, yarns and twisted threads; or a two-dimensional textile structure, preferably selected from the group consisting of woven fabrics, nonwovens, knitted fabrics, fleeces, felts and braids, wherein the fiber-containing, preferably textile, carrier material is particularly preferably a one-dimensional textile structure and step b) comprises the following sub-step: bo) impregnating the one-dimensional textile structure and producing a two-dimensional textile structure comprising the one-dimensional textile structure, wherein the impregnation is preferably carried out with a water-repellent impregnating agent, more preferably with a wax-based impregnating agent.

6. Proceedingsaccording to one of the preceding claims, wherein the fiber-containing, preferably textile, carrier material comprises a natural fiber material, wherein the natural fiber material is preferably selected from the group consisting of wool, in particular cotton; silk and linen.

7. Proceedings according to one of the preceding claims, wherein the crystallizable solution in step a) comprises distilled water as a solvent.

8. Proceedings according to one of the preceding claims, wherein the contacting in step c) is carried out by immersing at least a part, preferably the entire fiber-containing, preferably textile, carrier material into the crystallizable solution.

9. Proceedingsaccording to one of the preceding claims, wherein step a) comprises the following sub-step: a1) Dissolving at least one crystal of a hybrid material comprising a fiber-containing, preferably textile, carrier material on its surface with at least one crystal with a preferably aqueous solvent to obtain a crystallizable solution.

10. Hybrid material manufactured according to one of the methods as described in claims 1-9.

11. Hybrid material especially for use as a component of clothing and / or fashion accessories, comprising: i. a fiber-containing carrier material comprising one or more fibers, and ii. at least one crystal which at least partially encloses the circumferential surface of one of the one or more fibers to more than 30%, preferably completely.

12. Hybrid material according to claim 10 or 11, wherein the at least one crystal is at least one crystallite with a diameter D Kx exhibits characterized by the fact that the diameter D Kx 0.05 - 0.5 mm.

13. Hybrid material according to one of claims 10-12, wherein the hybrid material comprises a total quantity U with n crystallites having diameters D K1 , D K2 , ... - D Kn exhibits, where n ≥ 10, and where a subset A with k crystallites with diameters D K1 , D K2 , ... - D Kk an average of the diameters D KA exhibits a standard deviation σ DKA ≤ D KA * 0.5, preferably σ DKA ≤ D KA * 0.4, where k is preferably 10.

14. Hybrid material according to claim 13, wherein the k crystallites of the subset A are arbitrarily selected from the total set U.

15. use a hybrid material according to one of claims 10-14 for the manufacture of a garment, a fashion accessory or a decorative article.