PL240059B1 - Aluminum section of internal and external fireproof systems - Google Patents

Description

PL 240 059 B1

Description of the invention

The subject of the invention is an aluminum section used in internal and external fireproof systems such as partition walls, doors, windows, etc.

Fire protection systems are known from the state of the art, in which, for the construction of fireproof partitions, materials filling the chambers of aluminum sections, made of properly cut and formed GK plates, or Palstop type cooling plates or similar, with cooling properties, matched to the internal chambers of aluminum sections, are used. The main feature of these solutions is the release of large amounts of bound water during a fire, thus cooling the structure to be protected. This phenomenon continues until the bound water is released and temporarily prevents the temperature from rising on those parts of the frame structure that are in the protected zone. There are also examples of attempts to directly pour the center of the section with a material with the properties as described above.

From the patent description PL184499 there is known a fire-resistant insulation element in the form of a laminate of at least one layer of ceramic fibrous material and of at least one layer of heat-resistant inorganic fibrous material, for example glass wool or mineral fibrous material, characterized in that the layer of ceramic material is glued to a layer of heat-resistant inorganic material by means of a heat-resistant adhesive. The heat-resistant adhesive is water glass, silicate glue or cement-based glue. The layer of heat-resistant inorganic material is in the form of a semi-rigid plate. The layer of ceramic material facing the heat source has such a thickness that, under the fire conditions defined in standard A60, the temperature of the element in the region of the adhesive layer does not exceed the melting point of the material of the next layer. The adhesive forms a rigid intermediate layer between the layers of the laminate.

From the Polish patent application P.351682, a fire-resistant prefabricated construction element of relatively low average thickness is known, comprising a hardened gypsum-based substrate which can be obtained by hydration by mixing, for example, a dry material consisting mainly of at least one hydratable calcium sulphate and an additive a discrete mineral containing clay material, characterized in that the mineral additive comprises essentially clay material, where the amount of crystalline silica is approximately 15% by weight of the mineral additive, and an inert mineral supplement that is compatible with the clay material and is dispersible in on a hardened gypsum base.

EP0717165B1 discloses a fireproof structural member which is manufactured as a multi-chambered light metal, preferably aluminum, profile having an insulating rib to reduce heat flow. In this frame structure, the outer and inner walls delimit the empty chamber. The two hollow chambers are connected by an insulating rib and sternal ribs, thus creating a three-chamber profile. Fireproof plates are inserted into these chambers, which are held in place by metal springs. In the event of a fire, the fireproof tiles release water of crystallization which cools the aluminum profile and prevents the aluminum profile from melting when facing the fire. This design has the disadvantage that it is only intended for fire resistance periods of up to 30 minutes. This structure cannot be used for longer fire resistance periods of 60, 90 or 120 minutes.

From EP0785334B1 a frame system is known, which is also made of multi-chamber aluminum profiles. In this frame system it has been proposed to create an aluminum core profile which includes fire protection glazing. The outer and inner walls are situated in front of the core profile, thanks to which a three-chamber profile is also created. The bearing core profile or both outer walls are connected to an insulating rib to reduce heat transfer. The core profile chamber or both hollow chambers of the outer walls are filled with fire-retardant insulating mass, so that in the event of a fire, the outer walls protect the load-bearing profile core.

From DE4443762A1, a fire protection element is known, in particular for the construction of a frame structure on a building, for fixing a structural element to be fixed, for example a fire protection glazing or a fire protection board, which has a core profile, a heat-insulating sealant, surrounding the core profile, a cladding surrounding the sealing putty and an outer cover strip. for fixing the construction element, the core profile, the sealing putty and the cladding together forming a multi-layer element. The frame structure is shaped like this

A light metal load-bearing profile, the melting point of which is lower than the temperature generated by a fire that acts on the metal profiles, may be embedded on the fire-facing surface, it being ensured that fusion of the load-bearing metal profiles is prevented. light in the pre-set fire resistance period. For this purpose, plates or moldings of heat-binding hydrophilic adsorbent with high water content are mounted on the outer surfaces and / or on the inner surfaces of the aluminum profiles. In a preferred embodiment, the material for the boards or moldings is a mixture of gypsum and alum which absorbs energy when exposed to heat. When the activation temperature is reached, the plates or fittings release water of crystallization, which cools the metal structure. The heat absorbing material can also be introduced into the inner chamber of the metal profile in a liquid form and then it hardens in the inner chamber to form a solid shaped body.

The patent description PL203004 describes a fire-resistant profile construction element and a method of its production, as well as a window or door made of a fire-resistant profile construction element and a method of its production. Fire-resistant profile construction element for the production of windows, doors, wall elements, facade and the like, comprising two profile parts, essentially U-shaped, preferably of extruded aluminum, which form an inner bearing wall and an outer bearing wall, and on their openings the ends of the arms are connected by thermally separating insulating ribs into a composite profile surrounding the hollow chamber, characterized in that between the inner bearing wall and the outer bearing wall, the composite profile is formed as a single chamber profile in which the empty chamber forms a single chamber which it is at least partially filled in the core area with a fire-retardant insulation mass, in the central area of which a thermal insulation is arranged. Thermal insulation is attached to the walls, which are made of glass fiber mats, placed in the insulating mass. The thermal insulation is made at least partially of mineral wool. The insulating mass is reinforced with a reinforcement. The inner bearing wall and the outer bearing wall have free ends of the legs with an undercut groove in which insulating ribs are seated with positive locking, forming a statically load-bearing composite profile and, in particular, the free ends of the arms in the chamber are completely surrounded by a fire-resistant insulating mass. The insulating mass is connected to the composite profile by a positive and / or non-positive connection. The insulating mass is made of a mineral base. The insulating mass contains crystal bound water. The insulating mass is reinforced with metallic wire cloth. The insulating mass is made of a cement, preferably magnesium oxychloride, magnesium oxysulfate or entirely of magnesium oxychloride cement or magnesium oxysulfate cement. The magnesium oxychloride cement contains MgCL / Mg (OH) 2 / H2O in a molar ratio of 1: (2.5 - 5): (8 - 12), and the magnesium oxychloride cement contains MgSO4 / Mg (OH) 2 / H2O in a molar ratio of 1: (2.5 - 3.5): (6 - 10). The insulating mass is made of cements containing magnesium chloride and magnesium sulphate. The insulating mass is made of a cement based on magnesium oxychloride - magnesium oxysulphate containing predominantly magnesium chloride. The insulating mass is made of a cement based on magnesium oxysulfate - magnesium oxychloride, containing predominantly magnesium sulfate. The magnesium oxychloride cement - magnesium oxysulfate consists of a molar ratio of MgCl2 / MgSO4 of 1: (0.02 - 1.9). The magnesium oxysulphate-magnesium chloride cement consists of MgSO4 / MgCl2 in a molar ratio of 1: (0.02 - 1.9). The insulating mass comprises water glass, preferably sodium water glass. Sodium water glass consists of Na2O / SiO2 with an average molar ratio of 1: (1.5 - 4.0). The cement has an average molar ratio of salt (MgCl2 and / or MgSO4) to sodium water glass of 1: (0.02 - 0.35). The insulating mass contains silicic acid, preferably in the form of a gel. The insulating mass is formed from at least one molded part located in the hollow chamber and having a cross-section at least partially corresponding to that of the chamber. The insulating mass is a hardening mass. Insulating mass completely fills the chamber. The chamber has chamber parts not filled with insulating mass. The part of the chamber filled with insulating mass is closed from the chamber part, not filled with insulating mass, with an adhesive tape. The adhesive tape is glued to two arms of the inner and outer bearing walls arranged in a space and facing each other at a distance, the adhesive tape preferably being adjacent to the side walls of the arms which face the part of the cavity filled with fire insulating mass. The part of the chamber filled with insulating mass is closed from the side of the chamber part, not filled with insulating mass, by a fitting

PL 240 059 B1 from plastic. The molded part is slid over two legs of the inner and outer bearing wall, placed in the chamber and facing one another at a distance, the molding having a groove in which the free ends of the legs are seated. The outer bearing wall, on its outer surface facing away from the chamber, has a groove for receiving a seal for the glazing. The inner bearing wall and the outer bearing wall have grooves for retaining gaskets made of a heat expandable material. A glass strip is disposed on the outer surface of the inner bearing wall and the outer bearing wall facing the chamber. The inner bearing wall and the outer bearing wall on its outer surface facing the chamber have a protruding abutment arm with a groove formed therein, in which a stop seal is seated.

A method of manufacturing a fire-resistant profile construction element for the production of windows, doors, wall elements, façades and the like, wherein firstly two profile parts, essentially U-shaped, preferably of extruded aluminum, which form an inner bearing wall and an outer bearing wall, at their free ends, the arms are joined by thermally separating insulating ribs to form a composite profile surrounding the empty chamber, characterized by the fact that the hollow chamber in the core area is at least partially filled with fire-resistant insulation, and a thermal insulation is placed in the middle of the composite profile. . The insulating ribs are pressed into the grooves at the free ends of the legs of the inner and outer bearing walls. A hardening fire-resistant insulating mass filling the empty chamber is used as the intumescent insulation mass. The insulating mass is made of a mixture consisting of magnesium oxide and a concentrated, preferably saturated or supersaturated aqueous solution of magnesium chloride and / or a solution of magnesium sulphate. The insulating mass is made with the addition of water glass, preferably sodium water glass, which is introduced in a liquid form into the fireproof insulating mass until a density of 1.32 1.55 g / cm ³ is preferably obtained. The insulating mass is produced with the addition of a metal chloride, for example calcium chloride, the cation of which forms sparingly soluble sulphates in the insulating mass, preferably calcium sulphate. An insulating mass containing silicic acid is used. Silicic acid is produced by precipitation with a metal salt and / or acid from waterglass initially contained in the insulating mass. Fireproof insulation mass is made of a mixture consisting of 35 ± 25% by weight of MgCl2, 13 ± 12% by weight of MgSO4, 35 ± 25% by weight of MgO and 5.1 ± 5.0% by weight of an aqueous solution of sodium water glass, with the addition of water wherein the mixture may also contain a mineral and / or organic acid. The insulating mass is made of a mixture consisting of 13 ± 12% by weight of MgCl2, 31 ± 30% by weight of MgSO4, 31 ± 30% by weight of MgO and 5.1 ± 5.0% by weight of water glass, with the addition of water, and containing 1 - 30 vol.% Hollow microspheres as filler. Before joining the inner bearing wall and the outer bearing wall, as well as before filling the hollow chamber with the fire-resistant insulation mass, the unfilled chamber part is closed with adhesive tape, the adhesive tape being left in the hollow chamber after hardening of the insulation mass. The adhesive tape is adhered to the two arms of the inner and outer bearing wall extending into the chamber and spaced apart. In order to form at least one hollow chamber part which is not filled with insulation mass, before filling the chamber with the insulating mass, the unfilled chamber part is closed with a plastic molding which is left in the chamber after the insulation mass has cured. Preferably, the molded part slides with a positive fit over the two arms of the inner and outer bearing wall, which go into the chamber and face at a distance. In order to form at least one part of the chamber which is not filled with insulating mass, before filling the chamber with insulating mass, at least one shaped piece is inserted into the chamber, and after filling and hardening of the insulating mass, it is removed from the profile construction element.

A window or door comprising at least one frame, consisting of sections of fire-resistant structural members, and a fire-resistant glass glazing attached inside the frame, is characterized in that the glazing in its edge area is provided with U-shaped metal profiles, which in In the area of the side arms, they are bolted to the inner bearing wall and the outer bearing wall of the profile construction elements that form the sash or frame. A gasket is placed between the glazing and the frame, which foams under the influence of heat. A U-shaped metal fastening bar is placed between the glazing and the frame, surrounding and holding the glazing at the edge with the side arms and the lower arm connecting them, the side arms being hollow and the arm

The lower support wall is bolted to the inner bearing wall and the outer bearing wall of the frame in the area of the side arms. The frame supporting the glazing, formed as a window sash, is movably attached to the frame consisting of sections of profile construction elements forming the circumferential rebate chamber, the lock being mounted on the rebate surface of the window sash facing the rebate chamber, and the lock cover plate on the facing to the rebate chamber, the surface of the frame, respectively with the indirect inclusion of the connector, and the connectors are fastened with screws on the arms of the outer bearing wall and the inner bearing wall of the frame or the leaf frame. An anchoring part is set on the frame, on the surface facing away from the frame chamber, and fastened with screws to the side arms of the inner bearing wall and the outer bearing wall of the frame. The casing has a guide pipe in the post for fixing the transom rod in the fireproof insulation mass. On the surface of the frame facing the rebate chamber, in the area of the lateral arm of the outer bearing wall, there is a retaining groove in which a seal protruding into the rebate chamber is fitted, and in the area of the sash frame opposite the retaining groove and facing the rebate chamber, on the side arm of its outer bearing wall, a stop edge is formed for a central rib seal.

The method of producing window or door frames from fire-resistant profile construction elements is characterized in that a composite profile made of an inner bearing wall, an outer bearing wall and insulating ribs is cut to lengths and joined to form a frame in the corner areas, and a hole is then made leading into the chamber surrounded by the composite profile, after which the fire-resistant insulation mass is introduced into the chamber through the hole and the hole is closed.

There is also known a method of manufacturing doors and / or windows in a fireproof construction, where the profiles of the window, door and / or door leaf are cut to a specific size. Fireproof inserts are inserted into the cut sections and then trimmed. The cut sections are connected to the frames with the use of aluminum fittings by pinning, twisting or kneading. Then fireproof tapes are cut to the frame, which are glued and screwed. Metal sheets are attached to the frame covered with tape. Then the glazing beads are cut to the frame. After the glazing beads are fitted, the battens are processed by cutting the obstructive material in the places where the sheets are attached. The frame prepared in this way is transported to the construction site. At the construction site, the glazing beads are removed and the glass is mounted by tightening the sheet stabilizing the glazing. Then the glazing beads and gaskets are installed.

From the description of the invention PL230498 there is known a method of producing doors and / or windows in a fireproof structure according to the invention, which consists in inserting fireproof inserts and fireproof tapes into full-length raw sections. Then, the sections reinforced in this way are cut into specific dimensions. The cut sections are connected to the frames with the use of aluminum fittings by pinning, twisting or kneading. Plates are attached to the created frame. Preferably, the fireproof inserts are stabilized by means of fixing the insert through the stabilizing elements. Then the glazing beads are cut to the frame. A frame prepared in this way with glazing beads is transported to the construction site. At the construction site, the glass is fixed with the use of a previously installed sheet by bending the side wall of this sheet. Then the glazing beads and gaskets are attached.

From the application documentation of the invention P.299146, doors are known having a frame made of steel C-sections and side surfaces made of steel sheets. The edges and sides of the door are covered with brass sheets. The bolt lock and pintle hinges are also made of brass. The door is connected to a steel frame covered with a brass sheet by means of a flexible copper cable. The inside of the door is filled with insulating material. On the periphery of the door there is a gasket made of a material that swells under the influence of temperature.

From the description of the Polish invention PL191666, a fire-resistant glazing assembly is known, comprising glass plates, a spacer, an intermediate layer containing water and a sealing material, characterized by the fact that it consists of at least two glass plates, a spacer connecting two glass plates along their edges, the spacer adhesively bonded to two glass plates is a profiled cube made of silicone rubber, a water-containing intermediate layer that fills the transition space between the glass plates, an adhesive sealing material that seals the peripheral area between the spacer and the peripheral areas of the two glass plates. The flame retardant assembly in a preferred embodiment comprises a spacer made of a high temperature crosslinkable silicone rubber having a Shore A hardness of 40 to 60 one.

The silicone rubber has a decomposition point above 400 ° C. In a further preferred embodiment of the invention, the flame retardant assembly comprises a spacer made of high temperature crosslinkable polydimethylsiloxane. More preferably, the spacer is adhesively bonded to the glass sheets with an adhesive layer. The fireproof composition of the invention comprises a water-containing intermediate layer preferably made of a hardened alkali metal polysilicate, preferably containing from 30 to 55% by weight silicon dioxide, at most 16% by weight alkali metal oxide and up to 60% by weight water. In another preferred embodiment of the invention, the fire-resistant composition comprises a polysulfide-based adhesive as the adhesive material serving as the sealing material.

The fire-resistant assembly in another embodiment is characterized in that between the spacer and the sealing material it has a cube consisting of a thermally activatable foam material. The block consisting of the thermally activatable foam material preferably contains organic and / or inorganic substances, especially salts or oxides, which release gases when heated, such as especially water vapor, ammonia or sulfur dioxide and / or boric acid. The fire-resistant glass plate assembly in a preferred embodiment is characterized in that at least one of the glass plates is made of toughened glass. More preferably, the glass plates are bent to a substantially cylindrical or spherical shape.

From the application documentation of the invention P.354632 a set of sections and elements of a refractory wall is known, intended both as a facade wall and a partition wall of a building. The set of sections and elements of the fireproof wall consists of identical shells arranged symmetrically to each other: external and internal sections, fastened with shaped thermal breaks, and in the space created between the sections, cooling elements are symmetrically arranged to each other. There are cooling elements inside the sections. In the recess between the internal projections of thermal breaks, elements expanding under the influence of heat and pressing the cooling elements against the walls of the sections are embedded. From the outside, the outer section with the inner section is fastened with a profile overlay. From the inside, the internal and external sections are connected with a fastening wall through a rivet and a bolt. In the space between the angles and ceramic tiles, a fireproof glass is embedded, fixed with two glazing beads with gaskets. Between the fire-resistant glass and the wall connecting the sections from the inside, there is an element that expands under the influence of heat and closes the space between the fire-resistant glass and the connecting wall. Sections, profile cover plate, connecting wall, angles and are made of a non-combustible material.

From the description of the Polish invention PL208873, a set of sections and elements of the frame and sash in a fireproof structure according to the invention is known, it consists of two types of shell sections mounted alternately with one section of the same shape in the frame and sash. The different shapes of the frame are fastened with thermal breaks from the outside with a profile overlay through rivets, and on the other side, on the thermal break and the frame sections with an element that expands under the influence of heat. Elements that cool them are embedded in the space between the sections. In the recesses between the internal projections of thermal breaks, there are embedded elements that expand under the influence of heat, pressing the cooling elements against the walls of the sections. The leaf consists of various shapes connected with thermal breaks, where the element expanding under the influence of heat is embedded on the outer surface, and on the inside, the sections are connected to the fastening wall by a rivet and a bolt. In the space between the sections and the ceramic tiles, a fire-resistant glass is mounted, fixed with glazing beads with gaskets. An element expanding under the influence of heat is placed between the fire-resistant glass and the wall connecting the sections from the inside, and a gasket is placed in the C-shaped gaps at the ends of the sections, and cooling elements are embedded in the sections. The sections, the profile cover, the wall connecting the angles and thermal breaks are permanently connected with each other, and the remaining elements are loosely placed in the space in which they are located. The profile overlay, the connecting wall and the angles are made of a flame-retardant material.

The disadvantage of the solutions known from the prior art is that in each case it is meant to cool the structure by incorporating cooling cartridges which release large amounts of water bound in them during a fire. During fire tests, significant amounts of smoke and water vapor are released from these structures, making evacuation difficult. In addition, these are materials that often protect non-homogeneously, i.e. in some areas it is better, in others it is worse. This is often related to theirs

Due to brittleness and hence production errors and uncontrolled outflow of moisture (water) to the outside, instead of remaining inside the burned structure. Water is released from the entire cross section of the cooling cartridge.

The aim of the invention is to develop a solution that allows to eliminate the disadvantages of the solutions known from the state of the art and to obtain fire resistance of an aluminum structure in classes ^ from EI30 to EI120.

This aim is achieved by the aluminum section of internal and external fireproof systems such as partition walls, doors, windows etc. according to the present invention.

The essence of the invention in the form of an aluminum section of internal and external fireproof systems, such as partition walls, windows or doors, is that it contains profile parts, preferably made of extruded aluminum, forming at least one chamber, preferably closed, containing an insulating or insulating-cooling prefabricated element in the form of a perlite concrete insert. in a plastic matrix.

Preferably the perlite concrete insert is a mixture of expanded perlite, binders, additives and water, in which the binder / perlite weight ratio is 1: 6 and the water weight / binder weight ratio is from 2.4 to 2.9.

Preferably, the expanded perlite is granulated perlite, preferably with a grain size of up to 1.5 mm.

Preferably, the binders are cement and refractory cement, in a 1: 1 weight ratio, and semi-aqueous gypsum, in an amount from 1/5 to 1/3 of the total weight of binders.

Preferably the additives are: a set retarder in an amount of 0.5% to 1% of the total weight of the binders and a set fluidizer in an amount of 1% to 2% of the total weight of the binders.

Preferably, the plastic material of the matrix is a flame retardant material.

Preferably, the plastic of the matrix is PVC.

The advantage of the aluminum section of internal and external fireproof systems, such as partition walls, windows or doors, is that it acts as an insulating or insulating-cooling element during a fire. The structure of the building insulating or insulating-cooling prefabricated element filling its chamber in the form of a perlite concrete insert in a plastic matrix allows it to be securely placed in the structure to be protected, allows it to be precisely cut and glued together with a fireproof compound that guarantees a tight connection. Thanks to the matrix, the insert is not mechanically damaged during transport and installation. The insert provides insulation in fire and does not generate water vapor. In the insulating and cooling version, it can release small amounts of water vapor, but this is only the surface effect from the fire side.

The use of an insulating or insulating-cooling prefabricated element in the construction section in the form of a perlite concrete insert in a plastic matrix allows for the fire resistance of an aluminum structure in classes from EI30 to EI120.

The subject of the invention has been shown in the examples of implementation and in the drawings, in which fig. 1, fig. 7 show a prefabricated element in an elevation and in different shapes, and fig. 8 - fig. 10 an aluminum section filled in the form of a prefabricated building element in different shapes.

A building insulation or insulating-cooling prefabricated element consists of a matrix 1 filled with a perliot concrete insert in the form of a filling mixture 2.

The carcass 1 is made of a flame retardant plastic, preferably PVC.

The shape of the carcass 1 matches the shape of the inner cavity of the aluminum section of the profile parts 3 into which the carcass 1 is introduced.

The carcass 1 is made in the process of plastic extrusion as an open profile on one of the walls, or closed and subjected to processing (milling) allowing for making appropriate holes for filling with filling mixture 2.

The filler mixture 2 is perlite concrete based on perlite and various additives and binders. In perlite concrete, perlite, i.e. spiked quartz, takes over the function of a filler (aggregate), which is bound with an appropriately selected mixture of binders and additives.

The filling mixture 2 is expanded perlite, a mixture of binders and additives ensuring the necessary physicochemical properties. The binding binder is a mixture of cements - ordinary and heat-resistant and semi-water gypsum. The volume of expanded perlite is 6 times greater than the mass of the binder and the fluidizing additives in the process of creating this element constitute from 0.5 to 2.0% of the mass of the binders.

Claims (7)

PL 240 059 B1 While: - perlite is granulated perlite with a grain size of 1.5 mm; - the binder consists of: ordinary cement without additives, heat-resistant cement with a mutual weight ratio of 1: 1, semi-aqueous gypsum. The content of semi-water gypsum in the mixture of binders is from 1/5 to 1/3 of the total weight of binders, depending on the perlite used and the amount of water; - additives ensuring the necessary physicochemical properties are - in relation to the weight of the binder: - binding retarder - 0.5 + 1.0%; - binding liquefier - 1.0 ^ 2.0%; The water weight / binder weight ratio ranges from 2.4 to 2.9, depending on the perlite used. The method of manufacturing an insulating or cooling-insulating prefabricate consists of introducing the previously prepared filling mixture 2, made according to the recipe described above, into the matrix 1, compaction by vibration on a special vibrating table, and then leveling the upper surface by mechanical or manual supplementation of shortages or removal of perlite concrete surpluses. After the process, it is filled with the filling mixture 2, the precast element is set aside for aging, so that the excess water evaporates from it during the maturation process. Water evaporation takes place through holes in the matrix, which are used to fill the matrix with filling material. Maturing must last for a minimum of 10 days at a minimum temperature of 10 ° C. The finished construction insulating or insulating-cooling prefabricated element is then inserted into the appropriate internal chamber of the aluminum section of the partition wall, door, window, etc. The aluminum section used in internal and external fireproof systems, such as partition walls, doors, windows, etc., includes profile parts 3, preferably made of extruded aluminum, forming at least one chamber, preferably closed, containing an insulating or insulating-cooling prefabricated building in the form of a perlite concrete insert in a matrix made of plastic. Patent claims 1. Aluminum section of internal and external fireproof systems, such as partition walls, windows or doors, characterized in that it comprises profile parts (3), preferably of extruded aluminum, forming at least one chamber, preferably closed, containing an insulating or insulating-cooling prefabricated element in the form of an insert perlite concrete in a matrix (1) made of plastic. 2. Section according to claim The method according to claim 1, characterized in that the perlite concrete insert is a mixture of expanded perlite, binders, additives and water, in which the binder / perlite weight ratio is 1: 6 and the water weight / binder weight ratio is from 2.4 to 2.9. 3. Section according to claim 2. The process according to claim 2, characterized in that the expanded perlite is granulated perlite, preferably with a grain size of 1.5 mm. 4. Section according to claim The method according to claim 2, characterized in that the binders are: cement and refractory cement, in a 1: 1 weight ratio, and semi-aqueous gypsum, in an amount from 1/5 to 1/3 of the total weight of binders. 5. Section according to claim The method of claim 2, wherein the additives are: a set retarder in an amount of 0.5% to 1% of the total weight of the binders and a set fluidizer in an amount of 1% to 2% of the total weight of the binders. 6. Section according to claim The method of claim 1, wherein the plastic of the matrix is a flame retardant material. 7. Section according to claim The method of claim 1 or 6, characterized in that the plastic material of the matrix is PVC.