RU2682817C1 - Fixed formwork for monolithic concrete or reinforced concrete from inorganic smart glass (versions) - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to construction of buildings, structures, structures of concrete or reinforced concrete using pouring in formwork. It can be used both on a construction site and in production conditions for manufacture of prefabricated concrete or reinforced concrete structures. Technical result is achieved by one of the versions in that formwork for monolithic concrete or reinforced concrete structures erected on a construction site includes a set of elements and parts for forming a shape, at least part of enclosing shaping shell consists of inorganic glass or sitall with thickness of 0.5 mm to 150 mm, area of not less than 0.06 m, and fixed relative to poured concrete or reinforced concrete, wherein, at least, part of glass or sitall forming shell is made of smart glass or smart sitall. Smart glass or smart sitall may be made with possibility of changing transparency, color or heat transmission, incl. with automated control.EFFECT: technical result consists in reduction of power consumption for heating and / or conditioning of residential, non-residential premises, buildings created using the declared result of intellectual activity.88 cl, 2 dwg

Description

The field of technology.

The claimed result of intellectual activity, the invention relates to the construction of buildings, structures, structures of concrete or reinforced concrete using pouring into the formwork. It can be used both on a construction site and in production conditions for the manufacture of precast concrete or reinforced concrete structures.

The level of technology.

Formwork is understood as “a set of elements and parts intended to form monolithic concrete or reinforced concrete structures and structures erected at a construction site. The formwork is made of wood, metal, plywood, reinforced concrete, plastics, and other materials. The most common are collapsible, volumetric-block and sliding (movable). The choice of formwork is determined by the nature of the concrete structures (structures), the ratio of their geometric dimensions, adopted by the production technology works, climatic conditions "(" Polytechnical Dictionary ", 3rd ed. edited by A.Yu. Ishlinsky, M; Soviet Encyclopedia, 1989 - 656 p.; p. 345).

Fixed formwork is understood to mean a structure, the formwork elements of which, after setting concrete, become a functional inseparable part of a concrete or reinforced concrete product.

The prior art fixed formwork made of inorganic glass.

"Formwork for monolithic concrete or reinforced concrete structures erected at a construction site, comprising a combination of elements and parts for forming a mold, with at least a portion of the enclosing forming shell made of inorganic glass or glass metal with a thickness of 0.5 mm to 150 mm, with an area of at least 0.06 square meters, and non-removable in relation to the poured concrete or reinforced concrete. " (see. Application No. 2018100661 of January 11, 2018 for the invention of the Russian Federation "Fixed formwork for monolithic concrete or inorganic glass reinforced concrete (options)").

The disadvantage of the above prototype is the limited functions and stationarity in relation to external conditions.

Disclosure.

The objective of the claimed result of intellectual activity is the use of building structures that are adaptable to changing environmental conditions.

The technical result consists in reducing energy consumption for heating and / or air conditioning of residential, non-residential premises, buildings created using the claimed result of intellectual activity.

The indicated result according to the first embodiment is achieved in that the formwork for monolithic concrete or reinforced concrete structures erected at a construction site, including a combination of elements and parts for forming a shape, at least a part of the enclosing forming shell consists of inorganic glass or glass metal with a thickness of 0.5 mm to 150 mm, with an area of not less than 0.06 sq. m, and non-removable with respect to the poured concrete or reinforced concrete, while at least a part of the glass or ceramic glass forming shell is made from smart on glass or glass-ceramic smart.

In addition, the non-removable formwork fragment can be made of inorganic glass or glass with a linear expansion coefficient close to the similar coefficient of hardened concrete or reinforced concrete.

In addition, a glass or glass-ceramic non-removable formwork fragment can be coated on the side of the poured concrete with a substance up to 15 mm thick, enhancing adhesion to concrete or compensating for stresses at different temperature stresses, or ensuring glass or glass-free shatterproof.

In addition, a glass or glass-ceramic non-removable formwork fragment can be made of double glass or glass-metal with an interval of 2 mm to 60 mm.

In addition, the glass or glass-ceramic non-removable formwork fragment can be provided with stiffeners internal or external, or a combination of both.

In addition, the above stiffeners can have different spatial orientations.

In addition, the internal stiffening ribs may have devices for geometrical closure with hardened concrete, for example, holes or anchor elements.

In addition, a glass or glass-ceramic non-removable formwork fragment may be connected to other formwork fragments by structural jumpers.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected with other fragments of the formwork by structural bridges made of a material with low thermal conductivity.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected to the reinforced concrete internal reinforcement with structural jumpers.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected to the reinforcement of reinforced concrete with structural bridges made of a material with low thermal conductivity.

In addition, a glass or glass-ceramic non-removable formwork fragment can be made of colored glass or glass.

In addition, the formwork can be equipped with an internal heat insulator located in the middle.

In addition, the above heat insulator can be made in the form of a hollow box with internal transverse struts or partitions.

In addition, the hollow box can be made of cardboard or cardboard with sprayed internal thermal insulation with a thickness of up to 50 mm.

In addition, the inner cross struts of the box can be made in the form of a foam plastic mesh with minimized wall thickness.

In addition, the inner cross struts of the box can be made in the form of distributed rods or cylinders of cardboard or foam.

In addition, the free space of the heat insulator can be filled with airgel.

In addition, the free space of the heat insulator can be filled with foam glass.

In addition, a hollow cardboard box can be treated with an antiseptic against rodents and insects.

In addition, concrete can be reinforced with rods or mesh, or fiberglass, or combinations thereof.

In addition, concrete layers separated by a heat insulator can be interconnected by periodic bar reinforcement made of a material with low thermal conductivity.

According to the second option, formwork for monolithic concrete or reinforced concrete structures or structures erected at a construction site, including a set of elements and parts for forming a mold, including the formation of at least one hollow volume for subsequent filling with a heat insulator, at least at least, a part of the enclosing forming shell consists of inorganic glass or ceramic glass with a thickness of 0.5 mm to 150 mm, an area of 0.06 sq.m., and non-removable with respect to the poured concrete or reinforced concrete, while At least a portion of the glass or molding pyroceramics shell may be made of glass or smart smart glass-ceramic.

In addition, the glass or glass-ceramic non-removable formwork fragment can be made of inorganic glass or glass with a coefficient of linear expansion close to the same coefficient of the hardened concrete or reinforced concrete.

In addition, a glass or glass-ceramic non-removable formwork fragment can be coated on the side of the poured concrete with a substance up to 15 mm thick, enhancing adhesion to concrete or compensating for stresses at different temperature stresses, or ensuring glass-free or glass-free shatterproofing.

In addition, a glass or glass-ceramic non-removable formwork fragment can be made of double glass or glass-metal with an interval of 2 mm to 60 mm.

In addition, the glass or glass-ceramic non-removable formwork fragment can be provided with stiffeners internal or external, or a combination of both.

In addition, the stiffeners can have different spatial orientations.

In addition, the internal stiffening ribs may have devices for geometrical closure with hardened concrete, for example, holes or anchor elements.

In addition, a glass or glass-ceramic non-removable formwork fragment may be connected to other formwork fragments by structural jumpers.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected with other fragments of the formwork by structural bridges made of a material with low thermal conductivity.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected to the reinforced concrete internal reinforcement with structural jumpers.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected to the reinforcement of reinforced concrete with structural bridges made of a material with low thermal conductivity.

In addition, a glass or glass-ceramic non-removable formwork fragment can be made of colored glass or colored glass.

In addition, at least one formed free space may be filled with an airgel heat insulator.

In addition, at least one formed free space may be filled with foam glass with a heat insulator.

In addition, at least one formed free space may be filled with a foam insulator.

In addition, at least one formed free space can be filled with a foam insulator by pouring.

In addition, at least one formed free space can be filled with a heat-insulator with Mipora foam.

In addition, at least one formed free space can be filled with a heat-insulator with Mipora foam by the pouring method.

In addition, at least one formed free space may be filled with dispersed or fibrous thermal insulation material.

In addition, concrete layers separated by a heat insulator can be interconnected by periodic bar reinforcement made of a material with low thermal conductivity.

According to the third option, formwork for prefabricated monolithic concrete or reinforced concrete structures manufactured at the factory, including a set of elements and parts for forming a shape, at least a part of the enclosing forming shell consists of inorganic glass or glass metal with a thickness of 0.5 mm to 150 mm, area not less than 0.01 sq. m and non-removable in relation to the poured concrete or reinforced concrete, while at least part of the glass or glass-forming shell is made of smart glass or smart glass.

In addition, the glass or glass-ceramic non-removable formwork fragment can be made of inorganic glass or glass with a coefficient of linear expansion close to the same coefficient of the hardened concrete or reinforced concrete.

In addition, a glass or glass-ceramic non-removable formwork fragment can be coated on the side of the poured concrete with a substance up to 15 mm thick, enhancing adhesion to concrete or compensating for stresses at different temperature stresses, or ensuring glass-free or glass-free shatterproofing.

In addition, a glass or glass-ceramic non-removable formwork fragment can be made of double glass or glass-metal with an interval of 2 mm to 60 mm.

In addition, the glass or glass-ceramic non-removable formwork fragment can be provided with stiffeners internal or external, or a combination of both.

In addition, the stiffeners can have different spatial orientations.

In addition, the internal stiffening ribs may have devices for geometrical closure with hardened concrete, for example, holes or anchor elements.

In addition, a glass or glass-ceramic non-removable formwork fragment may be connected to other formwork fragments by structural jumpers.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected with other fragments of the formwork by structural bridges made of a material with low thermal conductivity.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected to the reinforced concrete internal reinforcement with structural jumpers.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected to the reinforcement of reinforced concrete with structural bridges made of a material with low thermal conductivity.

In addition, a glass or glass-ceramic non-removable formwork fragment can be made of colored glass or colored glass.

In addition, the formwork can be equipped with an internal heat insulator.

In addition, the heat insulator can be made in the form of a hollow box with internal transverse struts or partitions.

In addition, the hollow box can be made of cardboard or cardboard with sprayed internal thermal insulation with a thickness of up to 50 mm.

In addition, the inner cross struts of the box can be made in the form of a foam plastic mesh with minimized wall thickness.

In addition, the inner cross struts of the box can be made in the form of distributed rods or cylinders of cardboard or foam.

In addition, the free space of the heat insulator can be filled with airgel.

In addition, the free space of the heat insulator can be filled with foam glass.

In addition, a hollow cardboard box can be treated with an antiseptic against rodents and insects.

In addition, concrete can be reinforced with rods, or mesh, or fiberglass, or combinations thereof.

In addition, concrete layers separated by a heat insulator can be interconnected by periodic bar reinforcement made of a material with low thermal conductivity.

According to the fourth variant, formwork for prefabricated monolithic concrete or reinforced concrete structures manufactured in production, including a set of elements and parts for forming a mold, including the formation of at least one hollow volume for subsequent filling with a heat insulator, at least the part of the enclosing forming shell consists of inorganic glass or ceramic glass with a thickness of 0.5 mm to 150 mm, an area of at least 0.01 sq.m., and non-removable with respect to the poured concrete or reinforced concrete, while shey least a portion of the glass or molding pyroceramics smart shell made of glass or glass-ceramic smart.

In addition, the glass or glass-ceramic non-removable formwork fragment can be made of inorganic glass or glass with a coefficient of linear expansion close to the same coefficient of the hardened concrete or reinforced concrete.

In addition, a glass or glass-ceramic non-removable formwork fragment can be coated on the side of the poured concrete with a substance up to 15 mm thick, enhancing adhesion to concrete or compensating for stresses at different temperature stresses, or ensuring glass-free or glass-free shatterproofing.

In addition, a glass or glass-ceramic non-removable formwork fragment can be made of double glass, with an interval from 2 mm to 60 mm.

In addition, the glass or glass-ceramic non-removable formwork fragment can be provided with stiffeners internal or external, or a combination of both.

In addition, the stiffeners can have different spatial orientations.

In addition, the internal stiffening ribs may have devices for geometrical closure with hardened concrete, for example, holes or anchor elements.

In addition, a glass or glass-ceramic non-removable formwork fragment may be connected to other formwork fragments by structural jumpers.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected with other fragments of the formwork by structural bridges made of a material with low thermal conductivity.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected to the reinforced concrete internal reinforcement with structural jumpers.

In addition, a glass or glass-ceramic non-removable formwork fragment can be connected to the reinforcement of reinforced concrete with structural bridges made of a material with low thermal conductivity.

In addition, a glass or glass-ceramic non-removable formwork fragment can be made of colored glass or colored glass.

In addition, at least one formed free space may be filled with an airgel heat insulator.

In addition, at least one formed free space may be filled with foam glass with a heat insulator.

In addition, at least one formed free space may be filled with a foam insulator.

In addition, at least one formed free space can be filled with a foam insulator by pouring.

In addition, at least one formed free space can be filled with a heat-insulator with Mipora foam.

In addition, at least one formed free space can be filled with a heat-insulator with Mipora foam by the pouring method.

In addition, at least one formed free space may be filled with dispersed or fibrous thermal insulation material.

In addition, concrete layers separated by a heat insulator can be interconnected by periodic bar reinforcement made of a material with low thermal conductivity.

In addition, according to any of the options, inorganic glass or glass-ceramic in a shatterproof version can be used. For example triplex or glass / glass with one-sided bonding with a polymer film.

In addition, according to any of the options, smart glass or smart glass made with the possibility of changing transparency can be used.

In addition, according to any of the options, smart glass or smart glass made with the ability to change color can be used.

In addition, according to any of the options, smart glass or smart glass made with the possibility of changing heat transmission can be used.

In addition, according to any of the options, smart glass or smart glass with automated control can be used.

Inorganic glass is understood as “a transparent (colorless or colored) brittle material obtained by cooling a melt containing glass-forming components (usually oxides of silicon, boron, aluminum, phosphorus, titanium, zirconium, etc.) and metal oxides (lithium, potassium, sodium (calcium, magnesium, lead, etc.). According to the type of glass-forming component, there are distinguished SN silicate (based on SiO ₂ ), borate (В ₂ О ₃ ), borosilicate, aluminosilicate, boroaluminosilicate, etc. In addition to oxide, apply halide (fluorozirconate, fluoroberryl i.e., chalcogenide, etc. S.N. Due to the ability to give S.N. (changing its composition and conditions of heat treatment) various properties - optical, mechanical, thermal, chemical, etc. - it is common in various branches of engineering, construction , industry, decorative arts, at home. " (see. "Polytechnical Dictionary", 3rd ed., edited by A.Yu. Ishlinsky, M; Soviet Encyclopedia, 1989 - 656 p., p. 502).

By “glass crystals” we mean “glass-crystalline materials obtained by introducing seeds (catalysts) into the molten glass, as a result of which crystallization centers appear on the glass volume, on which microcrystals of the main phase grow. By changing the glass composition, the type of catalyst, and the heat treatment mode, C. can be obtained with certain properties, glass metals have high strength, hardness, chemical and thermal stability, low thermal expansion. technical materials made on the basis of artificial compositions from a variety of chemical compounds - oxides, salts, petro-crystals obtained on the basis of rocks (basalts, diabases, etc.), and slag-metals, the raw materials of which are metallurgical and fuel slags. ordinary glass (molding from molten glass) or ceramic. (molding from glass powder) technologies crystallize (in two or multi-stage mode) at high temperatures (700-1400 gr. Celsius). The main products from Sitall - sheet material, plates, panels, electrical insulators, bearings, dies, grinding media, chemical. equipment, pipes, containers, details of electronic and optical devices. (see. "Polytechnical Dictionary", 3rd ed., edited by A.Yu. Ishlinsky, M; Soviet Encyclopedia, 1989 - 656 p., p. 484) .

Under the triplex is understood - "a kind of shatterproof glass, consisting of two glass sheets fastened together by a polymer film" (see. "Polytechnical Dictionary", 3rd ed. Edited by A.Yu. Ishlinsky, M; Soviet Encyclopedia, 1989 . - 656 s; p. 546).

There is inorganic glass with a one-sided coating of a polymer film, it is also shatterproof and more durable and impact resistant with smaller dimensions in thickness.

By “airgel” we mean “a class of materials that are a gel in which the liquid phase is completely replaced by a gaseous one. Such materials have a record low density and exhibit a number of unique properties: hardness, transparency, heat resistance, extremely low thermal conductivity, etc. Aerogels based on amorphous silica, alumina, and also chromium and tin oxides. The first carbon-based airgel samples were obtained in the early 1990s. " (Wikipedia; https://en.wikipedia.org/wiki/%D0%90%D1%8D%D1%80%D0%BE%D0%B3%D0%B5%D0%BB%D1%8C).

Foam glass is understood as “Foam glass (foamed glass, cellular glass) - a heat-insulating material that is foam glass. For the manufacture of foam glass, the ability of silicate glasses to soften and (in the case of a blowing agent) is foamed at temperatures of about 1000 ° C. As viscosity increases at cooling the expanded glass melt to room temperature, the resulting foam acquires substantial mechanical strength. " (Wikipedia; https://en.wikipedia.org/wiki/%D0%9F%D0%B5%D0%BD%D0%BE%D1%81%D1%82%D0%B5%D0%BA%D0% BB% D0% BE).

Under the foam is understood - "Foam - a class of materials, which is a foamed (cellular) plastic mass.

Since the bulk of the foam is gas, the density of the foam is significantly lower than the density of its feedstock (polymer). This leads to relatively high thermal insulation properties (convection heat transfer takes place in a single cell, heat transfer along the walls of the cells is insignificant due to their small thickness) and soundproof properties (thin and relatively elastic cell walls are a poor conductor of sound vibrations) of materials of this class.

Foams were obtained from almost all the most widely used plastics (polymers), therefore the most famous materials of this class are: polyurethane foams, polyvinyl chloride foams, phenol-formaldehyde, urea-formaldehyde foams and polystyrene foam.

Depending on the composition of the raw material and the technology of its processing, it is possible to produce polystyrene of different density, mechanical strength, resistance to various types of exposure. These factors determine the choice of a particular type of foam for use in certain conditions and purposes.

In everyday life, a person most often encounters such a type of polystyrene as unpressed polystyrene foam (it was invented by BASF in 1951, the trade name is “styrofoam”). Styrofoam granules (PSV / EPS) are prepared by polymerizing styrene while adding a pore-forming substance (pentane). PSB-S polystyrene (expanded polystyrene, styrofoam) is a well-known thermal insulation material, 98% composed of gas enclosed in microscopic thin-walled polystyrene cells. "(Wikipedia; https://ru.wikipedia.org/wiki/%D0%9F % D0% B5% D0% BD% D0% BE% D0% BF% D0% BB% D0% B0% D1% 81% D1% 82).

Penoizol (mipora) is understood as urea-formaldehyde polystyrene (urea foam, CFP) - a universal heater. It first appeared in Germany in the late 30s. It was actively used in the 50s. Currently, the volume of urea-based heaters -formaldehyde resins abroad make up about 30% of all heat insulation materials produced in the USSR under the name Mipora, but were not widely used due to the lack of special resins required for its production and equipment technologies. After the 90s, it began to actively enter the market of building insulation under various trademarks. The most famous of them are: Penoizol (a trademark of New Building Technologies LLC), Mettemplast, Poroplast cf, Pentil, Omifleks, Unipor. "( Wikipedia; https://en.wikipedia.org/wiki/%D0%9A%D0%В0%D1%80%D0%B1%D0%B0%D0%BC%D0%B8%D0%B4%D0%BD % D0% BE-% D1% 84% D0% BE% D1% 80% D0% BC% D0% B0% D0% BB% D1% 8C% D0% B4% D0% B5% D0% B3% D0% B8% D0% B4% D0% BD% D1% 8B% D0% B9_% D0% BF% D0% B5% D0% BD% D0% BE% D0% BF% D0% BB% D0% B0% D1% 81% D1% 82).

Smart glass (or smart glass) is understood as “smart glass”, “electrochromic glass”, “glass with changing properties”) - a composite of layers of glass and various chemical materials used in architecture and production for the manufacture of translucent structures (windows,

partitions, doors, etc.) that changes its optical properties (opalescence (dullness), light transmission coefficient, heat absorption coefficient, etc.) when changing external conditions, for example, illumination, temperature or when applying electrical voltage (see Wikipedia https://en.wikipedia.org/wiki/%D0%A3%D0%BC%D0%BD%D0%BE%D0%B5_%D1%81%D1%82% D0% B5% D0% VA% D0 % BB% D0% BE)

Description of the drawings.

The claimed result of intellectual activity in one of its possible embodiments is shown in the attached images of FIG. 1 is a cross section with an internal heat insulator mounted prior to pouring concrete, and FIG. 2 cross section with the formation of a heat insulator after pouring concrete.

In FIG. 1 shows: fixed panels of inorganic glass formwork - 1; monolithic concrete or reinforced concrete layers - 2; built-in formwork module heat insulator-box - 3; the dashed line (-----) shows the jumpers connecting the glass panels 1 of a low heat conductive material.

Tie rods made of low heat conductive material between concrete layers 2; internal structure of the heat insulator 3; reinforcement of concrete layers 2; stiffeners on glass panels 1 - conventionally not shown. FIG. 1 illustrates embodiments of the invention 1 and 2.

In FIG. 2 shows: fixed panels of inorganic glass formwork - 1; monolithic concrete or reinforced concrete layers - 2; filled in foam insulator 4; fixed internal panels, which can be made of glass or other materials for economic reasons (for example, LSU) - 5; the dashed line (-----) shows the jumpers connecting the glass panels 1 of a low heat conductive material.

FIG. 2 illustrates embodiments 3 and 4.

Tie rods made of low heat conductive material between concrete layers 2; reinforcement of concrete layers 2; stiffeners / anchors on the glass panels 1, the material on the inner surfaces of the glass panels to compensate for stresses when the difference in thermal expansion is not conventionally shown.

In FIG. 1 and FIG. 2 conditionally indicated functional elements 6 smart glass or smart glass.

Exercise.

The claimed result of intellectual activity can be implemented as follows.

According to the first option. The company manufactures modules of permanent formwork: two sheets of inorganic glass 1 with a thickness of 4-8 mm (triplex or safety glass with a single-sided coating of a polymer film is possible). Length 2000 mm, height 1500 mm. Glass sheets are interconnected by several vertically flat bridges made of heat insulating material (for example, LSU). The distance between the glass panels is 500 mm. In the middle of the module there is a closed cardboard box 2000 * 1500 * 200 mm (L * H * W), which is a built-in heat insulator of the module - 3. Interpanel jumpers between the glasses pass through it. Inside, a cardboard box to counter poured concrete is equipped with cross struts. This can be a 200 mm thick lattice made of polystyrene foam made of flat elements (to save material), stiffeners made of cardboard, unconnected core elements glued to the inner walls of the box. The core elements can be made of foam, cardboard, foam glass, etc. The flat jumpers passing through the heat insulator box connecting the glass panels are sealed at the places of entry into the heat insulator so that the concrete 2 being poured does not get inside the insulator. Sealing can be rubber cuffs, mastic, adhesive tape, etc. In addition, the cardboard box itself can be coated from the inside with additional thermal insulation, for example foam rubber. This will serve to suppress the convection flows inside it (in addition to the fact that it is internally divided into separate sections by spacers) and increase the heat-insulating qualities.

Modules of fixed formwork are assembled together due to the use of a spike-groove ("angled protrusion-angled recess") design around the glass perimeter. A similar design around the perimeter has a heat insulator-cardboard box 3, due to which a complete circular perimeter of the modules is assembled, while there are no butt end gaps between adjacent glass panels 1 and adjacent heat-insulating boxes 3 that are inside the modules. For additional sealing, duct heat insulators on all their end surfaces can have soft foam pads.

The result is the following construction in the context: glass 1 with a thickness of 4-10 mm, then a gap of 150 mm for pouring concrete 2, then a 200 mm box-heat insulator 3, then again a gap of 150 mm for pouring concrete 2, and the outer glass 1.

Two layers of monolithic concrete 2, which turned out on opposite sides of the heat insulator 3, are equipped with reinforcement: rod (vertical and horizontal), mesh, fiber. Mesh fittings can be installed at the factory in the module itself within its dimensions. The rod is installed on the construction site during installation and is expanded in the usual way (preferably by modern screwing of the corresponding mating elements).

Two concrete layers are interconnected by rods of material with low thermal conductivity (for example, of chemical fibers and epoxy), these connecting rods pass between heat-insulating boxes in their vertical joints in special gutters (using lip seals from foam to prevent ingress of concrete). The drawing is not conventionally shown.

In addition, glass panels are provided with stiffeners. Glass strips are glued / soldered from the inside with their ribs to the plane of the panel. In the stiffeners themselves, holes were made for closure with poured and solidified concrete (anchor closure). Filling is carried out in parallel on both sides of the heat insulator 3, to prevent its shift. Glass panels 1 of fixed formwork will allow the effective use of external vibrators-compactors of concrete mix due to the hardness and stiffness of the glass.

To compensate for the difference in the coefficients of linear expansion a between glass and concrete (~ 9 * 10 ^-6 C and ~ 14.5 * 10 ^-6 C), the following solutions can be used:

- there are various glasses with different mechanical characteristics, including with metal additives that have a temperature coefficient of linear expansion, as in reinforced concrete (see, adj. materials);

- it is possible to apply a polymer film (for example, as with triplex technology) to a glass surface conjugated with concrete or a substance with a small modulus of elasticity, which will take the tangential (tangential) deformation difference (approximately ~ 4 μm per 1 degree over a length of 1 m), at the same time, shatterproof and additional strength of the glass will be provided along the way.

In the manufacture of the outer glass panel from double glass with a gap between them, the effect of a window pane is obtained. A monolithic structure will accumulate insolation energy.

In the second embodiment, the claimed result of intellectual activity can be carried out as follows. The modules form a structure with three vertically divided volumes. External 2 have a thickness of 130-160 mm and are poured with reinforced concrete, the internal volume 4 with a thickness of 200-500 mm (no restrictions) is filled with foam. The best option is to fill with penoizole (mipora), because it is an extremely effective and cheap polystyrene. Rodents are indifferent to it, it is poured right away in the form of foam, and not a swelling liquid (http://penoizol-logrus.ru/uslugi/uteplenie-penoizol). In this case, the filling lines can be immediately laid on the bottom of the insulated medium volume (these perforated hoses will remain there), and the filling should be done according to the bottom-up principle, which will make it possible to obtain a single monolithic heat-insulating cocoon without defects and voids immediately on the entire building / structure.

In this case, the lack of penoizol (mipores): hygroscopicity exceeding polystyrene will be fully compensated by the device of the invention, because glass is an ideal moisture and vapor impermeable material.

Using the claimed result of intellectual activity in the third and fourth options is similar to the above. The difference in application for prefabricated reinforced concrete structures manufactured at enterprises. Those. It can be slabs for panel house building, wall blocks, wall stones or even bricks. Moreover, fixed glass can be both on 6 faces of the box, and only on one, for example, located on the side of the street.

The heat insulator can be built-in before concrete pouring (duct), and can be filled after monolithic external volumes. Filling the cavity between hardened concrete forms with foam.

The inventive fixed formwork can be used in one-, two- and multi-story construction.

Inorganic glass qualities such as weather resistance, vapor impermeability, durability, preservation of color and surface quality, and the absence of the need for subsequent finishing are significant advantages.

In addition, in the claimed result of intellectual activity, the use of glass (or at least part) of smart glass (or smart glass) in glass (glass) glass-forming shells allows us to solve the problem of adapting the building structure to external conditions. For example, by changing color, increase the flow of reflected thermal energy in a hot period and vice versa.

In particular, smart glass "StekloBurg" (https://steklo-burg.ru/smart-steklo/) or "Privat Glass / PRIVATE GLASS" (http: //www.рrivateglass.ru/tech/pg- magic-steklo-s-peremennoy-prozrachnostyu /).

The claimed result of intellectual activity meets the criterion of "industrial applicability".

Claims (88)

1. Formwork for monolithic concrete or reinforced concrete structures erected at a construction site, including a set of elements and parts for forming a mold, while at least part of the enclosing forming shell consists of inorganic glass or glass metal with a thickness of 0.5 mm to 150 mm , with an area of not less than 0.06 sq. m, and non-removable with respect to the poured concrete or reinforced concrete, characterized in that at least a part of the glass or glass metal forming shell is made of smart glass or smart glass. 2. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that the non-removable fragment of the formwork is made of inorganic glass or glass with a coefficient of linear expansion close to the similar coefficient of filled hardened concrete or reinforced concrete. 3. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that the glass or glass-ceramic non-removable formwork fragment is coated on the side of the poured concrete with a substance up to 15 mm thick, enhancing adhesion to concrete, or compensating for stresses at various temperature stresses, or providing shatterproof glass or glass. 4. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that the glass or glass-ceramic non-removable formwork fragment is made of double glass or glass with a gap of 2 mm to 60 mm. 5. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is provided with internal or external stiffeners or a combination thereof. 6. Formwork for monolithic concrete or reinforced concrete structures according to claim 5, characterized in that the stiffeners have different spatial orientations. 7. Formwork for monolithic concrete or reinforced concrete structures according to claim 5, characterized in that the internal stiffeners have devices for geometric locking with solidified concrete, for example holes or anchor elements. 8. The formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that the glass or glass-ceramic non-removable formwork fragment is connected to other formwork fragments by structural jumpers. 9. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that the glass or glass-ceramic non-removable formwork fragment is connected with other fragments of the formwork by structural bridges made of a material with low thermal conductivity. 10. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that the glass or glass-ceramic fixed part of the formwork is connected to the reinforcement of the reinforced concrete with structural jumpers. 11. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is connected to the internal reinforcement of reinforced concrete with structural bridges made of a material with low thermal conductivity. 12. Formwork for monolithic concrete or reinforced concrete structures according to paragraphs. 1, 4, characterized in that the glass or glass-ceramic non-removable formwork fragment is made of colored glass or glass. 13. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that it is equipped with an internal heat insulator. 14. Formwork for monolithic concrete or reinforced concrete structures according to claim 13, characterized in that the heat insulator is made in the form of a hollow duct with internal cross braces or partitions. 15. Formwork for monolithic concrete or reinforced concrete structures according to claim 13, characterized in that the hollow box is made of cardboard or cardboard with sprayed internal thermal insulation up to 50 mm thick. 16. Formwork for monolithic concrete or reinforced concrete structures according to claim 13, characterized in that the inner cross struts of the duct are made in the form of a foam plastic mesh with minimized wall thickness. 17. The formwork for monolithic concrete or reinforced concrete structures according to claim 13, characterized in that the internal lateral struts of the duct are made in the form of distributed rods or cylinders of cardboard or foam. 18. Formwork for monolithic concrete or reinforced concrete structures according to claim 13, characterized in that the free space of the heat insulator is filled with airgel. 19. Formwork for monolithic concrete or reinforced concrete structures according to claim 13, characterized in that the free space of the heat insulator is filled with foam glass. 20. Formwork for monolithic concrete or reinforced concrete structures according to claim 13, characterized in that the hollow cardboard box is treated with an antiseptic against rodents and insects. 21. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that the concrete is reinforced with rods, or mesh, or fiber-optic, or combinations thereof. 22. Formwork for monolithic concrete or reinforced concrete structures according to paragraphs. 1, 13, characterized in that the concrete layers separated by a heat insulator are interconnected by periodic rod reinforcement made of a material with low thermal conductivity. 23. Formwork for monolithic concrete or reinforced concrete structures or structures erected at a construction site, including a set of elements and parts for forming a mold, incl. the formation of at least one hollow volume for subsequent filling with a heat insulator, while at least part of the enclosing forming shell consists of inorganic glass or glass metal with a thickness of 0.5 mm to 150 mm, an area of 0.06 sq m , and non-removable with respect to the poured concrete or reinforced concrete, characterized in that at least a part of the glass or glass-forming shell is made of smart glass or smart glass. 24. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is made of inorganic glass or glass with a coefficient of linear expansion close to the similar coefficient of solidified concrete or reinforced concrete. 25. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is coated on the side of the poured concrete with a substance up to 15 mm thick, enhancing adhesion to concrete, or compensating for stresses at various temperature stresses, or providing shatterproof glass or glass. 26. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that the glass or glass-ceramic non-removable formwork fragment is made of double glass or glass-metal with an interval of 2 mm to 60 mm. 27. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is provided with internal or external stiffeners or a combination thereof. 28. Formwork for monolithic concrete or reinforced concrete structures according to claim 27, characterized in that the stiffeners have different spatial orientations. 29. The formwork for monolithic concrete or reinforced concrete structures according to claim 27, characterized in that the internal stiffeners have devices for geometric locking with solidified concrete, such as holes or anchor elements. 30. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that the glass or glass-ceramic fixed part of the formwork is connected with other fragments of the formwork by structural jumpers. 31. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is connected to other fragments of the formwork by structural bridges made of a material with low thermal conductivity. 32. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is connected to the reinforcement of the concrete with structural jumpers. 33. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is connected to the internal reinforcement of reinforced concrete with structural bridges made of a material with low thermal conductivity. 34. Formwork for monolithic concrete or reinforced concrete structures according to paragraphs. 23, 26, characterized in that the glass or glass-ceramic non-removable formwork fragment is made of colored glass or colored glass. 35. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that at least one formed free space is filled with an airgel heat insulator. 36. The formwork for monolithic concrete or reinforced concrete structures according to p. 23, characterized in that at least one formed free space is filled with heat insulator foam glass. 37. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that at least one formed free space is filled with a foam insulator. 38. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that at least one formed free space is filled with a foam insulator using a pouring method. 39. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that at least one formed free space is filled with a heat-insulator foam Mipora. 40. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that at least one formed free space is filled with a heat-insulator with Mipora foam by the pouring method. 41. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that at least one formed free space is filled with dispersed or fibrous thermal insulation material. 42. The formwork for monolithic concrete or reinforced concrete structures according to claim 23, characterized in that the concrete layers separated by a heat insulator are interconnected by periodic bar reinforcement made of a material with low thermal conductivity. 43. Formwork for prefabricated monolithic concrete or reinforced concrete structures manufactured in the production, including a set of elements and parts for forming a mold, while at least part of the enclosing forming shell consists of inorganic glass or glass metal with a thickness of 0.5 mm to 150 mm , with an area of not less than 0.01 sq. m, and non-removable with respect to the poured concrete or reinforced concrete, characterized in that at least a part of the glass or glass metal forming shell is made of smart glass or smart glass a. 44. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, wherein the glass or glass-ceramic non-removable formwork fragment is made of inorganic glass or glass with a coefficient of linear expansion close to the similar coefficient of solidified concrete or reinforced concrete. 45. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the glass or glass-metal fixed piece of the formwork is coated on the side of the poured concrete with a substance up to 15 mm thick, enhancing adhesion to concrete, or compensating for stresses at various temperature stresses, or ensuring safety of glass or glass. 46. Formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the glass or glass-ceramic non-removable formwork fragment is made of double glass or glass-metal with an interval of 2 mm to 60 mm. 47. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is provided with internal or external stiffeners or a combination thereof. 48. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the stiffeners have different spatial orientations. 49. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the internal stiffeners have devices for geometric locking with solidified concrete, for example holes or anchor elements. 50. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is connected with other fragments of the formwork by structural jumpers. 51. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the glass or glass-ceramic non-removable formwork fragment is connected to other formwork fragments with structural bridges made of a material with low thermal conductivity. 52. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is connected to the reinforcement of the reinforced concrete with structural jumpers. 53. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the glass or glass-ceramic non-removable formwork fragment is connected to the reinforcement of the reinforced concrete with structural bridges made of a material with low thermal conductivity. 54. Formwork for precast monolithic concrete or reinforced concrete structures according to paragraphs. 43, 46, characterized in that the glass or glass-ceramic non-removable formwork fragment is made of colored glass or colored glass. 55. Formwork for monolithic concrete or reinforced concrete structures according to claim 1, characterized in that it is equipped with an internal heat insulator. 56. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 55, characterized in that the heat insulator is made in the form of a hollow duct with internal transverse struts or partitions. 57. Formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 55, characterized in that the hollow box is made of cardboard or cardboard with sprayed internal thermal insulation up to 50 mm thick. 58. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 55, characterized in that the internal transverse struts of the duct are made in the form of a foam plastic mesh with minimized wall thickness. 59. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 55, characterized in that the internal transverse struts of the box are made in the form of distributed rods or cylinders of cardboard or foam. 60. Formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 55, characterized in that the free space of the heat insulator is filled with airgel. 61. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 55, characterized in that the free space of the heat insulator is filled with foam glass. 62. Formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 55, characterized in that the hollow cardboard box is treated with an antiseptic against rodents and insects. 63. Formwork for precast monolithic concrete or reinforced concrete structures according to claim 43, characterized in that the concrete is reinforced with rods, or mesh, or fiber, or combinations thereof. 64. Formwork for monolithic concrete or reinforced concrete structures according to paragraphs. 43, 55, characterized in that the concrete layers separated by a heat insulator are interconnected by periodic rod reinforcement made of a material with low thermal conductivity. 65. Formwork for prefabricated monolithic concrete or reinforced concrete structures manufactured in production, including a combination of elements and parts for forming a mold, incl. the formation of at least one hollow volume for subsequent filling with a heat insulator, while at least part of the enclosing forming shell consists of inorganic glass or glass metal with a thickness of 0.5 mm to 150 mm, an area of at least 0.01 square meters. m, and non-removable in relation to the poured concrete or reinforced concrete, characterized in that at least a portion of the glass or glass-forming shell is made of smart glass or smart glass. 66. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that the glass or glass-ceramic non-removable formwork fragment is made of inorganic glass or glass with a coefficient of linear expansion close to the similar coefficient of filled hardened concrete or reinforced concrete. 67. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is coated on the side of the poured concrete with a substance up to 15 mm thick, enhancing adhesion to concrete, or compensating for stresses at various temperature stresses, or ensuring safety of glass or glass. 68. Formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that the glass or glass-ceramic non-removable formwork fragment is made of double glass with a gap of 2 mm to 60 mm. 69. Formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that the glass or glass-ceramic non-removable formwork fragment is provided with internal or external stiffeners or a combination thereof. 70. Formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 69, characterized in that the stiffeners have different spatial orientations. 71. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 69, characterized in that the internal stiffeners have devices for geometrical closure with hardened concrete, such as holes or anchor elements. 72. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is connected with other fragments of the formwork by structural jumpers. 73. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is connected with other fragments of the formwork by structural bridges made of a material with low thermal conductivity. 74. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that the glass or glass-ceramic non-removable fragment of the formwork is connected to the reinforcement of the reinforced concrete with structural jumpers. 75. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that the glass fixed piece of the formwork is connected to the internal reinforcement of the reinforced concrete with structural bridges made of a material with low thermal conductivity. 76. Formwork for precast monolithic concrete or reinforced concrete structures according to paragraphs. 65, 68, characterized in that the glass or glass-ceramic non-removable formwork fragment is made of colored glass or colored glass. 77. The formwork for precast monolithic concrete or reinforced concrete structures according to claim 65, characterized in that at least one formed free space is filled with an airgel heat insulator. 78. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that at least one formed free space is filled with a foam glass thermal insulator. 79. The formwork for precast monolithic concrete or reinforced concrete structures according to claim 65, characterized in that at least one formed free space is filled with a foam insulator. 80. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that at least one formed free space is filled with a foam insulator using a pouring method. 81. Formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that at least one formed free space is filled with a heat-insulator with a mipora foam. 82. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that at least one formed free space is filled with a heat-insulator with a mipora foam by the pouring method. 83. The formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that at least one formed free space is filled with dispersed or fibrous thermal insulation material. 84. Formwork for prefabricated monolithic concrete or reinforced concrete structures according to claim 65, characterized in that the concrete layers separated by a heat insulator are interconnected by periodic reinforcing bars made of a material with low thermal conductivity. 85. Formwork for monolithic concrete or reinforced concrete structures according to paragraphs. 1, 23, 43, 65, characterized in that the inorganic glass is made in any of the shatterproof versions. 86. Formwork for monolithic concrete or reinforced concrete structures according to paragraphs. 1, 23, 43, 65, characterized in that the smart glass or smart glass is made with the possibility of changing transparency. 87. Formwork for monolithic concrete or reinforced concrete structures according to paragraphs. 1, 23, 43, 65, characterized in that the smart glass or smart glass is made with the ability to change color. 88. Formwork for monolithic concrete or reinforced concrete structures according to paragraphs. 1, 23, 43, 65, characterized in that the smart glass or smart glass is made with the possibility of changing heat transmission.

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