RU191078U1 - Wall-mounted warm-cold building envelope - Google Patents

Abstract

The utility model relates to construction, in particular to building fencing systems with thermal insulation and decoration of external walls and facades. The technical objective of the present invention is to reduce the complexity and time of installation of a facade curtain rail and the cost of its operation due to the manufacture of “cold” and "Warm" modules while improving thermal performance and reliability to the perception of atmospheric effects (wind loads, protection against blowing and leaks). This result is achieved due to the fact that in the known hinged heat-cold building envelope made of separate blocks (modules) located in the “warm” and “cold” areas of the building facade, each module containing a metal frame of the frame made of vertically oriented profile racks and horizontally oriented profile imposts, the modules being joined to each other using seals, the modules themselves are attached to the building with supports, one part of which is rigidly connected to the building, etc. goy with the corresponding module, the module frame can be filled in whole or in part with double-glazed windows or sheet panels, changes are made, namely: - racks and imposts of the frame (frame) of the module located in the “warm” area of the building facade, are combined and consist of two parts (external and internal) connected by thermal inserts (thermal bridges); - and their bearing part is located on the outside of the building and connected to the module located in the "cold" zone, by means of an elastic sealant. In addition, in the fence Other changes have been made. Currently, on the basis of pilot tests of the claimed building envelope, work has been completed on the creation of technical documentation for the mass production of various versions of the hinged heat-cold building envelope of the building facade. 3 s.p. f-ly, 7 ill.

Description

The utility model relates to the construction and repair of buildings and structures for civil, industrial and agricultural purposes, in particular to fencing systems for buildings with thermal insulation and decoration of external walls and facades, to give them aesthetic qualities and to increase the degree of thermal insulation and protection from external atmospheric phenomena.

The facade forms the external appearance of the building, is its hallmark. However, it is a mistake to believe that the facade of the building carries only a decorative function. Properly selected and high-quality facade decoration protects the building from the effects of the external environment, so it is very important that the facade is always in perfect condition. The main goals that facade works pursue are insulation and protection of buildings from the effects of external atmospheric phenomena, as well as improving their aesthetic qualities. Energy-saving tasks have become a determining factor in the evolution of facade systems

Building envelope - building structures (walls, floors, partitions, etc.) that form the outer shell of the building, protecting it from the effects of heat, cold, moisture, wind, etc., and also divide the building into separate rooms.

The “warm” zone of the building facade is the area of the facade behind which there is a heated room, usually an opening formed vertically between the ceilings or the parapet and the ceiling, horizontally between the walls.

The “cold” zone of the building facade is the area of the facade behind which there is an unheated room, parapet, column or wall of the building.

The "warm-cold" building facade is a combined hinged enclosing structure that serves as protection for warm and cold sections of the building.

During the construction of modern buildings and structures it is difficult to achieve original solutions and attractive aesthetic forms without the use of architectural facade profile systems. Using reliable and easy to install profile systems, you can create modern stylish facades, windows and doors, translucent roofs, balconies, etc. Many small and large domestic and foreign companies are engaged in the release of system profiles. Among the Russian manufacturers of aluminum profile structures, Alutech, Tatprof, Sial, Initial, Unistem, and a number of no less well-known manufacturers have proven themselves well. Among the import firms such as Reynaers, Hueck, Wicona, Shueco and others are leading. If we visually compare facade systems with each other, the special differences between Russian and foreign facade structures are almost invisible. In addition, many structural elements of imported system profiles have long been produced in our country. The main differences may be in the design capabilities of a particular system.

It is known that heat losses in residential buildings occur not only due to walls, but it is external translucent enclosing structures that are traditionally considered to be their main cause. Even for low-rise buildings, this value reaches 35% of the total losses. In multi-storey buildings, it can reach up to 60-80%.

The use of sealed windows and the desire to reduce energy consumption by reducing ventilation losses significantly increase indoor air humidity. Another reason is errors in projects that contribute to the emergence of cold bridges, which, with increased humidity and temperature of the inner surface of the outer wall, cause condensation to form. The probability of condensation in the corner rooms is quite high, which is associated with the aerodynamic effect, which contributes to more efficient heat transfer and a decrease in the heat-insulating properties of the material.

In Western Europe, work on energy conservation in housing is one of the main directions of increasing the efficiency of the economy and is elevated to the rank of state policy. As a result of the work done over the past 30 years to warm buildings in Western Europe, the cost of heating them has decreased by 40-50%.

Among the existing options for increasing the thermal resistance of the external building envelope, the most effective and, accordingly, promising can be considered systems with external wall insulation and subsequent protection of the insulation either with layers of plaster (the so-called “wet” method), or constructive hanging elements forming a protective and decorative screen, separated from the insulation by an air gap (ventilated facades).

“Wet facade” is a multilayer construction, each element of which is necessary for solving certain problems. As a rule, the technology of "wet facade" implies the presence of three layers. The base layer is a reinforced adhesive, which is necessary to level the surface of the walls and more reliable adhesion between other layers. The next heat-insulating layer is made of specialized panels of mineral wool, and finally, the third layer of the “wet facade” consists of plaster, which is designed to protect the heat-insulating material and give an attractive appearance to the building.

A hinged ventilated facade (NVF) is a system consisting of a facing material that is mounted on a frame (stainless, galvanized or aluminum) to a load-bearing layer of a wall or a monolithic ceiling. Between the cladding and the wall there is a gap through which air circulates. This design eliminates the formation of condensation and moisture. Ventilated facades of buildings insulate buildings. To do this, a mineral wool insulation is attached to the wall, which does not pass and does not absorb moisture. In this case, the gap between the insulation and the building facade should not be less than 40 mm. In Russia, gaps do more than in other countries. This allows ascending air flows to circulate between the facing material and the insulation, drying the insulation layer in case of moisture. In order to prevent air blowing out of the insulation, it is protected by a moisture-proof, vapor-permeable membrane. The membrane in the curtain wall system performs several tasks at once. Firstly, it prevents the blowing of mineral wool fibers (and, most importantly, heat) from the insulation layer by the air flows moving in the ventilation gap. Secondly, it protects the insulation layer from getting wet, which can cause condensation to form on the inner surface of the cladding.

To ensure fire safety, the system of hinged facades includes non-combustible (NG) or non-combustible materials and products. They use a steel, preferably galvanized, fastener system and panels made of artificial stone, ceramics or asbestos-cement sheets, special aluminum panels of the NG category. Mineral wool is used as insulation, which withstands temperatures of 1200 ° C. This is especially important for high-rise buildings.

Along with the positive qualities of using ventilated facades, a number of drawbacks have been identified related to the choice of a hinged system that do not always meet the Russian climate. It must be remembered that the thickness of the insulation on Russian facades is much greater than in Europe, and therefore some foreign systems can not withstand our regulatory loads.

Each of the systems has a number of advantages and disadvantages, and only their objective analysis, taking into account the historical architectural appearance of the city, allows the designer to make a choice.

Facade systems are distinguished by the design of the bearing subsystems, the methods of fastening the insulation boards, the materials and fasteners used, the size and characteristics of the protective and decorative screens (claddings) and the ways of their fastening to the supporting subsystem.

Known design of fencing with thermal insulation, see patent RU No. 2229573, class. MKI E04F 13/08, 05/27/2004, Bull. No. 15), containing a metal frame formed by horizontally and vertically arranged profiles and mounted on brackets mounted on the wall of the building, while horizontally located Z-shaped profiles hold vapor-breathable insulation, and vertically located U-shaped profiles are attached to the Z- shelf with their bends. shaped profile. The presence on the outer side of the wall 1 of the insulation 2 provides savings of thermal energy inside the premises and the absence of air convection, creating comfort in the room at a lower air temperature (18-20 ° C).

The reliability and durability of enclosing structures are increased, since the dew point moves from the inside to the outside, where the temperature is lower and where the condensate that evaporates due to the ventilation system of the curtain wall. Moreover, condensate does not form and does not evaporate inside the wall, where the temperature is higher.

The disadvantages of the known device are time-consuming installation, due to the need for multi-point fastening of each plate, the inability to adjust the installation of the frame, the output of the fastening means of the panels on the outer surface of the plate, which affects the appearance of the cladding.

Known block translucent filling the opening of the building (window or door block), which contains a fixed frame (otherwise - a box, box) and a sash frame with one or more glazing elements made in the form of a single glass or glass, The frame and sash frame are made of profile PVC on the machines of the famous window technology. A double-glazed window consists of two or more sheets of glass, interconnected along a contour using distance frames and sealants. The double-glazed window is fixed in the sash frame by any known method, for example, using a removable glazing bead installed in the groove of the frame on its inner side facing the room. From the outside, a facing profile is fixed on the frame. On the edges of the profile, oriented essentially transversely to the plane of the double-glazed window, bends are made, intended for engagement with the upper influx and the profile leg of the outer part of the frame and snapping onto it. The manufacture of the facing profile and glazing bead is carried out on known equipment by extrusion, mainly from aluminum or its alloys, but other materials can also be used.

As an elastic sealant and gaskets, well-known industrially produced elastic gaskets of a tubular or more complex cross section can be used (RF Patent No. 2530873, published on October 20, 2014).

A significant drawback of the profiles is the low reliability of the operation of structures formed from profiles under conditions of strong temperature drops, especially frequent in Siberian conditions, as well as wind loads.

During operation under the action of loads, the structure can be deformed, namely, the halves of the vertical profile of the rack can move relative to each other under the action of the vertical weight load.

A system of external thermal insulation of buildings is known, which is a hinged facade system with an air gap or a facade system with a plaster layer, in which thermal insulation material is installed and fixed on the outer side of the walls of the building so that it protrudes beyond the edge of at least one window opening of at least than the thickness of the additional material, and containing additional thermal insulation material that is installed and secured to the slope of the at least one window p a swarm so that it covers all the mentioned slope; wherein said additional thermal insulation material has a thermal conductivity coefficient (λ) of not more than 0.035 W / (m⋅ ° C). In the design of external fencing, the insulation panels are made of asbestos cement sheets with foam glass enclosed between them. The connection between the sheets and blocks of foam glass is made by gluing with special compounds, the component of which was liquid glass (patent No. 1155578 (Z. No. 2012103056/03) publ. 04/27/2012).

This design is very time-consuming: its manufacture is artisanal and practically did not lend itself to mechanization.

The main disadvantage of the known technical solution is that the installation of thermal insulation material is carried out to the window opening. Since window openings are made with quarters, with this installation of heat-insulating material “cold bridges” appear, through which heat is removed from the building to be insulated, that is, the efficiency of insulation is reduced.

As a rule, a combination of the presented solutions is used in construction, namely a ventilated facade for wall insulation and a window unit installed in the opening. A common drawback of the curtain wall can be attributed to the high complexity and low quality of the docking units of an illegal armed formation located in the “cold” zone with a translucent structure or window located in the “warm” zone of the building, as a result of which blowing, freezing of the docking station and penetration of external moisture into the room are possible.

Facade USC 65 (Unitised System Construction) предназначенная для организации ограждающих навесных стен. Как правило применяется для высотных зданий с металлическим иил железобетонным каркасом без наружных стен. Конструкция представляет собой готовые модули состоящие из металлических (алюминиевых) каркасов В качестве светопрозрачного заполнения могут использоваться различные стеклопакеты. Конструкция модуля крепится на перекрытии при помощи опорных узлов. Система обладает высокой надежностью к восприятию ветровых нагрузок, достаточно герметична. Исключает влияние человеческого фактора, так как имеет полную заводскую готовность и не требует сборки на строительной площадке.Known system of modular (elemental) facade

Facade USC 65 (Unitised System Construction) designed for the organization of enclosing curtain walls. As a rule, it is used for high-rise buildings with a metal or reinforced concrete frame without external walls. The design is a ready-made modules consisting of metal (aluminum) frames. Various double-glazed windows can be used as translucent filling. The module design is mounted on the ceiling using the support nodes. The system has high reliability to the perception of wind loads, quite tight. Eliminates the influence of the human factor, as it has full factory readiness and does not require assembly at the construction site.

The disadvantages of the system include the possibility of freezing during the execution of the system in buildings with external walls or columns, when moving from the “cold” zone to the “warm” one both vertically and horizontally, because the location of the supporting part of the frame is located on the inside (from the premises) of the module.

The closest technical solution to the proposed utility model is the heat - cold facade KP50K TX of Sial (Catalog of aluminum structures and profiles of the SIAL system, Krasnoyarsk, 2009).

The system is designed for glazing buildings, where it is necessary to separate the cold zone with a single glass (in the area of blind walls) from the warm zone (in the area of window openings).

A feature of the system is the absence of an external difference between the “warm” and “cold” sections of the building. From the outside of the facade, the frame and sash of the window block are not visible, only decorative covers are visible.

Hidden leaf profiles are combined and consist of two parts (external and internal) interconnected by polyamide thermal inserts.

As the supporting elements, various profiles of the Sial system are used. The design of window units intended for the “warm” zone is assembled in the workshop and delivered assembled, the “Cold” part is delivered in the form of separate racks and crossbars and assembled directly at the facility.

Glazing, as well as the installation of window blocks is carried out outside the building. The filling is fixed with clamping strips, which are fastened with stainless steel self-tapping screws to the bearing profiles. Vertical decorative profiles (lid holders) pass without breaking from one “cold” area, through, through a “warm” area to the next “cold” area. For drainage of condensate, special drainage holes are provided in the frames and sash windows. Ventilation of the “cold” zone of the facade occurs due to the air gap between the insulation and glass, which avoids the accumulation of condensate on the inside of the glass. Solid walls (“cold” zone) can be lined with tempered glass or various panels, and when filling the “warm” zone, double-glazed windows are used. The filling is installed on the internal rubber seals and fixed with aluminum holders with external seals installed in them. Glass. Double-glazed windows or panels, when installed in the facade structure, are supported by linings. Lining material - polyamide, polyethylene, PVC or polypropylene. The choice of thermal inserts and glazing beads is carried out depending on the thickness of the filling.

The support nodes (brackets) are attached to the wall by means of anchors, and to reduce the heat loss under the brackets, gaskets are installed. Installation of plates with insulation.

The disadvantages of the system include the limited use of it, because It means the use of only sheet, mainly glass, materials in the "cold" zone, while modern architecture requires a variety of finishing materials. The disadvantages include the high complexity and dependence on the human factor and weather conditions due to the fact that the system is completely assembled at the construction site, and in this regard, poor tightness. In addition, there remains the possibility of freezing on racks and imposts during the transition from the cold to the warm zone, and also due to the fact that the bearing part is located on the inside of the structure.

The technical task of the present invention is:

- reducing the complexity and time of installation of the front curtain rails and costs during its operation due to the production of “cold” and “warm” modules in the factory,

- while increasing the thermal characteristics

- Reliability to the perception of atmospheric effects (wind loads, protection against blowing and leaks).

The technical result is achieved due to the fact that in the known hinged heat-cold building envelope made of separate blocks (modules) located in the “warm” and “cold” areas of the building facade, each module containing a metal frame of the frame made of vertically oriented profile racks and horizontally oriented profile imposts, the modules being joined together by means of gaskets, the modules themselves are mounted on the building with the help of supports, one part of which is rigidly connected to the building one and the other with the appropriate module, filling the frame of the modules can be performed in whole or in part with double-glazed windows or sheet panels, changes have been made, namely:

- racks and imposts of the frame (frame) of the module located in the “warm” zone of the building facade are made combined and consist of two parts (external and internal) connected by thermal inserts (thermal bridges);

- moreover, their bearing part is located on the outside of the building and is connected to the module located in the "cold" zone, by means of an elastic sealant;

- racks and imposts of the frame (frame) of the module located in the cold zone are made without thermal insulation (without thermal inserts, without thermal bridges).

- “warm” and “cold” modules are fully manufactured in the factory, with the possibility of delivery to the object in assembled form.

In addition, the modules located in the “warm” zone can be equipped with ventilation elements, for example, valves or flaps of various types of opening, and the frame frame of some modules located in any zone can be configured to install two or more filling in it sheet materials, which can be made partially or completely translucent. Moreover, in the case of partial implementation of the “warm” module translucent, the finish of the opaque zone can be performed by any decorative materials approved for use on the facades.

Cladding of cold modules can be performed both with sheet material and with any decorative materials approved for use on facades.

The analysis of the prior art by the applicant did not reveal sources of information that disclosed a technical solution characterized by a combination of features of the claimed solution, therefore, we can conclude that the latter meets the requirements of “novelty” and “industrial applicability”, because its manufacture does not cause difficulties and is carried out in the factory.

For a better understanding of the essence of the proposed technical solution, used as a hinged heat-cold building envelope, the following figures are given (Fig. 1 -).

In FIG. 1 shows a fragment of the facade of the building; in FIG. 2 shows a horizontal section 1-1 of the facade; in FIG. 3 - section 2-2 vertically of the "warm" zone; in FIG. 4 - section 3-3 vertically of the "cold" zone; in FIG. 5, 6, 7 show a more visual implementation of nodes 1, 2, 3, respectively.

A fragment of the building (Fig. 1) includes “warm” and “cold” zones 19 and 20 and shows different filling of the modules (with and without sash, translucent and sheet panels or decorative cladding).

In FIG. 2 (section 1-1) shows the wall 1 of the building, thermal insulation 2 of the walls of the building, the building envelope 3 of the facade of the building (surrounded by dashed lines), including “warm” and “cold” modules and other elements that will be disclosed below, the floors of building 4 ( shown conditionally), frame 5 of the “cold” module, outer bowl 6 of the “warm” module, inner bowl 7 of the “warm” module, glazing bead 8 securing the module’s filling, thermal gap 9, joint seal of the modules 10, filling 11 of the “warm” module (double-glazed window or sheet panel, sash, etc.), decorative cladding 12 (with ematichno).

In FIG. 3 (section 2-2) shows the “warm” modules placed along the height (floors) of the building, which can have different designs. In FIG. 3 except for the previously mentioned positions: 6, 7, 8, 9, 10, 11 show floor 4, insulation 13, support assembly 15 (bracket) mounted on floor 4, outer 16 and inner 17 of the impost of the “warm” module, respectively.

In FIG. 4 (section 3-3), except for the previously indicated positions: 1, 2, 4, 5, 10, 12; imposts 14 of the “cold” module are shown.

In FIG. 5 (node 1) shows the vertical docking of the “warm” modules 19, each of which contains a frame, the side stand of which is made combined, i.e. consists of two parts 6 and 7 between which there is a thermal insert 9, the filling of module 11 (double-glazed window) is fixed with a glazing bead 8. Seals 10 are placed between adjacent modules.

On Fig .. 6 (node 2) shows the vertical docking of the “cold” modules 20, which contain a frame 5, between which the sealant 10 is placed. The filling of the “cold” block can be made of sheet panels 12 (or decorative materials).

In FIG. 7 (node 3) shows the horizontal docking of the “warm” 19 and the “cold” module 20. The frames of the “cold” modules 5 and the outer part 6 of the frame of the “warm” module are respectively connected to each other by the seal 10. FIG. 7 also shows the inner part of the side rack of the frame 7, connected to the outer part of the rack frame 6 by a thermal gap 9, as well as the filling 11 of the “warm” module (glass packet) and glazing bead 8. The figure shows the decorative lining 12 of the “cold” module 20.

The manufacture of a hinged building envelope does not cause difficulties, because it consists of modules of the mounted heat - cold fence of the building, which are manufactured in the factory on specialized machines. The profiles of all elements of the module (side racks, imposts, glazing beads, etc.) are extruded, which ensures the quality of individual parts. After the manufacture of the individual structural elements, the module is assembled and installed in the frame of its sheet filling. A set of modules is made in accordance with the wishes of the client and can be structurally different both in the number of filling sheets, and in the combination of the arrangement of transparent and opaque elements in the sheets, their material, etc.

Installation of fencing modules is carried out by hanging them on the support brackets using a cargo crane or winch, depending on the weight of the module.

The thermal insulation is fixed to the wall of the building by a known method, using dowels.

For the decorative cladding of the opaque part of the “warm” module and the “cold” module, various plate, bulk and sheet materials are used, including plates made of natural stone (granite, marble, limestone), ceramic and cement-based plates coated with stone chips or painted laminated boards made of non-combustible or slow-burning polymeric materials and metal sheets (steel and aluminum) with and without coating. A significant variety of types of finishing materials, combined with a large selection of colors and surface textures, can significantly enrich the architectural and artistic expressiveness of buildings under construction and reconstructed.

The main advantages of the proposed technical solution over the well-known are: reducing the complexity and installation time of the front mounted fence and the costs of its operation, while improving the thermal characteristics by eliminating the bridges of the “cold” through the use of thermal breaks and ensuring reliable joints of the “warm” and “cold” modules .

In addition, increases the reliability of the perception of atmospheric effects (wind loads, protection against blowing and leaks).

At present, on the basis of pilot tests of the claimed building envelope, work has been completed on the creation of technical documentation for the mass production of various versions of the hinged warm-cold building envelope of the building facade.

Claims (5)

1. The hinged heat-cold building envelope is made of separate blocks (modules) located in the “warm” and “cold” areas of the building facade, each module containing a metal frame frame made of vertically oriented profile racks and horizontally oriented profile imposts, moreover, the modules are joined to each other by means of seals, the modules themselves are mounted on the building using supports, one part rigidly connected to the building, and the other with the corresponding module, filling the module frame can be made completely or partially translucent, characterized in that the posts and imposts of the module located in the "warm" area of the building facade are made combined and consist of two parts (external and internal) connected by thermal inserts (thermal bridges), and their bearing part is located from the outside of the building and connected to the module, located in the "cold" zone, by means of an elastic sealant. 2. The hinged heat-cold building envelope according to p. 1, characterized in that the racks and imposts of the frame (frame) of the module located in the cold zone are made without thermal insulation (without thermal inserts, without thermal bridges). 3. A hinged heat-cold building envelope according to claim 1, characterized in that the modules located in the “warm” zone can be equipped with ventilation elements, for example, valves or flaps of various types of opening. 4. A hinged heat-cold building envelope according to claim 1, characterized in that the frame of the frame of some modules located in any zone can be configured to install in it a filling of two or more sheet materials, which can be made partially or completely translucent.

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