RU86634U1 - BUILDING FRAME MODULE - Google Patents

Abstract

1. The frame module of the building, containing the base, the frame with external and internal cladding and insulation located between them, a ceiling, floor and roof, and utilities, characterized in that the module frame is load-bearing and made of a metal profile forming a rigid spatially closed system, while the profile is a fixing element for the frame structure of a wooden beam, on which the internal and external cladding of the ceiling, walls and floor are fixed, while all the elements of the metal frame are laid out of the cold zone and covered with insulation. ! 2. The frame module of the building according to claim 1, characterized in that the metal frame around the perimeter of the upper part is equipped with sling elements. ! 3. The frame module of the building according to claim 1, characterized in that a steel channel is used as the metal profile. ! 4. The frame module of the building according to claim 1, characterized in that the ends of the bars are equipped with technological protrusions and grooves to ensure a tight connection of the bars in the frame. ! 5. The frame module of the building according to claim 1, characterized in that the frame structure is made of pine timber with a cross section of 150 × 50 mm. ! 6. The building frame module according to claim 1, characterized in that ecowool cellulose insulation is used as insulation. ! 7. The frame module of the building according to claim 1, characterized in that the external walls are made of oriented particle board OSB. ! 8. The frame module of the building according to claim 1, characterized in that the internal walls are made of plywood. ! 9. The frame module of the building according to claim 1, characterized in that to ensure the required fire resistance of the supporting structures, plasterboard or

Description

The utility model relates to modular volume-frame construction and can be used in low-rise housing construction for the construction of residential buildings, public buildings and structures.

Known volumetric-frame technology for the construction of buildings (called North American technology), in which the basis of the walls is a supporting wooden frame, sheathed on the outside and inside with various materials, with the filling of the inner space of the wall with insulation.

The wooden frame of dried pine timber is sheathed on the outside with DSP (cement-bonded particleboard), hydro- and wind-proof membrane film (Juta, Stroyizol). The film protects the structures from wind pressure and water, and at the same time passes moisture vapor from the inside, which allows the insulation and wood to be constantly in a dry state. On the inside of the frame a heater is laid, for example, "ISOVER". The frame is closed with a vapor barrier film, which, in turn, protects the insulation and the wooden frame from moisture penetration from the inside of the room. On the inner side of the frame is fixed gypsum plasterboard (GKL Knauf), which acts as a preparatory layer for the finishing. The well-known production of frame houses provides high-quality internal preparation of premises for finishing even at the stage of manufacturing the frame (see http://www.domanarodu.ru/technology/) [1]. In the factory, parts of the building are made, then they are transported to the construction site, and from them, as from cubes, as soon as possible on a pre-erected foundation, a one- or two-story house is mounted.

However, houses built using well-known technology do not have sufficient frame rigidity, which makes it difficult for loading and unloading and transporting the wooden frame to the construction site, as well as insufficient seismic stability.

Known modular building (options) according to the patent for utility model 65924 [2], including a means of delivery of the modular building to the construction site. A well-known modular building contains a frame made of wood or metal, external and internal walls and a heater located between them.

When assembling the module in the factory, the walls of the module are attached to the base in assembled form, which creates gaps between the insulation layers and structural weaknesses in the interface lines between the base walls and the ceiling.

A known column for light construction, consisting of several nozzles to which profiles are attached, the shelves of which form grooves for attaching longitudinal bars and partitions (see FR patent No. 2667636, IPC ⁸ Е04С 3/30, publ. 04/10/92) [ 3].

The disadvantages of this design are the complexity of manufacturing and the rigidity of the fastening of the elements together. In addition, metal parts form “cold bridges”.

Known structural system for the construction of low-rise buildings (patent No. 62128 for utility model [4], consisting of formed on the basis of frame frames: external load-bearing walls, internal load-bearing walls, etc. All elements of the structural system are made of thin-walled steel profiles, which are connected detachable connection for the purpose of forming enlarged structural elements and creating a building frame .. For elements of external building envelopes - external walls and attic floors, a profile is provided it has a perforated wall to prevent the formation of “cold bridges.” The heat and sound insulating material in the external walling is located within the cross-sectional height of the frame elements and is protected by special films and sheathing on both sides. resistance of steel structural elements is ensured by anti-corrosion coating.

The specified structural system also does not have sufficient rigidity of the frame, which makes it difficult for loading and unloading and transportation of the module to the construction site, as well as insufficient seismic stability. Known structural system for the construction of low-rise buildings is the closest analogue of the claimed utility model.

The technical result of the utility model is to provide higher structural strength of the frame and increased seismic stability while maintaining high assembly speed, increase transportability, as well as improve its operational characteristics, including the provision of effective thermal insulation (absence of "cold bridges"), fire safety, and corrosion resistance.

The claimed technical result is achieved in that in a frame module of a building containing a frame with external and internal cladding and a heater located between them, a ceiling, floor and roof, and utilities, according to a utility model, the frame of the module is load-bearing and made of a metal profile forming a rigid a spatially closed system, the profile being a fixing element for the frame structure of a wooden beam, on which the internal and external cladding of the ceiling, walls and floor are fixed, with that all metallic elements disposed outside the carcass and closed cold zone heater.

At the same time, in the metal frame along the perimeter of the upper part, sling elements are provided.

In this case, a steel channel is used as a metal profile.

At the same time, the ends of the bars are equipped with technological protrusions and grooves to ensure a tight connection of the bars into the frame.

In this case, the frame structure is made of pine timber with a section of 150 × 50 mm.

At the same time, cellulose insulation of ecowool is used as insulation.

In this case, the external walls are made of oriented particle board OSB.

In this case, the internal walls are made of plywood.

At the same time, to ensure the fire resistance of the supporting structures, they use plasterboard or gypsum-fiber sheathing.

At the same time, the bottom of the module is coated with moisture-resistant plywood 15-18 mm.

In this case, the metal frame of the module has an anti-corrosion coating.

The inventive frame module of the building is illustrated by the following graphic materials.

Figure 1 is a General diagram of a frame module.

Figure 2 - view of the frame structure of a wooden beam.

Figure 3 - view of the connecting node of the modular frame (in cross section).

Fig 4 is a top view of the frame module.

The frame module of the building (Figs. 1, 3) contains a frame 1 with external 3 and internal 4 skins and a heater 5 located between them, as well as a ceiling, floor, roof and utilities (not indicated). The frame 1 of the inventive module is a supporting one, it combines a metal frame 9 and a frame structure 10 of a wooden beam. The metal frame 9 is made of profile 11, which can be used as a standard steel channel, for example No. 12 according to GOST8240-89. The welded metal frame forms a rigid spatially closed unchanged structure, providing increased seismic stability of the building, which is important for construction in areas of seismic activity. In addition, the module is more portable, as it is possible to move the entire module as a rigid whole, while destructive forces and stresses in its elements do not occur. The metal frame 9 along the perimeter of the upper part is equipped with sling elements 16 with threaded holes 17 into which the eyebolts 18 are installed when the module is transported to the assembly shop or to the construction site. Elements 16 can be made in the form of metal scarves welded in the corners of the upper part of the frame.

The frame structure 10 (Fig.2, 4), made of wooden timber, is the basis for fixing the inner and outer skin of the frame for the ceiling, walls and floor of the module. As such a beam, a pine beam with a section of 150 × 50 mm can be used. The bars are equipped with technological protrusions and grooves, which provide the possibility of a tight connection of the bars in the frame. The resulting frame around the perimeter has no gaps, which allows you to get a single enclosed space for laying insulation.

The channel 11 of the metal frame is rigidly connected to the lower 12 and upper 13 belt frames, in turn, rigidly connected to the vertical struts 14 of the frame (Fig.2, 4).

Outside and inside, the frame is lined with sheet material, forming the inner space 16, in which the engineering communications are located. The inner 4 and outer 3 cladding are used to seal the inner space of the wall. The inner space 16 is filled with insulation 5. As an effective insulation, cellulose insulation - ecowool is used. Ecowool is an environmentally friendly cellulosic material with high heat and sound insulating ability, high biostability (Internet resource. Wikipedia). The fine-fiber structure of ecowool determines its excellent penetration. The material fills inaccessible gaps and recesses, forming a continuous and seamless heat-insulating circuit, without requiring disassembly of existing structures, even in cases of insulation of existing structures. Cellulose insulation is placed in the cavity between the outer and inner parts of the frame in a wet manner using glue. At the same time, the insulation layer in the floor, walls and floors does not have gaps, but is a monolithic mass with a thickness of at least 10 cm. As a result, the inner space 16 is completely monolithic with insulation 5. This design provides almost 100% heat saving.

All elements of the metal frame are located outside the cold zone, as the outside is covered with a bar and insulated with a layer of insulation with a thickness of 10 cm or more, depending on the region of operation, which completely excludes “cold bridges”.

The outer casing 3 of the frame is made of oriented particle board OSB (or OSB). The advantages of using OSB slabs are: increased strength: earthquakes in California and Japan showed that the wall structures of frame-type houses, in which OSB slabs were used as cladding, survived them, unlike houses whose walls were built of brick and concrete; the ability to hold screws and nails in OSB is close to natural wood (the physical and mechanical properties of OSB are 2.5 times higher than that of chipboard); shape stability; weather resistance: the unique moisture-resistant properties of OSB boards allow the board to act as a waterproof barrier, preventing the penetration of moisture; durability; good sound insulation; high aesthetics in the decoration of rooms due to the pronounced structure of natural wood (Internet resource.www.belhouse.net).

The inner lining 4 of the frame is made of plywood. Covering the bottom of the module is made of moisture-resistant plywood 15-18 mm. Additionally, the bottom is coated with antifungal paint.

According to the utility model, modular buildings are constructed in the form of sections, or modules. 95% of the building is being prepared at the factory, and the remaining 5% is being prepared at the construction site.

The assembly process in the workshop is as follows. Assemble the bottom floor panel and in the finished form are laid in place. A prepared metal frame 9 is installed on top. In the grooves of the protruding parts of the bars 14, blanks of the frame 10 are installed, covering the metal frame. Parts of the frame and the metal frame are fastened with a bolted connection, which also contributes to the strengthening of the structure, excluding deformation. Wooden frames set in increments of 50 cm (figure 4).

The upper 15 strapping beam of the frame, which gives rigidity to the frame, and which can serve as the basis for the interfloor overlap, is laid on top of the frame thus mounted so that it is mounted on top (figure 4).

The module manufactured at the plant is transported to the construction site. In this case, the crane hooks it onto the eyebolts 18 in the sling elements 16, and loads it onto the platform for transportation. After installation at the construction site, the eye bolts are unscrewed, and the holes are closed with foam. If it is necessary to move the building, the holes are cleaned, eyebolts are installed, the module is hooked by a crane and transferred to another place.

The inventive frame module due to the assembly in production conditions, has a low cost, transportability, high performance, including effective thermal insulation, the complete exclusion of "cold bridges", increased seismic stability.

By carrying out the frame of the inventive module with a carrier, with a combination of a metal frame and a frame structure of a wooden beam with a bolted connection, a high structural strength and increased seismic stability are achieved. The increase in transportability is achieved due to the structural strength of the frame and the presence of sling elements with holes for eye bolts.

Improving operational characteristics, including ensuring effective thermal insulation (the absence of "cold bridges") is achieved due to the dense wooden frame structure that completely covers the metal frame; the use of effective cellulose insulation-ecowool. Corrosion resistance is achieved due to anti-corrosion coating of metal parts of the frame. The fire resistance of the supporting structures is ensured through the use of cladding from OSB boards, plasterboard or gypsum fiber sheets.

INFORMATION SOURCES.

1. Description of the technology of frame-wooden housing construction. Internet resource. http://www.domanarodu.ru/technology/.

2. Patent for utility model No. 65924. Modular building (options) and means of delivery of the modular building to the construction site.

3. Patent FR No. 2667636, IPC ⁸ Е04С 3/30, publ. 04/10/92).

4. Patent for utility model No. 62128. Constructive system for the construction of low-rise buildings (the closest analogue).

Claims (11)

1. The frame module of the building, containing the base, the frame with external and internal cladding and insulation located between them, a ceiling, floor and roof, and utilities, characterized in that the module frame is load-bearing and made of a metal profile forming a rigid spatially closed system, while the profile is a fixing element for the frame structure of a wooden beam, on which the internal and external cladding of the ceiling, walls and floor are fixed, while all the elements of the metal frame are laid out of the cold zone and covered with insulation. 2. The frame module of the building according to claim 1, characterized in that the metal frame around the perimeter of the upper part is equipped with sling elements. 3. The frame module of the building according to claim 1, characterized in that a steel channel is used as the metal profile. 4. The frame module of the building according to claim 1, characterized in that the ends of the bars are equipped with technological protrusions and grooves to ensure a tight connection of the bars in the frame. 5. The frame module of the building according to claim 1, characterized in that the frame structure is made of pine timber with a cross section of 150 × 50 mm. 6. The building frame module according to claim 1, characterized in that ecowool cellulose insulation is used as insulation. 7. The frame module of the building according to claim 1, characterized in that the external walls are made of oriented particle board OSB. 8. The frame module of the building according to claim 1, characterized in that the internal walls are made of plywood. 9. The frame module of the building according to claim 1, characterized in that in order to ensure the required fire resistance of the supporting structures, plating made of plasterboard or gypsum-fiber sheets is used. 10. The frame module of the building according to claim 1, characterized in that the coating of the bottom of the module is made of moisture-proof plywood 15-18 mm. 11. The frame module of the building according to claim 1, characterized in that the metal frame has a corrosion-resistant coating.