RU2112116C1 - Wall panel - Google Patents

Abstract

FIELD: building constructions, in particular, wall panel with load-bearing timber frame, mainly applicable in low-rise wooden house-building. SUBSTANCE: wall panel has heat insulation 5, timber frame of vertical posts 1 installed with pace 3 along the panel, and with pace 2 across the panel, and cross-bars 4 staggered in the gap between the adjacent posts of two adjacent transverse rows for attachment in their lateral vertical planes. Soft mats, for instance of inorganic fibres, installed between the lateral vertical planes of the cross-bars and posts are used as heat insulation. The total thickness of two mats exceeds the gap between the posts, but it is less than its doubled value. EFFECT: reduced labour content, saving of structural and heat-insulating materials, enhanced resistance to heat transfer. 2 cl, 3 dwg

Description

 The invention relates to the field of building structures, namely, to wall panels with a wooden frame, and will find primary application in low-rise wooden housing construction.

 Known panels with a wooden frame, cladding and thermal insulation [1].

 The frame is made of rack-boards of standard sections, for example 5 x 10 cm, located along the panel with a particular step, the dimensions in height and thickness of the panel.

 The design flaws are its bulkiness and high consumption of structural wood.

 Closest to the claimed and selected as a prototype is the device of wooden sheathing walls and partitions [2].

 The device comprises a wooden frame of rigidly interconnected vertical racks arranged in increments along the panel, and crossbars installed between them in a checkerboard pattern. There is a vertical partition made of plywood, etc. sheet material, playing the role of thermal insulation. Perhaps the use for partitioning sheet fire-resistant material.

 The assembly of crossbars located in a checkerboard pattern with their end and side surfaces with uprights is carried out in two mutually perpendicular planes, which complicates and complicates the assembly.

 Thermal insulation made of plywood or the like. sheet material (partition) or of sheet fireproof material is installed between the rows of racks and crossbars. The insulation is fixed in small areas at the contact points of the crossbars installed in a checkerboard pattern and fixed with their midpoints to the posts. This design does not provide a dense uniform fit of the insulation across its entire plane and ends, which does not exclude possible air circulation, and therefore leads to a decrease in heat transfer resistance.

 The objective of the proposed technical solution is to create a simple design of the wall panel with a wooden supporting frame, made with the least labor costs, saving structural wood and thermal insulation, with increased resistance to heat transfer.

 To solve this problem, in a wall panel containing a wooden frame of vertical racks installed in increments along the panel and staggered between them in a staggered manner, and thermal insulation, according to the invention, the racks are arranged in a row with a gap between them across the panel, and the crossbars are placed in the gap between adjacent racks of two adjacent transverse rows with the possibility of fixing along their lateral vertical planes. Soft mats, for example, made of inorganic fibers, installed between the lateral vertical planes of the crossbars and racks, are used as thermal insulation, while the total thickness of the two mats is greater than the gap between the racks, but less than twice its size.

 The installation of crossbars in the gap between adjacent racks of two adjacent transverse rows and fixing them with lateral vertical planes to the racks makes it possible to assemble panel elements in one plane, which automates the assembly process and reduces its complexity.

 The use as thermal insulation of soft mats made of inorganic fibers installed at the points of contact between the crossbars and racks allows compression of the thermal insulation along its lateral vertical planes.

 And the use of mats with a total thickness of more than the size of the gap between the uprights, but less than twice its size, ensures the creation of the necessary closed air layers and eliminates air circulation between them, which increases the resistance to heat transfer.

 The search showed the absence of similar technical solutions, which allows us to conclude that the device (panel) does not explicitly follow from the studied prior art, i.e. meets the criteria of "novelty" and "inventive step". This panel can be manufactured industrially, i.e. meets the criterion of "industrial applicability".

 In FIG. 1 shows a wall panel, a longitudinal section; in FIG. 2 is a front view of a panel; in FIG. 2 is a section AA in FIG. 2.

 The proposed wall panel includes vertical racks 1 installed with a gap 2 relative to each other across the panel and with a step 3 along the panel. The crossbars 4 are installed in the gaps 2 between adjacent racks 1 of two adjacent transverse rows and are fixed by vertical lateral planes to the racks 1. The crossbars 4 are installed in a checkerboard pattern with uniform reinforcement of the racks 1. The panel is provided with thermal insulation 5. As a thermal insulation, known heat-insulating materials can be used - loose, sheet, fluid. The preferred option is soft mats, such as inorganic fibers. The mats are compressed along the vertical planes between the uprights 1 and the crossbars 4, partially deformed in the gap 2 and form closed air spaces 6 in the spaces between the rows of the uprights 1 and the crossbars 4.

 The outer skin 7 can be composed of sheets joined on racks 1 by known methods.

 Example.

 Vertical posts 1 and crossbars 4 are made of 40 x 40 rails. The length of the panel stands are installed in increments of 3 ≈ 1 m. The number of posts 1 in the transverse row is 3. The posts 1 form 2 gaps in which the crossbars 4 are staggered and fixed on vertical planes by methods known in the art, for example nailing.

 Between the posts 1 and the crossbars 4 there are soft mats made of inorganic fibers, for example, fiberglass with a thickness of ≈ 30 mm, which form closed air layers together with the skin of the panel 7. In the gaps between the uprights, the mats are deformed by 20 mm (33%), which ensures the sealing of the panel along the end surfaces and creates closed air spaces inside the panel.

This panel with a thickness of 200 mm has a mass of ≈ 12 kg / m ² , heat transfer resistance ≈ 5 m ² • ^o C / W.

 The paneling is made of wood.

 The use of racks installed with a gap relative to each other increases the moment of inertia of the cross-section of the racks and, as a result, increases their bearing capacity.

 The use of relatively small building elements of the same type, for example, slats, creates a lightweight structure (discharged frame) with spatial stiffness, and saves structural wood, which saves by increasing the moment of inertia in this panel ≈ 50%.

 The thermal insulation in the proposed panel is evenly clamped across the entire plane. It excludes sagging and slipping. This ensures the durability of the element, and therefore saves thermal insulation, since part of the thermal resistance is provided by air gaps, the savings in the cost of thermal insulation is 30-60%.

 The increased thermal properties of such a panel allows the construction of energy-economic buildings with reduced heating costs - schools, kindergartens, and most of all - permanent residential buildings.

Claims (2)

 1. A wall panel comprising a wooden frame of vertical racks installed in increments along the panel and staggered between them in a checkerboard pattern and thermal insulation, characterized in that the racks are arranged in a row with a gap between them across the panel, and the crossbars are placed in the gap between adjacent racks two adjacent transverse rows with the possibility of fixing along their lateral vertical planes.  2. The panel according to claim 1, characterized in that soft mats are used as thermal insulation, for example, of inorganic fibers installed between the lateral vertical planes of the crossbars and racks, while the total thickness of the two mats is greater than the gap between the racks, but less than twice quantities.

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