RU139753U1 - CELL BAR - Google Patents

Abstract

1. A honeycomb bar consisting of parallel and equally spaced wooden slats interconnected by transversely arranged latches with a shift in the sequence of inserts to form air cavities, characterized in that it contains three walls, air cavities filled with a sealed ecowool, the latches are made in the type " dovetail ", and the ratio of the n distances between the lamellas and the thickness of the lamellas of the wooden beam is determined by the formula n = d1: d2, where d1 is the vapor permeability coefficient of ecowool, and d2 is the coefficient it is the vapor permeability factor of the selected wood species, each lamella has a “spike” in the upper part, a “groove” in the lower part, and cutouts for connecting along the length with the help of dowels from the end of the longitudinal wall. 2. A honeycomb beam according to claim 1, characterized in that the outer wooden lamella is brushed. The honeycomb bar according to claim 1, characterized in that in the transversely arranged latches in the center, holes are drilled during the construction of the wall for the passage of metal screeds. The honeycomb bar according to claim 1, characterized in that it comprises an end lamella for forming an angular joint.

Description

The utility model relates to the field of construction, in particular to wooden structures that can be used as prefabricated load-bearing elements in wooden housing for the formation of vertical walling.

Known timber thermos (patent for utility model of the Russian Federation No. 109171 dated 01/11/2011, IPC E04C-002/10) for the device of enclosing (wall) structures, made of two longitudinal boards located at a distance from each other, connected by racks, the planes of which perpendicular to the planes of the boards to be fastened, and a third longitudinal board covering the side of the beam, and a layer of polyurethane foam is applied to all the inner sides of the resulting box structure.

Known hollow beam (patent for the invention of the Russian Federation No. 109481 from 04/28/2011, IPC E04C 3/00), which is a rigid spatial, hollow, multi-layer and multi-faceted structure consisting of two walls connected by partitions, characterized in that the partitions having the same height size with walls, mounted so that they protrude above the upper edges of the walls to a height of not more than half the height of the walls.

Known wooden prefabricated element (RF patent No. 2461687 from 01/18/2011, IPC E04C 3/12, E04B 1/10) consisting of at least two longitudinal parts located parallel to each other at a predetermined distance, interconnected by embedded bonds, characterized in that mortgage ties are discretely installed along the length of the precast element in opposed grooves of rectangular cross section, with each groove cut in the middle of the longitudinal part and made continuous along its entire length, the height of the groove exceeds its depth and state It has 0.4-0.7 widths of the longitudinal part; the fibers of the longitudinal part are oriented along the longitudinal axis of the prefabricated element, and the fibers of the embedded bonds are perpendicular to the direction of the fibers of the vertical longitudinal parts.

The closest technical solution is a wooden packet element (RF patent No. 60570 dated 10.07.2006, IPC E04C 3/12), consisting of layers of solid wooden boards interconnected by inserts with the formation of air cavities, equipped with a supporting protrusion and a longitudinal mounting groove, characterized the fact that the inserts are made in the form of bars located parallel to the end surface of the packet element, and their length is equal to the height of the packet element, and the sequence of inserts between the previous and this layer of solid boards to is shifted in relation to the sequence of inserts between the data and the subsequent layer by half the distance between two adjacent inserts.

The disadvantages of all of the above technical solutions is that when choosing the thickness of the layers the vapor permeability of the beam and, accordingly, the problem of moisture accumulation are not taken into account, which negatively affects the thermal insulation properties of the wooden structure.

The objective of the utility model is to create a honeycomb beam with high vapor permeability, as well as improved thermal insulation properties and aesthetic appearance.

The technical result of the claimed utility model is to reduce thermal conductivity, obtain optimal vapor permeability of wooden building structures erected using honeycomb and increase heat conservation.

The technical result is achieved by the fact that the honeycomb bar, consisting of wooden lamellas parallel to each other at the same distance, interconnected by transversely arranged clamps with a shift of the sequence of inserts with the formation of air cavities, contains three walls, air cavities filled with a sealed ecowool, while the clamps are made by type "dovetail", and the ratio of n distances between the lamellas and the thickness of the lamellas of the wooden beam is determined by the formula: n = d1: d2, where d1 is the coefficient of vapor ekovaty permittivity, a d2 vapor permeability coefficient chosen wood, each sipe in the upper part has a "spike" in the lower part of the "notch" from the end of the longitudinal walls comprises recesses for the connection via the length of dowels.

The utility model is illustrated by drawings:

figure 1. - a fragment of a bar (top view);

figure 2 is a cross-sectional view of the lamella;

figure 3 - General view of the timber with cavities filled with ecowool;

figure 4 is a General view of the beam with cavities filled with ecowool with an end wall;

5 is a connection along the length of the hollow honeycomb bars.

A honeycomb bar consists of three lamellas parallel to each other at the same distance, two external 1 and middle 2, connected by transversely arranged wooden latches 3 using the dovetail connection 4 in an adhesiveless manner, the latches being staggered and each lamella in the upper part has The "spike" 5 and in the lower part of the "groove" 6 for the tongue-and-groove connection of the honeycomb bars in height and the slots 7 in the end parts for the keyway connection of the bars in length using the keys 8 and metika.

Clamps 3-wooden bars, a thickness greater than the thickness of the lamella, more than 1.5 times.

The latches 3 in the lower part have compensation slots to prevent the occurrence of cracks and deformation (not shown in the drawing).

The location of the latches 3 in a checkerboard pattern between the lamellas 1 and 2 excludes the cold bridges.

In the center of the clamps, holes are drilled during the construction of the wall for the passage of metal ties.

Between the parallel slats 1 and 2 and the clamps 3, air cavities are formed, which are filled with ecowool insulation 11

The thickness of the lamellas and the total thickness of the honeycomb bar are selected in such a way that when using ecowool as a filler, the vapor permeability of the honeycomb becomes equal to the vapor permeability of a solid tree.

The ratio of n distances between the lamellas and the thickness of the lamellas of a wooden beam is determined by the formula: n = d1: d2, where d1 is the ecowave vapor permeability coefficient, and d2 is the vapor permeability coefficient of the selected wood species.

For example, for pine across fibers:

d2 = 0.06 Mg / (m * h * Pa), d1 = 0.3 Mg / (m * h * Pa), and thus n = 5, i.e. when the thickness of the pine lamella is 30 mm, the thickness of the ecowool layer in the honeycomb cavity is 150 mm., i.e., the ratio of the distances between the lamellas and the thickness of the lamellas is n = 5: 1.

The triple-walled honeycomb bar has optimal vapor permeability. The thickness of the wood layer and the insulation layer are calculated based on their vapor permeability.

The thickness of the lamellas and the total thickness of the honeycomb bar are selected in such a way that when using ecowool as a filler, the vapor permeability of the honeycomb becomes equal to the vapor permeability of a solid tree.

For example, when using ecowool as a heater, the wall, which is a “layer cake” - “wood (3 cm) + insulation (15 cm) + wood (3 cm) + insulation (15 cm) + wood (3 cm)” - lets steam through, or “breathes” like a whole tree.

According to the vapor permeability properties, 3 cm of wood are equal to 15 cm of insulation.

Ecowool vapor permeability 0.3 mg / (m * h * Pa).

The vapor permeability of pine and spruce across the fibers is 0.06 Mg / (m * h * Pa).

The goal of achieving this ratio is to obtain a wall structure that is uniform in vapor permeability, which, in accordance with SNIP (II_3_79, clause 6.4), eliminates the use of additional vapor barrier and excessive moisture accumulation inside the structure in winter.

The density of ecowool filled in the air cavity is at least 65 kg / m ³ , which eliminates the settling of the insulation over time.

The length of the honey bar is from 0.5 m to 5.90 m.

To form a honeycomb beam in length, two beams are attached to each other in length. Moreover, in each of them, at the ends of the abutment, slots 7 are made (2 cm deep and 10 mm wide). The slot 7 is treated with silicone sealant and a dried wooden key 8 is inserted into it in the form of a parallelepiped 185 mm * 9 mm * 40 mm. The purpose of this seal is to prevent moisture and wind from entering the joint.

The external lamella is brushed, which allows you to emphasize the wood pattern and several times reduce the cost of painting the surface, since brushed wood does not require any additional processing before painting. This is due to the fact that when brushing soft wood fibers that are rotten are removed.

The honeycomb bar may have an end portion 9 when forming the corner connection of the building. At the same time, the decorative edge of the end face is made in production by gluing the end brushed lamellas and external brushed lamellas 1, cut from the inside at an angle of 45 degrees (pos. 10). This ensures both aesthetics and accuracy when assembling the corner joints of the building.

The use of ecowool containing cellulose, flame retardants and antiseptics in its composition allows to achieve high thermal insulation, as well as high fire resistance of the structure. Ecowool is a hygroscopic material that easily absorbs moisture from the external environment and easily gives it back, which ensures high vapor permeability of the honeycomb bar containing ecowool as a filler. The presence of antiseptic additives in the ecowool improves the biological properties of the product, namely resistance to rodents, fungi, insects.

The claimed technical solution meets the criterion of "novelty", as from the well-known and publicly available sources of information have not identified a similar technical solution.

The claimed technical solution meets the criterion of "industrial applicability", as it can be made from known materials and by known methods.

Claims (4)

1. A honeycomb bar consisting of parallel and equally spaced wooden slats interconnected by transversely arranged latches with a shift in the sequence of inserts to form air cavities, characterized in that it contains three walls, air cavities filled with a sealed ecowool, the latches are made in the type " dovetail ", and the ratio of the n distances between the lamellas and the thickness of the lamellas of the wooden beam is determined by the formula n = d1: d2, where d1 is the vapor permeability coefficient of ecowool, and d2 is the coefficient it is the vapor permeability factor of the selected wood species, each lamella has a “spike” in the upper part, a “groove” in the lower part, and cutouts for connecting along the length with the help of dowels from the end of the longitudinal wall. 2. Cellular beam according to claim 1, characterized in that the outer wooden lamella is processed by brushing. 3. The honeycomb bar according to claim 1, characterized in that in the transversely arranged latches in the center, holes are drilled during the construction of the wall for the passage of metal screeds. 4. The cell beam according to claim 1, characterized in that it contains an end lamella for forming an angular connection.

Images