RU218165U1 - WOODEN I-BEAM CONNECTOR - Google Patents

Abstract

The utility model relates to the field of construction, namely to the connections of spatial frames of various structures exclusively from wooden I-beams (hereinafter referred to as DDB) of any type and type of execution. The DDB connector, located at an angle to each other, is characterized by the fact that on the inside it is made with a relief that repeats the shape of the walls of the connected I-beams between their shelves, and on the outside it is made flat and provided with holes for fasteners located in the area of the shelves and holes with recesses for bolted connection of the walls of I-beams. EFFECT: ensuring a reliable connection of the elements of the load-bearing frame for wooden I-beams as a designer for self-assembly. 1 z.p. f-ly, 17 ill.

Description

The utility model relates to the field of construction, namely, to the connections of spatial frames of various structures exclusively from wooden I-beams (DTSB) of any type and type of execution.

There are various solutions for joining beams.

Known ridge knot, which can be used in the manufacture of wooden arches, frames and trusses (RU 65524 U1). The ridge assembly contains wooden rods, the ends of which are joined at an angle to each other and fastened with butt plates, while the cross section of the rods is given an I-beam profile, the wall of which is made of at least two plywood plates placed with a gap equal to the thickness of the plates fastened with each other by means of transverse stiffening ribs fastened to both plates, and the shelves are made in the form of bars fixed along the longitudinal edges of the plates on their outer side and in the gaps between them, and the ends of the shelves and walls of the rods rest against each other. The butt plates are given V-shaped outlines in the form of a ridge, and they are placed in the gap between the plywood plates and on their outer surface and are made with a thickness equal to the width of the gap. In addition, the joint section over the entire area of the butt plates and over the entire thickness of this section is stitched with tie elements, such as screws.

A significant disadvantage of this type of joint is that it is fastened with plates only in the area of the walls at the ends of the DDB, which is not sufficient for its use in other versions and does not reduce the load in the supporting part of the DDB on the shear.

A connector for beams (RU 2727996 C1) is known, made in the form of a single-piece flat part containing two bearing elements located at an angle to each other, with rectangular grooves made in them on one side of the flat part, limited by bearing support areas located in the area of \u200b\u200bthe largest loads.

The disadvantage of this nodal connection is the impossibility of providing a tight connection at the attachment points of the DDB, including directly end to end. The shape and type of this beam connector is designed to connect only solid rectangular beams, and without the use of any additional reinforcing elements, it will be impossible to make a snug fit of the SDB forms, which will inevitably lead to a deterioration in the strength characteristics of the beam and damage when exposed to various forces, for example, on a cut .

There are connectors for wooden beams under the woodcastor brand (site on the Internet https://woodcastor.ru/openbarn), and the like (https://barn-housc.shop/konnectory/).

This type of connectors is designed exclusively for a solid board for the formation of various arches and the roofing part of the frame structure. Their disadvantage is the high consumption of plywood during manufacture, in addition, several people are required to erect the frame due to the instability of the structure in disassembled form and the severity of the mounted parts. The connectors have a different shape and are divided into right and left connectors of different sizes, which leads to the complication of the constructor as a whole. An additional disadvantage is the use of additional overlays for the formation of a power frame.

Known metal connectors for beams used by the company LLC "MINIDOM.RU" under the brand Barn (https://barn.ru/') and similar LLC "Group of Companies" Antey "(https://vsesvai.ru/shop/konnektor /).

Similar to the aforementioned connectors, this type is designed exclusively for a solid board to form various forms of nodal joints. A significant drawback is the use of metal in nodal joints with a wooden board, which negatively affects the strength during the operation of the load-bearing frame due to possible condensation in the area of \u200b\u200bcontact between wood and metal, which leads to rotting of the tree, and therefore to a decrease in the strength of the power unit . Also, the use of metal for the production of a connector leads to its rise in price in comparison with plywood, which has a high degree of tensile strength.

The technical problem to be solved is the creation of a connector for wooden I-beams (hereinafter referred to as the Connector), which provides a high bearing capacity of the DDB connection between each other and makes it possible to reduce the consumption of wood when forming a frame structure.

EFFECT: ensuring a reliable connection of the elements of the load-bearing frame for the DDB as a constructor for self-assembly.

This result is achieved by a connector for wooden I-beams located at an angle to each other, characterized in that on the inside it is made with a relief that repeats the shape of the walls of the connected I-beams between their shelves, and on the outside it is made flat and provided with shelves located in the area holes for fasteners and holes with recesses for bolted connection of the walls of I-beams.

The relief of the inner side may be less than the shape of the walls of the connected beams between their shelves by 1-2 mm.

The connector can also be coated with a polymeric waterproofing and reinforcing material.

The use of a Connector with a relief that repeats the shape of the inner part of the DDB - part of the beam between the shelves, usually made in the form of bars - and the shape of their connection, allows for tight connections in the area of the wall of the DDB (2) and in the area of \u200b\u200bshelves (3) at the connecting ends of the connection DDB.

The repetition of the shape of the inner part of the beams, as a rule, means the execution of the relief in the form of a solid plate in the area of the supporting part of the DDB (Fig. 1, 2, 3, 4, 5), which gives close contact along the entire inner surface of the walls of the beams in places of their contact with connector.

Also, this solution will allow anyone who does not have building skills to build low-rise frame houses on their own according to standard projects, that is, it allows to simplify the assembly of frames.

Thus, the connecting node will in most cases be two docking ends of the DDB, pressed on both sides by the Connectors (see Fig. 6).

The utility model is explained with the help of FIG. 1-17.

In FIG. 1 shows a general view of the outer part of the Connector.

In FIG. 2 shows a general view of the inside of the Connector.

In FIG. 3 shows a general view of the end part of the Connector.

In FIG. 4 shows a general view (isometry) of the outer part of the Connector.

In FIG. 5 shows a general view (isometry) of the interior of the Connector.

In FIG. 6 shows an example of a nodal connection with 120 degree connectors.

In FIG. 7 shows an example of a 90 degree universal connector

In FIG. 8 shows an example of a Ridge Connector.

In FIG. 9 shows an example of the visor connector.

In FIG. 10 shows the V-shaped support connector

In FIG. 11 shows the L-shaped support connector.

In FIG. 12 shows the T-shaped support connector.

In FIG. 13 shows the Y-shaped support connector.

In FIG. 14 shows a support-through connector.

In FIG. 15 shows the reverse version of the support-through connector.

In FIG. 16 shows a reinforced double connector.

In FIG. 17 shows an example of a complex construction of a frame section using Connectors of various designs.

The density of the connection is ensured by direct gluing together along the entire plane of contact of the Connectors with DDB at its ends, for this, the beams in the area of the walls are pulled together with Connectors with a bolted connection, and in the area of \u200b\u200bthe shelves they are sewn together with metal brackets, nails or self-tapping screws (see Fig. 6).

Structural adhesive can be used for additional strength at the point of contact between the Connectors and the beams.

For any spatial position of the beams and the formation of any architectural complexity, Connectors were developed, which are solid or prefabricated plates made of plywood grade not lower than FK 4/4 according to GOST 3916.1-2018 or plywood coated with a polymeric waterproofing reinforcing material with high tensile strength or break.

The thickness of the plywood of the Connector depends on the dimensions of the inner shelf of the DDB.

The use of metal plates is not allowed due to the highly probable negative atmospheric effect, namely, the constant inter-seasonal temperature difference will invariably lead to condensation. The condensate that has fallen out will destroy the wooden component of the assembly at the junction of metal and wood, which will lead to decay and destruction of wooden power elements.

As mentioned above, the standard Connector has different types of execution and purpose, depending on the formation of the angular value of the DDB connections between themselves.

To develop standard solutions for the formation of connecting nodes, for example, typical types of interbeam angles of 30, 45, 60, 90, 120, 135, 150 degrees are used. For the design of non-standard solutions, other angular values \u200b\u200bin the range of 10-170 degrees can be used. In FIG. 1, 2, 3, 4, 5, 6 shows an example of a standard 120 degree Connector.

Changing the beam connection angle leads to a change in the shape of the connector itself, however, the essence of each node remains unchanged, namely: the outer part of the Connector (1) always has a flat shape, (see Fig. 1, 4) with holes (4) and recesses (5) for bolted connection and additional places for brackets (screws, nails) fasteners (6).

The inner part (2, 3) repeats the shape of the DDB corner joint, and repeats the shape of the inner part of the beam (see Fig. 6), which makes it possible to have a tight connection both in the area of the wall (central partition) of the beam (2) and in the area of the beam flanges (3).

In the space between the flanges of the beam, the inner part of the rib of the Connector can have a gap of 1-2 mm both for possible expansion during temperature changes and for ease of assembly.

As can be seen from FIG. 1-17, this version of the Connector allows you to connect the DDB butt-to-butt at different angles between two beams, as well as to ensure a snug fit of the joints of the beams on each side and has a rigid fastening along all side planes on both sides, which ensures high efficiency and durability of this nodal connection.

Next will be described technical options for the execution of the connecting node.

Depending on the location of the nodal connection in the power frame, there are certain changes and additions to the formation of the connecting node and the Connector:

- according to the type of corner connection DDB for example: 30, 45, 60, 90, 120, 150 degrees, etc.

- by type of destination, for example: Ridge, Visor, Support, Checkpoint, Checkpoint, Support-Checkpoint.

- by type of connection, for example, Connector - Y, Connector - T, Connector - V.

- special purpose, for example, Universal, Double, Front, Connecting.

These types of executions are of fundamental importance in the formation of the connecting node of the load-bearing frame for different architectural styles of the construction of a frame building for any type of angles of conjugation of the DDB.

Connector Universal.

The Universal Connector, unlike the standard one, has special cutouts on both sides for the DDB guide under the flanges of the beam, located perpendicular to the Connector. So in FIG. Figure 7 shows an example of a 90-degree Universal Connector with a DDB guide located perpendicular to the slots.

This solution allows the guide beam to freely fit into the slot of the Connector, which makes it possible to assemble the load-bearing frame according to the template, always with the same dimensions in any section of the load-bearing frame. By default, these cutouts are made along the outer edge of the Connector, but if necessary, they can be made along the inside.

Connector Ridge.

The Ridge Connector is mainly designed to form the arch of the future roof ridge. Unlike the standard one, it can have special grooves in the center along the axis of conjugation of two ridge beams of different heights, depending on the project. In this groove, a guide intersection bar or an intersection DDB jumper is installed. An example of execution is shown in Fig. 8.

Connector Kozyrkovy.

Depending on the type of roofing with soft tiles, with metal tiles, and other types of roofing pie, as well as on the type of roof suspension and the method of its filing in place of the Peak Assembly, the Connectors can have different types of execution, some of them are shown in Fig. 9.

In the case of a roof seam, it is rational to use a standard nodal connection with a Connector - V (Fig. 6)

To carry out the sheathing of the canopy suspension, as well as to install the bars and boards of the roofing cake, a gasket is fastened (with staples, screws, nails) into the protruding part, repeating the shape of the protruding part of the canopy made of wood or plywood in the shape of the protruding element of the canopy. For the version for an inch board for a cornice strip (kagelnik), an example is shown in Fig. 9.

Connector Basic V-shaped.

This type of Connectors allows you to strengthen any type of DDB corner connection in places where it is required to support this connection for additional unloading of forces acting directly from above. It is advisable to use the supporting V-shaped in the ridge zone of the load-bearing frame, as in Fig. 10.

Connector Basic G-shaped.

This type of connection allows you to combine any inclined part of the load-bearing frame to the connection of beams at 90 degrees by leaning on this connection from above. It is rational to use this type of connector in the transition of the roofing part of the load-bearing frame to the wall part with the already formed division of the frame of the interfloor overlap (Fig. 11).

Connector Basic T-shaped.

It is rational to use this type of Connector in places where the vertical load is supported to the base of the load-bearing frame. So, for example, it is possible to use this Connector in places where wall openings rest against the base of the floor or to evenly distribute loads in the formation of a ridge knot truss (Fig. 12).

Connector Basic Y-shaped.

This type of connection is made in the form of a fork connector to support the V-shaped connection of the DDB (Fig. 13). The Support Y-Connector can be used, for example, to attach additional roof hangers to compensate for sagging (tightening) of the lintel under its own weight in order to redistribute the load between all elements more evenly.

Connector Support-through.

Support-Through Connector - for forming a corner connection with a horizontal or vertical support with an already formed V-shaped nodal connection of the load-bearing frame (Fig. 14).

The reverse version of the Connector is designed for adjoining any SDB to a solid supporting SDB, as a result of which the support beam itself does not break in the nodal connection (Fig. 15).

An illustrative example of the use of this Connector for the installation of a transverse DDB jumper (puff) between roof beams to increase the rigidity of the roof structure, aimed at reducing the load on the roof truss expansion, which reduces the snow and wind load aimed at destroying the walls.

Connector Reinforced Dual.

To strengthen connectors or possible design solutions, all of the above types of Connectors can be converted to Reinforced when connecting beams to each other by doubling. One of the many examples of this implementation is shown in Fig. 16.

The result of using Connectors for DDB allows you to perform complex solutions for building a load-bearing frame and forming sections. An example of the complex construction of a frame section using the aforementioned Connecting Nodes in FIG. 17:

Knot 1. - Connector V-shaped Ridge (120 degrees);

Node 2. - Connector Support-Through (120 degrees);

Node 3. - Connector Visor (120 degrees);

Knot 4. - Connector V-shaped Universal (120 degrees);

Node 5. - Connector Y-shaped Support (120 degrees);

Node 6. - Connector T-shaped Support (90 degrees);

Node 7. - Connector Support-Through (120 degrees);

Node 8. - Connector L-shaped support-through (120 degrees).

The production of the described types and types of Connectors is carried out using high-precision CNC machines in the factory. Each Connector must be used in accordance with the technical calculations for the loads and are used in accordance with the individual design decision.

Thus, the solutions discussed above for the implementation of interbeam connections using the developed types of Connectors allow us to solve the previously posed technical problem.

EFFECT: ensuring reliable connection of elements of a load-bearing frame for wooden I-beams as a constructor for self-assembly.

A comparative analysis of the features of the claimed solution with the features of the prototype and analogs indicates that the claimed solution meets the criterion of "novelty".

Claims (2)

1. A connector for wooden I-beams located at an angle to each other, characterized in that on the inside it is made with a relief that repeats the shape of the walls of the connected I-beams between their shelves, and on the outside it is made flat and provided with holes located in the area of the shelves for fasteners and holes with recesses for bolted connection of the walls of I-beams. 2. The connector according to claim. 1, characterized in that the relief of the inner side is less than the shape of the walls of the connected beams between their shelves by 1-2 mm.

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