RU43287U1 - CONSTRUCTION TOOL - Google Patents

Description

The utility model relates to devices used in construction, for example, when laying walls and other structures of brick blocks, namely, tools for applying mortar, for example, adhesive mortar, to a building block or brick, in particular, hollow, and distribution of mortar on its surface.

Known press boulevards (see USSR patent for invention No. 10342, IPC B 43 L 17/02, publ. 06/29/1929) with a removable pressing head-handle and blotter on a curved working surface, used for getting wet, for example, paper , by applying a considerable force to the wetted surface through the press. The press boulevard is used by touching the supporting surface of the blotted paper, first, one end of the supporting surface gradually transferring forces to the other end of the supporting surface of the press boulevard without interruption from the blotted paper, thereby achieving the largest area of the processed paper without increasing the dimensions of the press boulevard. In this case, the main purpose of using the press tool is to collect with it surplus substances, such as ink, from any surface, such as paper.

Known trowel, designed, for example, for applying mortar and its distribution on the surface of building elements, consisting of a flat working surface for applying and distributing pasty compositions, for example, cement, while the upper side of the flat surface is provided with a protruding element, which, in turn, , is interfaced with the handle section, which is at right angles to the working surface of the trowel and the handle section, which is approximately parallel to the working surface, while I wait for the mentioned sections on the inner surface of the handle there is a recess, and on the outer surface of the handle there is a small influx, on the front side of the handle there is an elongated recess for accommodating the index finger. Sections perpendicular and parallel to the working surface are conjugated through the inclined part, while the part of the handle perpendicular to the working surface is narrowed to the base, and on its sides there are also recesses for accommodating the fingers of the hand (see patent of the European Patent Office for the invention No. EP 0042971, IPC E 04 F 21/16, publ. 01/06/1982).

The known device is used as follows. Spread with a mortar with its help one side of a number of building elements, for example, bricks. Moreover, in the case of using hollow building elements, a significant part of the solution will fall into the cavity of the element, which will lead to uneconomical consumption of the solution. After that, the building element is placed in a place predetermined for it. By pressing and tapping a brick, level it with respect to previous bricks and then apply another portion of the mortar to its upper side. In this case, the solution between the laid brick and the previous layers of bricks has an uneven thickness, which also leads to its uneconomical consumption.

A scoop bucket is known for spreading the mortar over a masonry of hollow stones, while for spreading the mortar only along the edges, the side walls of the scoop are beveled to the end wall, which is made in the form of two mouthpieces for the solution to be dispensed from the scoop with two jets (see USSR author's certificate for invention No. 78332, IPC E 04 G 21/22, publ. 01/31/1950).

However, it is difficult to use the known device for pressing previously laid bricks, due to the thinness of the walls of the material from which the scoop bucket is made, as well as the inability to apply sufficient force to the laid brick to press it, for example, due to the perpendicular location of the handle relative to the direction of movement of the scoop. The specified device is also difficult to operate due to its significant mass due to the large amount of solution inside the bucket. In this regard, most of the mortar between the bricks remains unevenly distributed and, therefore, does not provide proper adhesion between the bricks and leads to uneconomical consumption of the mortar. In addition, this device is applicable only for applying mortar to building elements having large voids located along one line and does not fill the surface with the mortar located between the voids themselves, but distributes the mortar only at two extreme surfaces, excluding the application of mortar at the ends.

The closest analogue in terms of the combination of design features is a construction tool for applying mortar - a trowel having a synthetic base in the form of a panel, which is equipped with a handle with a supporting element on one side, and the other side of the panel is the working surface of the device to which a removable working plate is attached. While the plate has a protrusion, which is located in the slots of the support element, and which is held,

at least one clamping strip. Thus, the working surface and the plate are interconnected by elements that are located above the surface of the element. The trowel can have two identical clamping strips parallel to each other and parallel to the main direction of movement of the working surface. In this case, the replaceable working plate can be made of foam, felt, rubber, sponge (see German patent for invention No. DE 19512365, IPC E 04 F 21/16, publ. 23.01.1997).

However, it is also difficult to use the known device when applying the mortar on an uneven surface or a surface containing voids, due to the fact that a significant part of the solution will freely enter such voids, while it is inconvenient for the trowel to smoothly process unpredictably uneven surfaces. This leads to uneconomical consumption of mortar and an increase in the coefficient of thermal conductivity of the masonry and, consequently, an increase in heat loss during operation of the building through brickwork.

In modern construction, the requirements for thermal protection of the outer walls of buildings and structures are sharply increased. Therefore, along with the use of various facade insulation systems for buildings, it is also relevant to use bricks of various voids and reduce the thickness of the masonry joints, for example, from 10-12 mm to 2-3 mm, which generally reduces the thermal conductivity of masonry and, therefore, increases the thermal resistance of such walls.

Since the voids in the brick have different configurations (round, slit-like, square, ellipsoid, etc.) and sizes, and are often offset relative to each other, apply a layer of mortar to the free, from voids, “bed” surface of the brick with previously known tools impossible without filling part of the voids with a solution.

The task to be solved by this utility model is to create a simple and convenient construction tool construction with advanced functionality.

The technical result achieved in solving the problem is to reduce the consumption of mortar used when laying a building element, as well as reducing the coefficient of thermal conductivity of the masonry.

The problem is achieved in that a well-known construction tool containing a supporting structure provided on one side with at least one handle, while the working element is attached to the supporting structure,

according to a utility model, one side of the supporting structure is made curved, while the working element is made of elastic material with a raised outer surface and covers part of the curved surface of the supporting structure, which exerts pressure on the building element.

The radius of curvature of the surface of the curved side of the supporting structure lies in the range from 20 to 22 cm, and the arrow of the arc of the curved side of the supporting structure is from 3 to 5 cm.

The working element is attached to the surface of the upper side of the supporting structure of the tool.

It is advisable that the length of the curved surface is not less than the length of the largest side of the building element.

The height of the relief on the outer surface of the working element may lie in the range from 3 to 6 mm.

The term "building element" in the framework of this application refers to building elements in the form of blocks, parallelepipeds or other forms for the construction of individual parts of buildings, for example, bricks.

The above signs provide a technical result due to the following.

The execution of one of the sides of the supporting structure is curved, for example, with a length not less than the length of the largest side of the building element, for example, brick, allows the building tool to contact the entire accessible surface of the building element, thereby applying mortar to it.

An elastic working element is attached to the surface of the curved side of the supporting structure of the building tool, namely, at least to the part that puts pressure on the building element. The requirement of elasticity is necessary for tight contact between the working element and the supporting structure, which avoids the loss of force exerted through the tool to the building element. The outer surface of the elastic working element is embossed. In this case, when working with the tool in the space between the relief elements, a mortar will be contained, for example, adhesive mortar, which is then applied by touch to the building element. Moreover, in places of voids in the building element, the solution is not applied, but remains in the inter-relief space on the outer surface of the working element. Depending on the height of the relief, from 3 to 6 mm, you can choose the optimal amount of building

mortar, which will be on the tool before it will be applied to a building element, for example, on a brick. Due to this and due to the absence of the solution entering the voids of the building element, it is possible to achieve savings in the consumption of mortar. The implementation of the working element in such a way that it completely covers part of the curved surface of the supporting structure, exerting pressure on the building element, is necessary in order to apply the mortar from the working element on the brick to the maximum possible area with one touch. In this case, due to the presence of the relief, the solution will be applied in a more even layer, filling small bumps on the brick. The layer of the applied solution will be from 2 to 3 mm, while the voids of the building elements will be filled with an air gap. As a result of this, the coefficient of thermal conductivity of the masonry as a whole decreases, and, accordingly, the heat loss through the brickwork during the operation of the building is reduced.

Thus, using the construction tool of the proposed design, it is possible, firstly, to apply a thin layer of, for example, adhesive mortar to any building element, including hollow or uneven bricks, and, secondly, to practically eliminate the penetration of adhesive into the voids of the brick, regardless of their sizes and configurations.

The utility model is illustrated by the following drawings, where Fig. 1 shows an example of a construction tool, general view (axonometry); figure 2 is the same, side view in section; figure 3 - fragment I in figure 2 on an enlarged scale.

Positions in the drawings indicate the following: 1 - supporting structure; 2 - handle on the supporting structure 1; 3 - working element attached to the supporting structure 1; 4 - relief made on the outer surface of the working element 3.

The construction tool comprises a supporting structure 1, for example, a hollow one, equipped with a handle 2 on one side, while the other opposite side of the supporting structure 1 is curved (FIGS. 1 and 2). The radius of curvature of the surface of the curved side of the supporting structure lies in the range from 20 to 22 cm, and the arrow of the arc of the curved side of the supporting structure is from 3 to 5 cm.

It is advisable to perform the handle 2 directed along the maximum length side of the upper surface of the support structure 1 and along the direction of movement of the tool. However, it is possible to make two handles parallel to the shorter sides of the upper surface of the supporting structure 1. In this case, the handles can be as close as possible to the edges of the upper surface of the supporting structure 1.

To the supporting structure 1 is attached a working element 3 made of an elastic material, for example, rubber. The outer surface of the working element 3 is provided with a relief 4 (figure 3). It is advisable to perform the working element 3 with the height of the relief 4 on the outer surface of the working element 3 in the range from 3 to 6 mm. Such a relief is dictated by the following. In the case of the relief 4 with a height of less than 2 mm, it is likely that the mortar will not linger in the inter-relief space and, therefore, the required amount of sufficient liquid and fluid, for example, adhesive mortar, for fixing one building element will not be on the surface of the tool. When performing relief 4 with a height of more than 6 mm, on the contrary, there is a high probability that an excessively large amount of adhesive solution will be in the inter-relief space, which will lead to its insufficiently economical consumption.

The working element 3 is fixed to the supporting structure 1, covering at least that part of the curved surface of the supporting structure 1, which when using the tool exerts direct pressure on the building element, for example, brick.

The working element 3 can be attached to the upper side 'of the supporting structure 1, for example, by pressing the edges of the working element 3 with strips pressed against the surface of the supporting structure 1 by screws (Figs. 1 and 2).

In addition, it is advisable to perform a construction tool with a supporting structure 1, the length of the arc of the curved surface of which is not less than the length of the largest side of the building element.

The construction tool is used as follows.

During construction, holding the tool by the handle 2, made on one side of the supporting structure 1, is lowered into a container with a mortar, for example, adhesive. The solution enters the outer surface of the working element 3, filling, in particular, with the inter-relief space.

The tool is pressed to the place of the future location of the building element, for example, brick. The solution located on the outer surface of the tool, due to the forces of molecular interaction and, for example, adhesive properties, is transferred to the surface where the brick will be located. In this case, the excess solution remains on the outer surface of the working element 3 in the inter-relief space. The brick is laid in the right place. The tool is again dipped into the container with the solution and pressed with it the previously laid building element, making oscillating movements, transferring the pressing force from one end of the building

an element on another without taking off from a brick. Thus, the brick is evenly pressed to the surface of the previously laid building element, and the mortar is evenly applied to its outer surface. In this case, the solution from the outer surface of the working element 3 does not fall into the voids on the brick, remaining on the relief 4 and in the inter-relief space due to the strength of molecular attraction and the adhesive properties of the solution.

Thus, the proposed construction tool, unlike the well-known press box, does not serve to collect excess material, for example, liquid from any surface, but for economical uniform application of any material on the surface. Moreover, the proposed construction tool has a simple and convenient design, which is characterized by advanced functionality. Moreover, when using the proposed building tool, a reduction in the consumption of mortar used in masonry is achieved, and the thermal resistance of the brickwork increases due to the absence of mortar in the voids of the building elements.

Claims (5)

1. A construction tool comprising a supporting structure provided on one side with at least one handle, wherein a working element is attached to the supporting structure, characterized in that one side of the supporting structure is made curved, while the working element is made of elastic material with embossed outer surface and covers part of the curved surface of the supporting structure, exerting pressure on the building element. 2. The tool according to claim 1, characterized in that the radius of curvature of the surface of the curved side of the supporting structure lies in the range from 20 to 22 cm, and the arrow of the arc of the curved side of the supporting structure is from 3 to 5 cm. 3. The tool according to claim 1, characterized in that the working element is attached to the upper side of the supporting structure of the tool. 4. The tool according to claim 1, characterized in that the length of the curved surface is not less than the length of the largest side of the building element. 5. The tool according to claim 1, characterized in that the height of the relief on the outer surface of the working element lies in the range from 3 to 6 mm.