CZ2020708A3 - Prefabricated die, head and die assembly and method of making this assembly - Google Patents

Abstract

The prefabricated die (1) is provided in the head (2) with at least one adjusting hole (3) intended for mounting on the adjusting mandrel (4) of the support head (5). The positioning hole (3) is formed in the positioning plate (6), which extends beyond the contour of the head (2) in the direction (a) of the axial axis of the positioning mandrel (4). The adjusting plate (6) is connected to the head (2) or to the die (1) with the possibility of vertical movement of a part of the adjusting plate (6) with the adjusting hole (3). The assembly comprises at least one prefabricated die (1) and at least one support head (5) provided with an adjusting mandrel (4). The clearance of the positioning hole (3) is larger than the cross section of the positioning mandrel (4). The adjusting mandrel (4) is loosely mounted in the adjusting hole (3). The dies (1) are gradually fitted through the positioning holes (3) on the positioning mandrel (4) of the support head (5). The exact position of the dies (1) is corrected by their displacement within the clearance between the adjusting mandrel (4) and the adjusting hole (3).

Description

Prefabricated die, head and die assembly and method of making this assembly

Field of technology

The invention relates to the construction industry, in particular to a prefabricated die and a head for finishing both horizontal and vertical building structures.

State of the art

The use of prefabricated parts is one of the basic and commonly used construction procedures in the current construction industry, replacing or at least limiting direct work on construction sites. Prefabricated parts are made of concrete, reinforced concrete, ceramics, ceramic-concrete combinations, steel and other materials. These parts are mass-produced in pre-production, transported to the construction site and installed there as an assembly part.

This pre-production of prefabricated parts off-site speeds up the final construction process, significantly reduces the discomfort of working outdoors in various climatic conditions and improves the structure and accuracy of construction of buildings, bridges and similar building structures. It also eliminates the need to build formwork, which is so necessary when preparing concrete structures at the construction site. Thanks to machine pre-production, molds for series production, vibrating benches for shaking concrete and jigs for more precise installation of metal or other reinforcing and fastening elements can be used for the finishing of building elements. All this improves the quality of the resulting prefabricated product and gives it better parameters than can be achieved by production technology on site. On the other hand, in the case of prefabricated parts, it is necessary to solve the problem of their settlement, where it is first necessary to geodetically determine the coordinates for their position, and then it is necessary to fit these large and heavy parts to the marked coordinates, usually by crane. For this purpose, various support head structures are anchored to the ground, for example concreted into the ground, so that, during settling, they form both a permanent and a temporary stabilizing and load-bearing element of a building provided with darkness for the establishment of foundation openings.

From the document CZ 2010-893, the foundation structure of buildings intended for flood areas is known. The foundation structure is not in direct contact with the subsoil and is supported by columns or footings. A reinforced concrete frame consisting of a pair of reinforced concrete dies and a pair of reinforced concrete stiffeners is anchored to the columns, interconnected by a system of positioning holes and mandrels. This construction is fitted with standard ceiling panels mounted on mortar-studded mandrels. The disadvantage of this construction is the fact that the system of positioning holes and darkness of this solution is able to connect only two separate parts of the structure, ie one dark foot with one positioning hole of the die or stiffener.

U.S. Pat. No. 4,107,889 discloses the construction of building foundations, when the foundation foot, as in the previous document, is provided with a positioning mandrel or pin, on which a die is set at the location of the foundation opening in the die. In contrast to the previous one, the constitutional opening located here is located elsewhere than at one end of the channel. Here, too, it is true that one tm is intended for only one inlet opening of the die.

For the purposes of the description of the present invention, a die means a ceiling, roof or bridge die, lintels, ceiling beams, panels, foundation sills, foundation strips and the like made of any material. The end of the die is called a head, which is a stepped end of the die for mounting the die on a support head, which for the purposes of the present invention means any construction designed to accommodate the die, especially a column, pile, foot wall, etc. The shoulder may be a tooth. The die is usually a horizontal building component, such as a foundation beam, a ceiling beam, including, for example, ceiling panels, but it can also be a vertical building component, such as a wall section. For purposes of describing the present invention, the term "die" will mean any prefabricated one

- 1 CZ 2020 - 708 A3 building structure, intended at least at one end for mounting on a support head provided with an adjusting mandrel, and provided with an adjusting hole intended for fitting on said setting darkness.

During construction, according to the prior art, the die head is first placed on the upper surface of the support head, e.g. the foot, and at the same time the die is manipulated by a crane so that the setting dark fits into the opening opening. The die can then no longer be manipulated, either horizontally or vertically. The foundation footing or other support must therefore be very massive, bulky, heavy, deep foundations must be dug for it, formwork, reinforcement and concreting must be built, all with dimensioning for its load not only by the die, but also by its own building structure, which will be to mount after fitting the die.

The current design of the dies is such that the positioning holes are formed directly in the die or in its head, e.g. as part of a tooth. However, it is common for constructions that more gutters meet at their ends, eg in the case of foundation or ceiling gutters, they meet at the corners of future rooms. The ends of the dies with teeth and positioning holes can be fitted in two ways.

In the first method, one very large and strongly dimensioned head is built, carrying up to four or more dies. There is one setting darker for each die on the upper surface of the head. The dies lie with their heads on the same upper surface of the head, each of which is mounted on its setting darkness with its setting hole.

In the second method, a separate head must be made for each die, dimensioned to support one die.

The disadvantages of the known prefabricated structures of the die type and of the two known methods of their assembly lie in the fact that their installation takes a very long time and, in addition, is also constructionally and thus financially demanding. First, the position of the future locating mandrels must be geodetically determined. Then the formwork must be built and the heads built, or the prefabricated head with the positioning market can be precisely fitted in the set position. The heads are dimensioned for the load-bearing capacity corresponding to the static load of the whole structure, ie very heavy. It is not possible to place more than one die at the same time on one head with one adjusting mandrel, because each die would be at a different height.

The object of the present invention is to eliminate these drawbacks.

The essence of the invention

The present invention overcomes the shortcomings of currently known prefabricated dies, support head assemblies and dies, and methods of making such assemblies.

The prefabricated die according to the invention is provided in the head with at least one positioning opening intended for fitting the die to the positioning darkness. The positioning dark is part of the support head and protrudes above its upper profile. The positioning hole is formed as part of the positioning plate in that part of it which extends beyond the contour of the head in the direction of the longitudinal axis of the die. The positioning plate is connected to the head or die with the possibility of moving at least that part of the positioning plate in which the positioning hole is formed. The possibility of moving a part of the positioning plate with the positioning hole is with one degree of freedom in the vertical plane, i.e. in the direction (a) of the axial axis of the positioning darkness (4) and the positioning opening. This direction (a) of the axial axis is the direction in the vertical plane, i.e. the direction up and down in the plane perpendicular to the longitudinal axis of the positioning darkness.

In a preferred embodiment, the positioning plate is possible, where its first end is integrated in the head. The long end of the positioning plate provided with the positioning hole is unloaded from the head with the possibility of pivotal movement within the limits of the possibility of the material of the plate.

In another preferred embodiment, the positioning plate is made of steel web.

-2 CZ 2020 - 708 A3

In another preferred embodiment, both the die and the head are of a reinforced concrete structure. In this preferred embodiment, the positioning plate is inseparably mounted with its first end in the head.

In yet another preferred embodiment, the die is made of reinforced concrete. A metal housing is integrated in the head of this die, in which the first end of the positioning plate is housed. The fastening of the metal housing to the head is in this preferred embodiment detachable or non-detachable.

In the following preferred embodiment, the first end of the positioning plate is firmly anchored in the metal housing, at least in part. The free, ie unanchored part of the first end of the positioning plate is then placed with the possibility of pivotal movement within the limits of the elasticity of the plate material. The limiting factor of the swing is also the inner profile of the metal housing.

In another preferred embodiment, the first end of the positioning plate in the metal housing is rotatably mounted on a pin or slidably in a sliding link. This bearing allows the movement of the entire positioning plate in the vertical direction. The movement of the first end of the positioning plate is either rotatable or sliding in the slide, where the sliding movement is limited by the length of the slide or the height of the metal housing.

In another preferred embodiment, the first end of the positioning plate has a smaller diameter in the horizontal plane than the inner horizontal diameter of the metal housing. In this preferred embodiment, the free part of the first end of the positioning plate is provided with a fixed spacer, which limits the possible horizontal oscillation of the positioning plate in the metal housing.

In the following preferred embodiment, the positioning plate is fixed to the head with the possibility of pivotal movement along its entire length.

In another preferred embodiment, the positioning plate is connected to at least one arm arranged on the side of the die and rotatably mounted on a pin passing through the die.

In another preferred embodiment, the positioning plate is made of steel web.

In the following preferred embodiment, the positioning hole has an oval or rectangular shape.

In another preferred embodiment, the head has a tooth formed at its end provided with a positioning plate. The present positioning plate is thus positioned on the tooth in this preferred embodiment. The tooth is adapted for mounting on a support head, its main task being to define the vertical position of the drawing of the die by its support on the support head. In the case of dies whose height significantly exceeds their width, the tooth also serves for the spontaneous gravitational positioning of the die profile in a vertical position, which is advantageous in particular if the die is used as a foundation strip with subsequent undercutting.

The assembly of at least one prefabricated die is formed by at least one support head provided with an adjusting mandrel. The clearance of the positioning hole is larger than the cross section of the positioning darkness, so that the positioning darkness is loosely deposited in the positioning hole.

In a preferred embodiment, the inner length of the positioning hole in the direction of the longitudinal axis of the die and the inner width of the positioning hole in the direction perpendicular to this direction are greater than the outer dimensions of the positioning darkness in said directions.

In another preferred embodiment, the positioning tm has a kilometer cross-section. In this preferred embodiment, the positioning opening has an oval or rectangular shape, the clearance of the positioning darkness in the positioning hole being at least 5 mm over the entire circumference of the positioning darkness. This clearance is in all directions of the horizontal plane.

-3 CZ 2020 - 708 A3

In another preferred embodiment, the play of the setting darkness in the setting hole is greater in the direction of the longitudinal axis of the die than in the direction perpendicular to this direction.

In the following preferred embodiment, n dies are mounted on one support head, where n = 2 to 8. In this preferred embodiment, the positioning plates of all dies are arranged on a common positioning darkness by their positioning openings. The end of the plate of each subsequent die is thus arranged higher in the setting darkness than the end of the plate of the previous die.

The method of finishing the assembly consists in geodetically measuring the position of the positioning darkness in the support head. Subsequently, the positioning darkness in the support head is anchored in the hole created in the geodetically oriented place. Subsequently, the dies are gradually fitted with their positioning holes in the positioning plates on one common positioning dark of the support head. The correction of the positioning of the die is given by the possible displacement of the dies to the desired position within the clearance between the positioning mandrel and the positioning opening of the positioning plates of the dies. In the final position of the shoulder, the longitudinal axes of the dies intersect the cross-section of the setting darkness. In the most preferred embodiment, the longitudinal axes of the dies directly intersect the axis of the setting darkness.

In a preferred embodiment, the support head and the dies are dimensioned to a load capacity corresponding to the dead weight of the assembly. After being placed on the support head, the dies are concreted, thus creating precisely directionally oriented and planar foundation strips in the upper part.

In another preferred embodiment, a die with a removably mounted metal housing is used. In this preferred embodiment, the metal housing is removed from the die after the concreting.

In the following preferred embodiment, a die with a pivoting positioning plate with two arms on a common pin is used. In this preferred embodiment, the positioning plate with the arms and the pin is removed from the die after the concreting of the die.

The biggest advantage of the solution according to the invention is that the construction of the die allows the joint installation of several dies at the same time. The axes of all dies point to the center of the respective setting dark, and the possibility or possibility of vertical deflection of the plate allows each further plate to be mounted on the same setting dark on which the previous plate with the setting hole is already mounted. The next plate tilts upwards. The height of all dies remains the same, all dies are mounted with their heads on one head with a single positioning mandrel. The shape of the positioning opening in the planchet allows a certain freedom of mounting the die in the coordinate system of the horizontal plane, ie. precise placement of the die directly by crane on the geodetic coordinates of its position. The secondary advantage is that the solution can be used for a system of temporary heads and temporary foundation dies, which are very light. After installation, the temporary beams are underconcreted, and then removed again, creating finished foundation strips on the construction site.

The solution according to the invention allows a single mounting tm to be used for the correct axial mounting of all the respective dies, the center of which is the intersection of the coordinate system of the axes of all the respective dies. This single darkness is easily defined by the surveyor, while eliminating the risk of inaccurate positions of multiple mandrel-mounted mandrels caused by rotating a multi-mandrel-mounted head.

Installation of dies according to the invention is very fast, not only saving time of assembly, but especially time required for previous construction of stable and massive heads with a special positioning mandrel for each die, saving material, ie formwork and concrete, and thus reducing the cost. construction process.

-4 CZ 2020 - 708 A3

Clarification of drawings

The invention will be further elucidated with the aid of the drawings, which show:

Giant. 1 is a perspective view of a die fitted with a pair of positioning plates for simultaneous seating on a pair of support heads, each with one positioning mandrel. Each plate is connected to two arms rotatably mounted on a pivot in the head of the dies;

Fig. 2 is a perspective view of a part of a pair of dies fitted with a pair of positioning plates on a common positioning darkness protruding from a single support head. Each plate is connected to two arms rotatably mounted on a pivot in the head of one of the dies;

Fig. 3 is a perspective view of a part of a trio of dies fitted with a trio of positioning plates on a common positioning darkness emerging from a single support head. Each plate is connected to two arms rotatably mounted on a pivot in the head of one of the dies;

Fig. 4 is a perspective view of a part of a pair of dies fitted with a pair of positioning plates on a common positioning darkness emerging from a single support head. Each plate is connected to two arms rotatably mounted on a pivot in the head of one of the dies. The die is formed by a steel "I" profile;

Fig. 5 is a perspective view of a part of a trio of dies fitted with a trio of positioning plates on a common positioning darkness emerging from a single support head. Each plate is connected to two arms rotatably mounted on a pivot in the head of one of the dies. The die is formed by a steel "I" profile;

Fig. 6 is a perspective view of one side of the dies fitted with a metal housing with an adjusting plate and a fixed spacer. The plate is seated on the positioning darkness of the support head.

Fig. 7 is a perspective view of a part of two dies mounted on the same setting darkness of one support head. The dies are fitted with a metal housing with an adjusting plate. The adjusting plates are provided with a fixed spacer.

Fig. 8 is a perspective view of a part of three dies mounted on the same setting darkness of one support head. The dies are fitted with a metal housing with an adjusting plate. The adjusting plates are provided with a fixed spacer.

Fig. 9 is a perspective view of one side of the dies fitted with an adjusting plate on the adjusting darkness of the support head. The positioning plate is inseparably anchored to the head from above and the lateral movement is prevented by a double-sided lateral guide.

Examples of embodiments of the invention

It is to be understood that the specific embodiments of the invention described and illustrated below are presented by way of illustration and not by way of limitation. Those skilled in the art will find or be able to ascertain using routine experimentation more or less equivalents to the described embodiments of the invention.

According to the basic embodiment of the invention shown in Figs.

- 5 CZ 2020 - 708 A3 top profile. The positioning hole 3 is formed as part of the positioning plate 6 and is located in that part of the positioning plate 6 which extends beyond the contour of the head 2 in the longitudinal axis direction 1. The positioning plate 6 is connected to the head 2 or die 1 with at least that part of the positioning plate 6, in which the positioning hole 3 is formed. upwards and downwards in the longitudinal axis of the positioning darkness 4. The positioning plate 6 is movable and its first end is integrated in the head 2. The long end of the positioning plate 6 is provided with a positioning hole 3 and is unloaded from the head 2 with pivoting movement positioning plates 6.

The movement of the positioning plates 6 in the direction and axial axis of the positioning hole 3 is important for mounting several positioning plates 6 on one common positioning plate 4. Conversely, lateral movement, i.e. movement in the radial direction of the positioning hole 3, is undesirable and 1 to setting dark 4.

According to the same embodiment of the invention, the positioning plate 6 can be made of steel strip. According to another embodiment of the invention, the positioning plate 6 can be made of plastic, another metal, another material or another profile with sufficient strength and ductility.

According to a long, not shown, embodiment of the invention, the die 1 and the head 2 are of reinforced concrete construction. In this exemplary embodiment of the invention, the positioning plate 6 is inseparably mounted with its first end in the head 2 and its thick end protrudes from the head 2 from the side, i.e. from the side adjacent to the positioning darkness 4 in the set state of the die 1.

According to a third embodiment of the invention, shown in FIG. 9, both the die 1 and the head 2 are of reinforced concrete construction. In this exemplary embodiment of the invention, the positioning plate 6 is inseparably mounted with its first end in the head 2 and its long end protrudes from the head 2 in its upper part and along this upper part of the head 2 faces the side of the head 2, where it projects laterally outside the side profile of the head. 2. According to this exemplary embodiment of the invention, the long end of the positioning plate 6 is provided with a side guide 11 which prevents the positioning plate 6 from moving sideways, even when it is bent in the direction and axial axis of the positioning hole 3.

According to a fourth embodiment of the invention, partially shown in Figs. 6 to 8, the die 1 is made of reinforced concrete and a metal housing 7 is integrated in the head 2 of this die 1, in which the first end of the positioning plate 6 is mounted. 2 is a detachable or non-detachable phenomenon in this preferred embodiment. The detachable connection can be made by means of anchor bolts (not shown) or other methods well known to the person skilled in the art for anchoring elements to reinforced concrete. The non-removable connection can then be effected, for example, by means of anchor elements (not shown) fixed to the metal housing 7 and encapsulated in head 2, or also by means of a screw connection (not shown).

According to the same embodiment of the invention, the first end of the positioning plate 6 (not shown) is at least partially anchored in the metal housing 7. The free, i.e. unanchored part of the first end of the positioning plate 6 is then pivoted. In this exemplary embodiment of the invention, the inner profile of the metal housing 7 is also a swing.

According to a fifth embodiment of the invention, shown in part 6 to 8, the die 1 is made of reinforced concrete and a metal housing 7 is integrated in the head 2 of this die 1, in which the first end of the positioning plate 6 is housed. 2 is a detachable or non-detachable phenomenon in this preferred embodiment. In this exemplary embodiment of the invention, the first end (not shown) of the positioning plate 6 in the metal housing 7 is rotatably mounted on a pin (not shown) or slidably in a sliding link (not shown). This bearing allows the movement of the entire positioning plate 6 in the vertical direction. The movement of the first end of the positioning plate 6 is either rotatable or sliding in the slide, where the sliding movement is limited by the height of the slide and the height of the metal

-6GB 2020 - 708 A3 of the housing 7. The movement of the other end of the base plate 6 is an extension of the movement performed by the first end. In addition, the other end can also perform a vertical up or down bend, depending on the flexibility of the construction material of the positioning plate 6.

In the sixth embodiment of the invention shown in Figs. 6 to 8, formed according to the fourth and fifth embodiments, the first end of the positioning plate 6 has a smaller diameter in the horizontal plane than the inner horizontal diameter of the metal housing 7. 6 is in this preferred embodiment provided with a fixed spacer 10 which limits the possible horizontal oscillation of the positioning plate 6 in the metal housing 7.

According to a seventh embodiment of the invention, shown in FIGS. 1 to 5, the positioning plate 6 is fastened to the head 2 with the possibility of pivotal movement along its entire length.

According to one variant of the seventh embodiment of the invention, the positioning plate 6 is connected to at least one arm 8 arranged on the side of the die 1 and rotatably mounted on a pin 9 passing through the die L. To create a sufficient barrier for possible lateral displacement or bending 4, the arrangement can be made with a pair of arms 8 arranged on both sides of the die 1, which are mounted on a common pin 9. Instead of one arm 8, the positioning plate 6 can be mounted, according to a non-illustrated embodiment of the invention, opposite the arm 8 opposite the side guide 11.

According to another variant of the seventh embodiment of the invention, the positioning plate 6 is made of steel strip. Also in this exemplary embodiment of the invention, the positioning plate 6 can be made of a different construction material or of a different material profile.

For the individual embodiments of the invention, the positioning opening 3 has, according to FIGS. 1 to 9, an oval or not rectangular shape. The positioning hole 3 can also have other shapes, but the oval and rectangular shape best meet the needs of fitting this hole 3 on the positioning section 4 of cross-section.

For individual embodiments of the invention, the head 2 may be provided at its end provided with an adjusting plate 6 with a tooth 12. This arrangement is shown, for example, in Figs. 12 in these embodiments of the invention is adapted to be mounted on a support head 5 and its task is to precisely define the vertical position of the mounted die 1. For dies 1, the height of which significantly exceeds their width, the tooth 12 also serves to self-gravitationally position the die position. According to another exemplary embodiment of the invention shown in FIGS. 6 to 8, the tooth 12 can also be formed as part of a metal housing 7.

According to FIGS. 1 to 9, the support head assembly 5 and the die 1 are formed by at least one prefabricated die 1 and at least one support head 5 provided with an adjusting mandrel 4. The clearance of the adjusting aperture 3 tm 4 is placed in the positioning opening 3 with clearance.

According to the exemplary embodiment of the invention shown in Figs.

According to the exemplary embodiment of the invention shown in FIGS. 1 to 9, the positioning body 4 has a circular cross section. In this exemplary embodiment of the invention, the positioning opening 3 has an oval shape or, according to an exemplary embodiment of the invention, a rectangular shape. According to both of these embodiments of the invention, the play of the setting darkness 4 in the setting hole 3 is at least 5 mm along the entire circumference of the setting darkness 4. This play is in all directions of the horizontal plane. According to the same exemplary embodiments of the invention, the play of the setting darkness 4 in the setting hole 3 is greater in the direction of the longitudinal axis of the die 1 than in the direction perpendicular to this direction.

-7 CZ 2020 - 708 A3

According to the exemplary embodiment of the invention shown in FIGS. 2 to 5 and 7 to 8, n dies 1 are mounted on one support head 5, where n = 2 to 8. The positioning plates 6 of all dies 1 are in this exemplary embodiment of the invention their positioning plates. the openings 3 are arranged on a common positioning dark 4. The end of the positioning plate 6 of each subsequent die 1 is thus arranged higher on the positioning dark 4 than the end of the positioning foil 6 of the previous die L. it is made possible by the possibility of the positioning plate 6 to make a movement in the vertical plane with its other end.

According to the exemplary embodiment of the invention shown in FIGS. position focus created. Then the dies 1 are successively fitted with their positioning holes 3 in the positioning plates 6 to one common positioning team 4 of the single support head 5. In the final position of setting the dies 1 on the common setting dark 4, the longitudinal axes of the dies 1 intersect the cross-section of the setting dark 4. Ideally, the longitudinal axes of the dies 1 intersect the axis of the common setting dark 4.

According to another embodiment of the invention, the support head 5 and the dies 1 are dimensioned for a load capacity corresponding to the dead weight of the assembly. After being placed on the support head 5, the dies 1 in this exemplary embodiment of the invention are concreted, thus forming precisely directionally oriented and planar base strips in the upper part.

In another exemplary embodiment of the invention, a die 1 with a detachably fastened metal housing 7 is used.

In the following exemplary embodiment of the invention, a die 1 with a pivoting positioning plate 6 with two arms 8 on a common pin 9 is similarly used. again it is possible to use them for mounting on another die L

Industrial applicability

The prefabricated die, head and die assembly and the method of making this assembly will find application in construction, where they will primarily speed up and simplify the process of assembling buildings, bridges and similar building structures, and will also make their assembly more accurate.

Claims (22)

PATENT CLAIMS A prefabricated die (1) provided in the head (2) with at least one adjusting hole (3) intended to be fitted on the adjusting head (4) of the support head (5), characterized in that the adjusting hole (3) is formed in the adjusting hole (3). plate (6) which extends beyond the contour of the head (2) in the direction of the longitudinal axis of the die (1) and is connected to the head (2) or die (1) with the possibility of moving at least that part of the positioning plate (6) in which an adjusting hole (3) is formed, this movement being with one degree of freedom in the vertical plane in the direction (a) of the axial axis of the adjusting darkness (4) and the adjusting hole (3). Prefabricated die according to claim 1, characterized in that the positioning plate (6) is flexible, its first end is integrated in the head (2), and its second end provided with the positioning hole (3) is lined from the head (2) with the possibility of pivotal movement within the limits of the elasticity of the plate material (6). Prefabricated die according to Claim 2, characterized in that the positioning plate (6) is made of steel strip. Prefabricated die according to Claim 2 or 3, characterized in that the die (1) and the head (2) are made of reinforced concrete and the positioning plate (6) is inseparably mounted with its first end in the head (2). Prefabricated die according to claim 2 or 3, characterized in that the die is made of reinforced concrete and a metal housing (7) is arranged in the head (2), in which the first end of the positioning plate (6) is accommodated, the metal housing (7) being fastened. ) to heading (2) is detachable or non - detachable. Prefabricated die according to claim 5, characterized in that the first end of the positioning plate (6) is at least partially anchored in the metal housing (7), the free part of the first end of the positioning plate (6) being pivotable. within the limits of the elasticity of the plate material (6) and the inner profile of the metal housing (7). Prefabricated die according to claim 5, characterized in that the first end of the positioning plate (6) is rotatably mounted in the metal housing (7) on the pin (9) or slidably in a sliding slide with the possibility of movement in the vertical direction. Prefabricated die according to claim 6 or 7, characterized in that the first end of the positioning plate (6) has a smaller diameter in the horizontal plane than the inner horizontal diameter of the metal housing (7), the free part of the first end of the positioning plate (6) it is provided with a fixed spacer (10) limiting the horizontal oscillation of the positioning plate (6) in the metal housing (7). Prefabricated die according to Claim 1, characterized in that the positioning plate (6) is fastened to the head (2) with the possibility of pivotal movement. Prefabricated die according to claim 9, characterized in that the positioning plate (6) is connected to at least one arm (8) arranged on the side of the die (1) and rotatably mounted on a pin (9) passing through the die (1). Prefabricated die according to Claim 9 or 10, characterized in that the positioning plate (6) is made of steel strip. Prefabricated die according to one of Claims 1 to 11, characterized in that the positioning opening (3) has an oval or rectangular shape. -9EN 2020 - 708 A3 Prefabricated die according to one of Claims 1 to 12, characterized in that the head (2) has a tooth (12) provided with this positioning plate (6) at its end provided with a positioning plate (6), the tooth (12) being adapted to be mounted on a support head (5) for defining the vertical position of the die (1). Assembly of at least one prefabricated die (1) according to one of Claims 1 to 13 and at least one support head (5) provided with an adjusting mandrel (4), characterized in that the clearance of the adjusting hole (3) is greater than the cross section of the adjusting darkness ( 4), so that the positioning darkness (4) is loosely mounted in the positioning opening (3). Assembly according to claim 14, characterized in that the inner length of the adjusting hole (3) in the direction of the longitudinal axis of the die (1) and the inner width of the adjusting hole in the direction perpendicular to this direction are greater than the outer dimensions of the adjusting darkness (4). in the indicated directions. Assembly according to claim 15, characterized in that the positioning darkness (4) has a circular cross-section, the positioning hole (3) has an oval or rectangular shape, and the clearance of the positioning darkness (4) in the positioning opening (3) is at least 5 mm the entire circumference of the settling darkness (4), in all directions of the horizontal plane. Assembly according to claim 16, characterized in that the play of the positioning darkness (4) in the positioning opening (3) is greater in the direction of the longitudinal axis of the die (1) than in the direction perpendicular to this direction in the horizontal plane. Assembly according to one of Claims 14 to 17, characterized in that n dies (1) according to one of Claims 1 to 13, where n is equal to 2 to 8, are mounted on one support head (5), the positioning plates ( 6) all dies (1) are arranged with their positioning openings (3) on a common positioning darkness (4) so that the end of the plate (6) of each subsequent die (1) is arranged higher on the positioning darkness (4) than the end of the plate (6) ) of the previous die (1). Assembly method according to claim 18, characterized in that the position of the positioning darkness (4) in the support head (5) is geodetically aligned, the positioning darkness (4) is anchored in the support head (5) to the geodetically marked position, and subsequently the dies (1) are gradually fitted with their positioning holes (3) in the positioning plates (6) on the positioning darkness (4) of the support head (5), with correction of their position by moving the dies (1) to the required position within the setting darkness (4) ) in the positioning openings (3) of the plates (6) of the dies (1) so that in the final position the longitudinal axes of the dies (1) intersect the cross-section of the positioning darkness (4), preferably intersect its axis. Assembly method according to claim 19, characterized in that the support head (5) and the dies (1) are dimensioned for a load capacity corresponding to the dead weight of the assembly, after placing on the support head (5) the dies (1) creates precisely directionally oriented and planar base strips at the top. Assembly method according to claim 20, characterized in that a die (1) with a detachably fastened metal housing (7) is used, the metal housing (7) being removed from the die (1) after the concrete (1) has been concreted. Assembly method according to claim 20, characterized in that a die (1) is used with a pivoting positioning plate (6) with two arms (8) on a common pin (9), the positioning plate (6) with arms (8) ) and the pin (9) is removed from the die (1) after concreting the die (1).