RU204002U1 - Supporting building structure - Google Patents

Abstract

PURPOSE: The utility model is used in construction as formwork, as well as scaffolding. SOLVED PROBLEM: expanding the functionality of the supporting building structure due to the possibility of adjusting the longitudinal and lateral stability by means of the location of additional universal elements in a wide range of angles and fixation on any part of the main element between the cup nodes. ESSENCE OF THE USEFUL MODEL: in a supporting building structure, including a bearing surface and formed by main vertical elements and main horizontal elements with tips in the form of wedges at the ends, connected to each other by means of cup attachment points, each of which is made in the form of two counterparts, the lower fixed, mounted on the corresponding vertical element, and the upper, installed with the ability to move along the vertical element, as well as including additional connecting elements, it is proposed to make additional connecting elements universal, for which each of them is provided at the ends with a clamp for fixing on any located between cup nodes, a section of the main element at an angle to it within the range from 0º to 180º. In this case, at least one universal element can be fixed simultaneously on the main vertical element and on the main horizontal element. At least one universal element can be fixed between two adjacent vertical elements. At least one universal element can be fixed between two adjacent horizontal elements. Each clamp can contain two steel clamping parts in the form of brackets, connected on one side with a clip latch, and on the other side with a bolt with a nut, as well as a steel screw welded to one of the brackets, while the clamp is installed with the possibility of rotation around the screw axis at an angle from 0º to 180º.

Description

The utility model relates to construction and can be used in formwork structures for the construction of buildings and structures with cast concrete floors, as well as as scaffolding for general construction and facade works.

Formwork is a temporary form for the construction of concrete and reinforced concrete structures, which is built right on the site of construction work. Slab formwork made of wedge-shaped scaffolding elements is a hinged frame structure made of vertical and horizontal elements.

Known supporting building structure, described in patent RU No. 137046 - floor formwork containing a set of mounted on jacks composite vertical struts made of pipes and equipped on the opposite side of the jacks with height-adjustable stops, and mounted with the formation of a quadrangle horizontal hollow crossbars, equipped at the ends welded tips with paired wedges diverging at an obtuse angle for installing one of them in the lower bowl welded to the vertical post, made with conical outer and inner side surfaces, and fixing the second wedge to the post with the upper bowl movable along and around the post with the possibility of fixing made in with a groove to a rod welded to the rack in the longitudinal direction, and the tips are made with a conical truncated central part facing the inside of the horizontal crossbars, and the wedges are made with a convex outer surface to mate with a concave inner surface upper and lower bowls and with a concave inner surface for mating with the surface of the vertical posts, with ledges welded to the edges of the horizontal beams on the tips.

The disadvantage of the known formwork is the limited functionality of the formwork and attachment points, which leads to insufficient rigidity of the structure and low longitudinal and vertical stability, and, consequently, to a change in the geometric shape of the structure, its distortion and collapse, especially when it is erected over a wide installation area, when the principle of distribution of loads due to horizontal ties is not effective enough.

The closest technical solution, chosen as the closest analogue, is a supporting building structure - cup-type floor formwork according to RU patent No. 140596, containing the main elements - vertical elements and horizontal elements containing wedge-shaped ends at the ends, supporting elements, beams, formwork a shield, a cup assembly for attaching horizontal elements to vertical ones, made in the form of two mating parts, the lower fixed, mounted on the vertical element, and the upper, mounted with the ability to move in the upper part along the height of the vertical element, each equipped with an inner surface, which is described by the equation of the body surface rotation or its derivative, characterized in that it additionally contains diagonal connecting elements installed in a vertical plane, in an arbitrary order in length and height from the outside of the mounted frame structure, formwork, and containing formwork at the ends tips in the form of wedges, with the possibility of their rotation relative to the diagonal element along the axis of attachment of this element and the wedge, intended for clamping between the lower attachment point and the upper attachment point.

The disadvantage of this useful model is the limitation of the functionality of the supporting building structure, since additional diagonal elements can be fixed only in the cup attachment points of the main horizontal elements to the main vertical elements, which limits the range of angles between the main elements and additional ones. In addition, the introduction of additional diagonal elements into the structure using the same cup principle of fastening to a vertical element as horizontal elements, although it simplifies the installation of the structure, however, complicates the cup assembly itself and reduces its reliability.

The objective of the claimed utility model is to expand the functionality of the supporting building structure due to the possibility of adjusting the longitudinal and lateral stability by means of the arrangement of additional universal elements in a wide range of angles and fixation on any part of the main element between the cup assemblies.

The technical result is to expand the functionality and use of the supporting building structure both in the form of formwork and in the form of scaffolding, that is, both for performing work on the installation of horizontal monolithic structures, and for work inside and outside the premises with the placement of workers and building materials on steel scaffolding decks. Such unification is achieved due to the introduction of universal elements into the structure with clamps at the ends, which do not limit the possibility of positioning universal elements only obliquely (diagonally), but allow them to be located in a wide range of inclination angles from 0º to 180º and vertically and horizontally, which increases the stability of the structure while increasing reliability.

The essence of the utility model lies in the fact that in the supporting building structure, including the bearing surface and formed by the main vertical elements and the main horizontal elements with tips in the form of wedges at the ends, connected to each other by means of cup attachment points, each of which is made in the form two mating parts, the lower fixed, mounted on the corresponding vertical element, and the upper, installed with the ability to move along the vertical element, and also including additional connecting elements, it is proposed to make additional connecting elements universal, for which each of them must be provided at the ends with a clamp for fixing on any section of the main element located between the cup nodes at an angle to it within the range from 0º to 180º.

At least one universal element can be fixed simultaneously on the main vertical element and on the main horizontal element. In this case, the universal element can be fixed, for example, at an angle ranging from 5º to 85º.

At least one universal element can be fixed between two adjacent vertical elements. In this case, the universal element can be fixed, for example, at an angle ranging from 0º to 40 º or from 140 º to 180º.

At least one universal element can be fixed between two adjacent horizontal elements. In this case, the universal element can be fixed, for example, at an angle ranging from 50º to 130 º.

Each clamp can contain two steel clamping parts in the form of brackets, connected on one side with a clip latch, and on the other side with a bolt with a nut, as well as a steel screw welded to one of the brackets, while the clamp is installed with the ability to rotate around the axis of the screw at an angle from 0º to 180º.

At least two main horizontal elements connected by a cup attachment point can be located in a horizontal plane relative to each other at an angle ranging from 90º to 270º inclusive.

At least three main horizontal elements connected by a cup attachment point can be located in a horizontal plane relative to each other at an angle ranging from 90 º to 120 º inclusive.

The bearing surface can be made in the form of a shuttering board.

The bearing surface can be made in the form of a steel deck.

The load-bearing surface can be designed so that one part of it is the deck, and the other part is the shuttering board.

The steel deck can be fitted with a ladder.

The main and additional connecting elements can be made in the form of pipes of a circular cross-section, while the main vertical elements can be interconnected using sections of a steel pipe of a square section with a diagonal size corresponding to the inner diameter of the vertical elements, and in the middle part of each section of a steel pipe perpendicularly a steel plate is welded to its side surface.

Figure 1 shows a general view of the supporting building structure.

Fig. 2. shows an adjustable base, general view.

Figure 3 shows the unilka, general view.

Figure 4 shows a connecting element in the form of a piece of square pipe connected to a vertical element, on which a cup attachment unit is installed for fixing three horizontal elements at an angle of 120 ° to each other, general view, top view.

Figure 5 shows a steel deck, General view.

Figure 6 shows a universal element with clamps at the ends, general view.

Figure 7 shows a universal element with a yoke, cross-section.

Figure 8 shows an example of the arrangement of universal elements vertically, horizontally and diagonally, a general view of the supporting building structure.

Figure 9 shows an example of the arrangement of universal elements vertically, horizontally and diagonally, a general view of a fragment of a supporting building structure.

Figure 10 shows an example of the arrangement of universal elements diagonally in the horizontal plane, top view.

The proposed supporting building structure, shown in Fig. 1, contains vertical elements 1, horizontal elements 2, connecting elements 3 in the form of a section of a steel pipe of square section, universal elements 4, adjustable bases 5, univilki 6, steel decks 7, formwork shield 8, ladder 9.

The vertical elements 1 are the main load-bearing elements of the supporting building structure in the vertical plane. They are joined together vertically according to the "pipe-to-pipe" principle with the help of connecting elements 3. Connecting element 3 is a steel pipe 17 of square cross-section with a diagonal size not exceeding the inner diameter of the pipe of the vertical element 1, and a steel plate 18 located in the middle of the steel pipe 17 perpendicular to its lateral surface, Fig. 4.

Vertical elements 1, horizontal elements 2 and universal elements 4 are made in the form of pipes of circular cross section. To connect horizontal elements 2 with vertical elements 1, cup attachment points are used, each of which is made in the form of two mating parts 11, 12, Fig. 4. The lower parts of the 11 cup attachment points are fixedly mounted on vertical elements 1 with a constant step multiple of a given value, which is determined depending on the axial load. The upper part 12 of each cup attachment unit is installed with the ability to move along the corresponding vertical element 1 and is made with the possibility of fixing the horizontal elements 2. A hammer blow on the upper part 12 of the attachment unit fixes the horizontal connection in the working position . The lower part 11 of the cup attachment can be made, for example, of structural alloy steel, which increases the vertical stability of the supporting building structure.

The horizontal element 2 shown in Fig. 4 includes a pipe 15 of circular cross-section, with a diameter equal to the diameter of the pipe of the vertical element 1, with wedge-shaped tips 16 located at the ends. The fixation of the horizontal elements 2 on the vertical element 1 is carried out by clamping the tips 16 between the lower 11 and upper 12 parts of the cup attachment unit.

Two horizontal elements fixed by a cup attachment unit have a degree of freedom in the horizontal plane relative to each other in the range of angles from 90º to 270º. Three horizontal elements fixed by a cup attachment unit have a degree of freedom in the horizontal plane relative to each other in the range of angles from 90º to 120º. This range of angles is determined by the dimensions of the tips of 16 horizontal elements 2, while using one cup attachment of the vertical element 1, a maximum of four horizontal elements 2 can be fixed, each horizontal element 2 is located at an angle of 90 ° to the vertical element 1.

In the upper part of the structure, unilk 6 are installed. The unilk 6 consists of a circular tube 22 with a trapezoidal thread, a nut 23 with a trapezoidal thread, a steel plate 25 and square tubes 26, FIG. 3. Unilk 6 act as a threaded jack and are intended for fixing the formwork panel 8, for adjusting the height and leveling the formwork flatness.

The universal element 4 consists of a pipe 19 of circular cross-section with clamps at the ends for fixing (fixing) on any section of the main element (vertical element 1 or horizontal element 2) located between the cup nodes, at an angle to it within the range from 0º to 180º. Each clamp is made in the form of brackets 20 and 32 and a screw 21 welded to the clamp connecting the bracket 32 with a pipe 19 of circular cross-section, Fig. 6.

The clamp contains two steel clamping parts in the form of brackets 20 and 32, connected on one side with a latch-clip, and on the other side with a bolt 30 with a nut 31, as well as a steel screw 21 welded to the bracket 32 so that the clamp rotates 180º around the axis of the screw 21. The clamp is designed for fixing the universal elements 4 on the horizontal elements 1 and vertical elements 2. The clamping force is regulated by the bolt connection. The clamp is fixed on the pipe 19 of the universal element 4 with the screw 21. When pressure is applied to the vertical element 1, the load is transferred to the pipe 19 of the universal element 4, then to the screw 21 of the universal element 4 and then to the main element 1 or 2, thereby distributing the load. Such fixation of the universal element 4 allows to increase the stability of the structure and provides the ability to adjust the angle of inclination of the universal element 4 relative to the main element 1 or 2 in a wide range from 0º to 180º inclusive.

The universal element 4 has the ability to be fixed in a vertical, horizontal and diagonal position, FIG. 8. The universal element 4 in the process of installation has the ability to move along the cylindrical surface of the vertical and horizontal elements 1 and 2.

The universal element 4 can be fixed simultaneously on the main vertical element and on the main horizontal element, for example, taking into account the presence of a cup attachment unit at an angle ranging from 5º up to 85º, fig. 9.10.

The universal element 4 can be fixed between two adjacent vertical elements, for example, taking into account the presence of a cup attachment unit at an angle ranging from 0º to 40º or from 140º to 180º, Fig. 8.

A universal element can be fixed between two adjacent horizontal elements, for example, taking into account the presence of a cup attachment unit at an angle ranging from 50º to 130º, Fig. 8.

Due to such an attachment, the load is distributed between the vertical 1 and horizontal 2 elements, as well as the stability of the supporting building structure is increased, which provides an expansion of the functionality of the supporting building structure.

The adjustable base 5 consists of a circular tube 22 with a trapezoidal thread, a nut 23 with a trapezoidal thread and a steel plate 24, FIG. 2. The adjustable base 5 is designed to align the vertical elements 1 in height with respect to each other and to ensure the horizontal flatness of the formwork. The adjustable base can be attached to a supporting base, for example, to the floor, since it includes a plate 24 with holes.

Steel deck 7 provides accommodation for workers and construction materials. The steel deck consists of beams 27 with hooks 28 at the ends for attachment to horizontal elements 2, and a deck 29 of perforated sheet metal, FIG. five.

Formwork shield 8 is made of any material that provides the required rigidity, and is a form-building element to which the concrete adjoins during concreting in the case of using the proposed supporting building structure as a formwork, Fig. one.

The ladder 9 is made of circular pipes and a railing made of rolled sheet metal, Fig. 1. The ladder 9 is attached to the horizontal elements 2 using hooks located at the ends of round pipes. On the horizontal elements 2, it is possible to arrange a steel deck 7 and an extension ladder 9, since the universal elements 4 increase the longitudinal stability of the supporting building structure.

The proposed supporting building structure, depending on the problem to be solved and the required load capacity, is completed as a formwork or as a scaffold, or as a scaffolding from the required number of vertical basic elements 1, horizontal basic elements 2, universal elements 4, as well as univilok 6, connecting elements 3 and support elements 5.

For concrete pouring of horizontal reinforced concrete structures, formwork is used, mounted on a support base, shown in Fig. 1, in which stiffeners are placed to distribute loads from horizontal reinforced concrete structures: main vertical elements 1, main horizontal elements 2 and universal elements 4.

For the installation of reinforcement before concreting reinforced concrete structures, an assembly site for the working personnel is required. Steel deck 7 is used as an assembly platform. In order to climb to the mounting platform, a ladder 9 is used, Fig. 1.

For work at a height inside and outside the premises under construction with the placement of working personnel, an adjustable base 5, an assembly site and fences are required to ensure the safety of work. Vertical elements 1 are stacked on top of each other, fixed by connecting element 3, thereby increasing in height. Horizontal elements 2 are connected to vertical elements 2 using cup attachment points, and universal elements 4 are fixed with clamps between the main elements 1, 2. Steel decks 7 and ladders 9 are installed on each tier, and universal elements 4 can, for example, be installed as a handrail for the safety of movement of workers on the supporting building, FIG. five.

Thus, the proposed utility model allows you to expand the functionality of the supporting building structure and use it both in the form of formwork and in the form of scaffolding, that is, both for performing work on the installation of horizontal monolithic structures, and for work inside and outside the premises with the placement of a worker. personnel and building materials on steel scaffolding decks. Such unification is achieved due to the introduction of universal elements into the structure with clamps at the ends, which do not limit the possibility of positioning universal elements only obliquely (diagonally), but allow them to be located in a wide range of inclination angles from 0º to 180º and vertically and horizontally, which increases the stability of the structure while increasing reliability.

Claims (12)

1. Supporting building structure, including the bearing surface and formed by the main vertical elements and the main horizontal elements with tips in the form of wedges at the ends, interconnected by means of cup attachment points, each of which is made in the form of two counterparts, the lower fixed, installed on the corresponding vertical element, and the top, installed with the ability to move along the vertical element, as well as including additional connecting elements, characterized by the fact that the additional connecting elements are made universal, for which each of them is equipped at the ends with a clamp for fixing on any section of the main element located between the cup nodes at an angle to it within the range from 0º to 180º. 2. The supporting building structure according to claim 1, characterized in that at least one universal element is fixed simultaneously on the main vertical element and on the main horizontal element. 3. The supporting building structure according to claim 1, characterized in that at least one universal element is fixed between two adjacent vertical elements. 4. The supporting building structure according to claim 1, characterized in that at least one universal element is fixed between two adjacent horizontal elements. 5. The supporting building structure according to claim 1, characterized in that each clamp can contain two steel clamping parts in the form of brackets, connected on one side by means of a clip latch, and on the other side by means of a bolt with a nut, as well as a steel screw welded to one of the brackets, while the clamp is installed with the ability to rotate around the screw axis at an angle from 0º to 180º. 6. The supporting building structure according to claim 1, characterized in that at least two main horizontal elements connected by a cup attachment point are located in a horizontal plane relative to each other at an angle ranging from 90 ° to 270 ° inclusive. 7. The supporting building structure according to claim 1, characterized in that at least three main horizontal elements connected by a cup attachment point are located in a horizontal plane relative to each other at an angle in the range from 90 º to 120 º. 8. The supporting building structure according to claim 1, characterized in that the supporting surface is made in the form of a shuttering board. 9. The supporting building structure according to claim 1, characterized in that the supporting surface is made in the form of a steel deck. 10. The supporting building structure according to claim 1, characterized in that the supporting surface is made in such a way that one part of it is a flooring, and the other part is a shuttering board. 11. The supporting building structure according to claims 9, 10, characterized in that the steel deck is equipped with a ladder. 12. The supporting building structure according to claim 1, characterized in that all the main and additional connecting elements are made in the form of circular pipes, while the main vertical elements are interconnected by means of square steel pipe sections with a diagonal size corresponding to the inner diameter of the vertical elements, and in the middle part of each piece of steel pipe, a steel plate is welded perpendicular to its lateral surface.

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