RU2119026C1 - Method for erection of monolithic buildings and set of extending, displaceable, tunnel-shape shuttering for realization of method - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: this can be used for erection of monolithic buildings and structures with application of extending three-dimensional displaceable tunnel-shape shuttering. According to method, panels of interstory coverings are mounted with inserts and L-shaped end inserts which are fixed relative to interstory coverings by means of splittable locks. Introduced into wall and side panels are height inserts which respectively change height of tunnel and height of building story. Also installed are turnable clamps which fasten vertical wall and side panels. Application of aforesaid method and shuttering widens technological potentialities of equipment, improves its versatility and quality of buildings and structures being erected, cuts period of erecting monolithic structures and reduces number of auxiliary technological operations. EFFECT: higher efficiency. 3 cl, 7 dwg

Description

 The invention relates to construction technology and equipment and can be used for the construction of monolithic structures and buildings using sliding volumetric-permissible tunnel formwork.

 The closest technical solution in terms of the method is the method of erecting monolithic buildings, including the manufacture of support crowns broken down into grips, the installation of formwork, the placement of wall reinforcement, concrete walling, curing concrete in the formwork before hardening, dismantling the formwork and repeating the technological cycle. The method is characterized in that prior to the installation of the formwork, scaffolds are mounted around the entire perimeter of the building’s erected floor, the embedded parts are placed in the form of concrete crosses made separately according to the thickness of the walls and the height of the floor and the communication networks are mounted, and after the formwork is installed in the form of half tunnels, the floor reinforcement is placed and exposed the design position of the half-tunnel vertically and horizontally, while concreting the ceiling is carried out after concreting the walls, and after dismantling the formwork on the previous grab it restavlyayut the subsequent zahvatki (see. RF Patent N 2079618, E 04 G 11/20, E 04 B 1/16, 1997).

 Tunnel formwork for erecting monolithic buildings is known from the patent literature, including prefabricated formwork L-shaped half-tunnels that form a tunnel in a paired position, embedded elements, panel fastening elements in joint with each other, adjustable length struts and formwork moving rollers (see patents France N 2432073; 2504580; E 04 G 11/02, publ. 1980, 1982; Germany patents N 2426126, 2530756; 2620124, E 04 G 11/02, 1975, 1977, 1976).

 The closest technical solution is a set of volumetric climbing tunnel formwork, containing tunnel formwork for one grab, including prefabricated formwork L-shaped half-tunnels and L-shaped panels with an end, forming tunnels in a paired position, embedded elements, joint fastening elements among themselves, struts of adjustable length and supporting channel beams for the rigidity of the panels, which make up the formwork stabilization system and auxiliary equipment - scaffolding. The embedded elements are made in the form of concrete crosses installed between the half-tunnels and exposed at the top, the width of which corresponds to the wall thickness, and the height to the height of the building ceiling.

 The supporting parallel channel stiffness beams of vertical board stiffness, reinforced by the longitudinal walls of channels on the shields and installed with a gap relative to each other, are equipped at the junctions of vertical boards with a clamping device in the form of additional inserts of channel sections of a smaller size, located on both sides of the joined boards inside the stiffeners and fastened interconnected detachable connections. The fastening elements of the ceiling panels to each other at the junction are made in the form of a pair of retainer bolts with a heel, mounted on opposite sides of the panels to be joined, and the heel is equipped with a mounting pin inserted into the corresponding groove of the shield and stabilizing the axial distance between the fixing bolts with the fixing element, and the scaffold installed at the same level around the perimeter of the building (see RF patent N 2078180, E 04 G 11/20, 1997).

 The proposed set of expandable, volumetric-permissible tunnel formwork is illustrated by drawings, where in FIG. 1 shows a general view of a sliding volumetric tunnel tunnel formwork; in FIG. 2 - L-shaped insert for changing the width of the tunnel formwork; in FIG. 3 - connection of a high-altitude insert with wall panels of sliding half-tunnels; FIG. 4 is the same as in FIG. 3 without lining; in FIG. 5 - coupling detachable devices; FIG. 6 is the same as in FIG. 5, top view; in FIG. 7 - dismantling of sliding half tunnels.

 The method of erecting monolithic buildings includes the manufacture of support crowns broken down into grips, installation of scaffolds around the entire perimeter of the erected floor of the building, placement of embedded parts in the form of concrete crosses made separately for wall thickness and height of the ceiling, and installation of communication networks, installation of formwork in the form of half tunnels, placement of reinforcement walls and ceilings and putting in the design position of the tunnels vertically and horizontally, concreting walls and ceilings, curing concrete in the formwork until it hardens, dismantling the formwork, installation on the subsequent capture and the repetition of the technological cycle. The method is characterized in that the floor panels are mounted with inserts and L-shaped end inserts, which are fixed relative to the floors with detachable locks, and high-rise inserts are installed in the wall and end panels, changing the tunnel height as desired and fastening the vertical panels with rotary brackets.

 The proposed set of sliding volumetric-permissible tunnel formwork, implementing the above method, comprises type-setting formwork L-shaped half-tunnels and L-shaped panels with an end face for one gripper, forming a tunnel in the assembled position. The kit also contains embedded elements made in the form of concrete crosses installed between the half-tunnels and exposing them along the top, the width of which corresponds to the wall thickness and the height to the height of the building ceiling. The tunnel formwork stabilization system is made in the form of strapping, installation strips, struts of adjustable length and load-bearing beams for the rigidity of the shields. The kit contains coupling detachable devices installed in the joints of vertical, L-shaped panels, and fastening elements of ceiling panels to each other at the junction, and auxiliary equipment - scaffolds installed around the perimeter of the structure.

 The set of sliding volumetric-permissible tunnel formwork is distinguished by the fact that it is equipped with an insert in the ceiling-end shields with detachable locks that change the width of the tunnel, and the inserts are equipped with traverses located on the inside along the entire length of the inserts, racks with running rollers, lifting screws, latches and mounting struts. The kit contains high-altitude inserts on the wall and end shields that change the height of the tunnel, which are equipped with connecting inserts made in the form of dowels with detachable fasteners and linings with detachable connections and mounted on the upper end of the shield and installed in the groove on the end of the lower shield.

 The coupling detachable devices of the vertical shields are made in the form of a bracket rotatable on the axis of the bracket on one side and with an adjustable stop on the other side of the bracket, covering the strands of panels with the mounting brackets that are joined together.

 Achievable technical result of the claimed invention is to expand the technological capabilities of the equipment used, to increase its versatility and quality of structures being erected, as well as to reduce the time of construction of monolithic structures, reducing the number of auxiliary technological operations.

 The technological process is carried out as follows: scaffolding is installed, formwork is mounted and mortgages are installed. Next, the communication networks are mounted alternately with the installation of half tunnels and inserts, the formwork is installed vertically and horizontally. They carry out the installation of reinforcement for concreting the floor and lay the details - concrete crosses. Mount communication networks on the ceiling and carry out concreting. Carry out the dismantling and installation of formwork on a new grab and installation of embedded parts on prepared scaffolds. Further, the technological cycle is repeated.

 The set of sliding, volume-permissible tunnel formwork contains type-setting formwork L-shaped sliding half-tunnel shields 1, L-shaped boards with an end face 2 with high-altitude inserts 3 and an insert 4 and an L-shaped insert 5 and ceiling (overlapping) shields forming in the assembled the position of the tunnel (see Fig. 1). The formwork contains a stabilization system, including struts 6 of adjustable length, racks 7 with track rollers 8 and lifting jacks 9, a crossbar 10 and a crosshead 11 for lifting the insert. In the L-shaped insert, a hole 12 for the eyebolt is made (not shown in FIG. 2). Embedded elements (not shown in the drawing) installed between the half tunnels and exhibiting them at the top are made in the form of concrete crosses, the width of which corresponds to the thickness of the wall 13 (Fig. 5), and the height to the height of the ceiling of the structure. As auxiliary equipment, roll-out scaffolds 14 with a boardwalk and a folding guard 15 (see Fig. 5) are used, installed at the same level along the entire perimeter of the structure.

 High-altitude inserts 3 on the wall and end panels with channel ties 16 change the height of the tunnel (see Fig. 3 and 4). They contain connecting inserts made in the form of a key 17 with detachable fastening elements 18 and plates 19 with detachable connections and mounted on the upper end of the shield and installed in the groove on the end of the lower shield 1.

 Coupling detachable devices (see FIGS. 5 and 6) of the vertical shields of the L-shaped half-tunnels 1 are made in the form of a bracket 21, which is rotatable on the axis 20, on one side and with an adjustable stop 22 on the other side of the bracket 21, covering the strands 23 connected to each other slats.

 The insert 4 for changing the width of the tunnel consists of a ceiling shield (overlap) with two-way clamps (not shown in Fig. 1) for fastening with an L-shaped half-tunnels of the end shield, racks with lifting screws 9 and sprockets 8 for dismantling the insert, crosshead 11 for lifting insert.

 Insert 5 (see Fig. 2) is directly attached to one of the half-tunnels and is dismantled with it. Insert 5 consists of a ceiling shield with two rows of retainers (not shown in the drawings) for attaching it to the main half-tunnels of the end shield. Box 3 (see Fig. 1) serves to change the height of the floor compared with the standard, is installed on the wall and end shields. Insert 3 consists of a wall element with connectors, fasteners and plates with bolts (see Fig. 3 and 4).

 In FIG. 5 shows the dismantling of sliding half tunnels. The second part of the half-tunnel A is dismantled in the second turn, and the first part of the half-tunnel B. is dismantled first. The half-tunnel is rolled out onto the boardwalk B of the withdrawable scaffolds with frame G and hinged guards 15.

Claims (3)

 1. A method of erecting monolithic buildings, including the manufacture of support crowns broken down into grips, installation of scaffolds around the entire perimeter of the erected floor of the building, placement of embedded parts in the form of concrete crosses made separately by the thickness of the walls and the height of the ceiling, and installation of switching networks, installation of formwork in the form of half tunnels , placement of reinforcement of walls and ceilings, and vertical designing of half-tunnels, concreting of walls and ceilings, curing of concrete in the formwork until hardening I, dismantling the formwork, installing it on the next grab and repeating the technological cycle, characterized in that the floor panels are mounted with inserts with L-shaped end inserts, which are fixed relative to the floors with detachable locks, and high-rise inserts are installed in the wall and end panels, changing accordingly the height of the tunnel and floors of the building and swing brackets fastening vertical wall and end shields.  2. A set of sliding volumetric-permutable, tunnel formwork, comprising prefabricated formwork L-shaped half-tunnel shields and L-shaped boards with an end face for one gripper, forming a tunnel in the assembled position, embedded elements made in the form of concrete crosses installed between half-tunnels and exhibiting them along the top, the width of which corresponds to the wall thickness, and the height to the height of the ceiling of the structure, struts of adjustable length and load-bearing beams for the rigidity of the shields that make up the stabilization system of tunnel formwork, coupling detachable devices installed in the joints of vertical, L-shaped panels, and elements for fastening ceiling panels to each other at the junction and auxiliary equipment - scaffolds installed around the entire perimeter of the building under construction, characterized in that the kit is equipped with an insert and a L-shaped insert in ceiling shields with detachable locks that change the width of the tunnel, and the inserts are equipped with a traverse located on the inside along their entire length, racks with running rollers, lifting screws and mounting braces high-altitude inserts on wall and end shields with channel ties that change the height of the tunnel, which contain connecting inserts made in the form of dowels with detachable fasteners and linings with detachable connections and mounted on the upper end of the shield and installed in the groove on the end of the lower shield.  3. The kit according to claim 1, characterized in that the coupling detachable devices of the vertical shields are made in the form of a swivel on the axis of the bracket on one side and with an adjustable emphasis on the other side of the bracket, covering the strands of panels that are joined together, with the mounting brackets.

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