RU201330U1 - STAND FOR TENSION OF STEEL ROPES AND TESTING OF PRE-STRESSING ELEMENTS OF BUILDING STRUCTURES - Google Patents

Abstract

The utility model relates to the field of construction and can be used for tensioning steel ropes, in particular, reinforcing ropes and testing prestressing elements of building structures. The technical result is the creation of a mobile compact structure based on a metal frame, eliminating the need for a strong foundation that allows loading the stand into a car. railway or air transport of appropriate carrying capacity, transport it to another construction site, unload, assemble and prepare for work. The stand for tensioning steel ropes and testing prestressing elements of building structures includes a steel frame 1, a pumping station 2, high-pressure hoses 3 and electrical equipment 4, frame 1 contains longitudinal ledgers 5, extending from them on both sides of the frame 1 inclined ledgers 6 and fixed at the ends of the inclined ledgers 6 perpendicular to them horizontal paired beams 7, perpendicular to the longitudinal ledgers 5 are made with Connecting them 8, at both ends of the frame 1 steel plates 9 are attached to the shelves of the paired beams 7, to which the wedge plates 10 and hydraulic jacks 11 are attached, in the middle part of the frame there is a docking device - a coupler 12, steel ropes 13, wedge collet clamps 14 , lugs 15, supports 16. 4 C.p. f-ly, 7 ill.

Description

The claimed technical solution relates to the field of construction and can be used for tensioning steel ropes, in particular reinforcing ropes and testing prestressing elements of building structures.

Known stand for tensioning reinforcement ("Machinery and equipment for the production of prefabricated reinforced concrete. Industry catalog. Moscow, 1983" page 340-343 stand SMZH-338A), including a frame with fixed and movable grips placed on it, a pumping station and electrical equipment. The disadvantage of this stand is that it is stationary, not mobile and cannot be moved to another place without destroying part of its structure, due to the fact that its frame is monolithic into the foundation, which is an integral part of the stand structure and takes loads from the tension of the reinforcement.

The task of the proposed technical solution is to increase the mobility of the stand, to ensure the possibility of moving it from one construction site to another. The technical result is the creation of a mobile compact structure based on a metal frame, which eliminates the need for a powerful foundation, into which the elements of the stand are embedded, allowing the stand to be loaded into a road, rail or air transport of the corresponding carrying capacity, transported to another construction site, unloaded, assembled and prepared for work.

The specified technical result is achieved by the fact that the stand for tensioning steel ropes and testing prestressing elements of building structures includes a steel frame, a pumping station, high-pressure hoses and electrical equipment, the frame contains longitudinal girders, inclined girders extending from them on both sides of the frame and fixed at the ends of the inclined crossbars perpendicular to them, horizontal paired beams, perpendicular to the longitudinal crossbars, connecting ties are made, at both ends of the frame, steel plates are attached to the flanges of the paired beams, to which wedge plates and a hydraulic jack are attached, in the middle part of the frame there is a docking device - a coupler for steel ropes that are pulled through a coupler, wedge plates and hydraulic jacks and secured with wedge collet clamps, the frame has lugs fixed in the upper part to the longitudinal and inclined girders for installing the stand supports on the platform with a crane, and the supports are made in the lower part of the frame and attached to the braces and to the inclined beams, also the holes in the steel plates are made in the center of the plate, with conical expanding parts facing outward from the frame, also the longitudinal beams and inclined beams are made in mutually perpendicular planes, also the longitudinal beams connecting their connections, inclined crossbars and beams are made of I-profile, the frame is also collapsible, consisting of end and middle sections, on the longitudinal crossbars of which there are flanges with holes for bolts.

The claimed technical solution is illustrated by a drawing, where in FIG. 1 shows a longitudinal section of a stand for tensioning steel ropes and testing prestressing elements of building structures, the frame of which is made all-welded, in Fig. 2 shows a top view of a stand for tensioning steel ropes and testing prestressing elements of building structures, FIG. 3 shows a side view of a stand for tensioning steel ropes and testing prestressing elements of building structures, FIG. 4 shows a perspective view of a stand for tensioning steel ropes and testing prestressing elements of building structures; FIG. 5 shows the bolted flanges on the longitudinal girders of the frame; FIG. 6 shows a steel plate with a tapered bore, a wedge plate and a hydraulic jack; FIG. 7 shows a docking device (coupler) with steel ropes extending from it.

A stand for tensioning steel ropes and testing prestressing elements of building structures includes a steel frame 1, a pumping station 2, high-pressure hoses 3 and electrical equipment 4, frame 1 contains longitudinal girders 5 extending from them on both sides of the frame 1 inclined girders 6 and fixed at the ends inclined girders 6 perpendicular to them horizontal paired beams 7, perpendicular to the longitudinal girders 5 are made connecting them 8, at both ends of the frame 1 steel plates 9 are attached to the shelves of the paired beams 7, to which the wedge plates 10 and hydraulic jacks 11 are attached, in the middle part of the frame a docking device is installed - a coupler 12, steel ropes 13, wedge collet clamps 14, lugs 15, supports 16, holes 17 are made in the center of steel plates 9, with conical expanding parts facing outward from the frame 1, longitudinal girders 5 connecting their connections, inclined girders 6 and beams 7 are made of an I-section, frame 1 is made prefabricated boron, consisting of end 18 and middle sections 19, on which flanges 20 with holes for bolts 21 are made.

Stand for tensioning steel ropes and testing prestressing elements of building structures works as follows. On a flat solid platform, for example, on a concreted platform 22 with a crane using lugs 15, a frame 1 is installed, next to which a pumping station 2 and electrical equipment are placed 3. From the ends of the frame 1, wedge plates 10 and hydraulic jacks 11 are connected to the steel plates 9, in the middle part of the frame 1, a docking device 12 (coupler) is installed for the steel ropes 13. Through the central holes of the coupler 12, the wedge plate 10 and the hydraulic jack 11, the steel ropes 13 are pulled to one side of the frame 1, and through the peripheral holes of the coupler 12, the wedge plate 10 and the hydraulic jack 11 pulls the steel ropes 13 to the other side of the frame 1. The steel ropes 13 in the coupler 12 and the wedge plates 10 are fixed with wedge collet clamps 14. With the help of the pumping station 2, hydraulic fluid is supplied through the high-pressure hoses 3 to the hydraulic jacks 11, which create tension steel ropes 13 and stresses in wedge plates 10 and kupler 12. Stressed o-deformed states in wedge plates 10, coupler 12 and steel ropes 13 are recorded by sensors of various types, for example, frequency-type devices. If it is necessary to tension steel ropes of great length, a collapsible frame 1 is used. End sections 18 and middle sections 19 are installed on a concreted platform 22 and connected to each other by means of flanges 20 with bolts 21.

The proposed stand design for tensioning steel ropes and testing prestressing elements of building structures is mobile and compact. There is no need for a strong foundation in the proposed stand design, since the tension forces of the ropes are closed on the frame of the stand and are not transmitted to the foundation, therefore, it is enough just to install the stand on a level platform. The proposed design of the stand for tensioning steel ropes and testing prestressing elements of building structures allows you to move it with a solid or collapsible frame from one construction site to another by various modes of transport (road, rail, aviation).

Claims (5)

1. The stand for tensioning steel ropes and testing prestressing elements of building structures includes a steel frame, a pumping station, high-pressure hoses and electrical equipment, the frame contains longitudinal girders, inclined girders extending from them on both sides of the frame and horizontal paired girders fixed at the ends of the inclined girders perpendicular to them beams, perpendicular to the longitudinal girders, connecting ties are made, at both ends of the frame, steel plates are attached to the flanges of the paired beams, to which wedge plates and a hydraulic jack are attached, in the middle of the frame a docking device is installed - a coupler for steel ropes that are pulled through the coupler, wedge plates and hydraulic jacks and secured with wedge collet clamps, the frame has lugs fixed in the upper part to the longitudinal and inclined girders for installing the stand supports on the platform with a crane, and the supports are made in the lower part of the frame and attached to the ties and to the slope girders. 2. A stand for tensioning steel ropes and testing prestressing elements of building structures according to claim 1, characterized in that the holes in the steel plates are made in the center of the plate, with conical expanding parts facing outward from the frame. 3. A stand for tensioning steel ropes and testing prestressing elements of building structures according to claim 1, characterized in that the longitudinal girders and inclined girders are made in mutually perpendicular planes. 4. A stand for tensioning steel ropes and testing prestressing elements of building structures according to claim 1, characterized in that the longitudinal girders connecting their ties, inclined girders and beams are made of an I-profile. 5. Stand for tensioning steel ropes and testing prestressing elements of building structures according to claim 1, characterized in that the frame is collapsible, consisting of end and middle sections, on longitudinal girders of which flanges with bolt holes are made.

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