SU1728718A1 - Stand for testing constructions - Google Patents

Description

The invention relates to testing equipment, in particular, to stands for testing structures under cyclic loading.

A stand for testing structural strength is known, comprising a base with a power frame mounted thereon, including a stand and a crossmember connected thereto, and a loading hydraulic cylinder connected to the cross member. It allows studies of the static and fatigue strength of small rigid structures.

However, the well-known stand does not provide for testing compliant structures, since the rigid force frame does not change its shape following the deformation of the loaded structure. In addition, when the structure under test is deformed, the axis of the loading cylinder deviates from the initial position, which causes errors in the stress-strain state of the structure.

Closest to the present invention is a stand for testing structures containing a base (force field) with power frames installed on it, each of which includes a stand and a cross member connected to it, and associated with the crossbars of the corresponding frame pair located in the same plane of the loading cylinders .

The bench provides testing of both small and large rigid structures for static and cyclic loads.

However, it does not ensure the testing of malleable structures, as in it the rigid force frame does not change its shape together with the tested structure, and errors also arise due to the deviation from the initial position of the axes

corresponding loading cylinders,.

The aim of the invention is to extend the functionality by

ensuring tests of not only rigid, but also malleable structures, increasing the accuracy when testing malleable structures by eliminating errors resulting from deviations from the initial position of the axes of the corresponding loading hydraulic cylinders.

This goal is achieved by the fact that the stand is equipped with pairs of tg, one end of each pull rod is pivotally connected to the corresponding end of the crossmember, and the other is rigidly connected to the stem of the corresponding main hydraulic cylinder, the main hydraulic cylinders are hinged on the base, and the connection of each rack and corresponding the cross member is made in the form of an additional loading cylinder that is installed coaxially with this crossbar, is pivotally connected with it to the indicated stand and located in the plane of placement of a pair of main hydraulic cylinder s, with which the crossbar is connected. Pairs of t g with the main cylinders, crossmembers and base form hinge chetyrehtzvenniki that when

The deformations of the test structure with it change their shape. The main loading hydraulic cylinders can be equipped for their angular movement, which facilitates the maintenance of the stand, as well as the need for disassembling and assembling the power frames and the structure under test when installed on the stand. The stand can also be equipped with guides mounted on the base corresponding slide guides, locking tabs of the slide blocks in the slide guides, and driving the movement of the slide blocks, and the main

loading hydraulic cylinders and devices for their angular displacement (in this case) are fixed on the respective sliders, which allows to increase accuracy when testing compliant structures by eliminating errors resulting from deviations of the axes of the corresponding hydraulic cylinders from the initial position, displacing the center of their hinged mounted on the power floor in the appropriate direction.

FIG. 1 shows the stand, general view; in fig. 2 is a view A of FIG. one; in fig. 3 is a scheme for loading a compliant structure with compressive Pc and lateral Pe forces; in fig. 4 is a diagram of devices for the angular displacement of the main loading cylinders; in fig. 5 is a diagram of the loading of the test structure with the system of inclined forces Pel in FIG. 6 shows the mounting scheme of the main loading cylinder and the device for its angular movement on the slide; in fig. 7 is a section BB in FIG. 6; in fig. 8 is a scheme for elimination of errors arising due to deviations from the initial position of the axes of the main loading hydraulic cylinders.

The stand consists of a base 1 (power floor) on which the power frames are installed, each of which is made in the form of a stand 2 with a strut 3 and crossbars (beams) 4 connected to the stand 2. The number of power frames depends on the dimensions and type of - of the object. FIG. 1.2, two power frames installed parallel to one another are shown. Each cross member 4 is connected to a pair of main loading hydraulic cylinders 5 located in one plane. They are hinged on base 1. The connection of each rack 2 to the corresponding cross bar 4 is made in the form of an additional loading hydraulic cylinder 6 mounted coaxially to cross member 4 pivotally connected to it and with 2 and a pair of main cylinders 5 with a cross member 4 are connected with a pair of strands 7, one end of each rod is rigidly fixed coupled to the rod of the corresponding cylinder 5 through a coupling 8, and the other end of the same sleeve 8 is fixedly connected with the lug 9 a hinge axis 10 which is fixed to the respective end transverse rechiny 4.

The test structure 11 (for example, a spatial rectangular truss) is rigidly fixed to the base .1 and rigidly attached to the brackets 12 fixed to the crossbars 4. Each coupling 8 has an axial hole, on one side of which is right, and on the other left hand carving. At the response ends of the tg 7, rods of the hydraulic cylinders 5 and cylindrical shanks 13 of the lugs 9 are threaded, coupled with threads in the corresponding ends of the holes in the sleeves 8. On the sleeves 8 and the throat 7 there are flats for a wrench (not shown) for manual adjustment lengths t. On the cylinder bodies 5 and the base 1, there are lugs for securing the mounting of the stretcher 14, designed to maintain the hydraulic cylinders 5 in a vertical position when mounting the test structure 11.

Instead of mounting braces 14, the stand can be equipped with devices for the angular displacement of the main loading cylinders 5. Each such device can be made in the form of at least two hydraulic cylinders 15, one ends of which are hinged on the base 1, and others are hinged on the case of the loading hydraulic cylinders 5.

In case it is necessary to increase the accuracy when testing compliant structures by eliminating errors resulting from deviations from the initial position of the axes of the main loading cylinders, the stand is equipped with guide rails 16, made in the form of a groove in the base 1, sliders 17 installed in the guides 16, clamps of position of the sliders in the guides, made in the form of hydraulic cylinders fixed to the sliders 17, 18, on the rods 19 of which the brake discs 2.0 are fixed, and driven by the movements of the sliders made in Idea of hydraulic cylinders 21 installed in channels 22 of base 1. Main loading hydraulic cylinders 5 and devices for their angular displacement (hydraulic cylinders 15) are fixed on the corresponding sliders 17.

The stand works as follows.

After installing the test structure 11 in the stand and fixing it to the base 1 to ensure accurate contact of the brackets 12 crossmembers 4 with the structure 11 with fully extended hydraulic cylinder 5 rods adjust the length of the thread 7. For this, use a wrench for flats (not shown) to rotate the sleeve 8 one side or another. At the same time, depending on the direction of rotation, the couplings 8 are either screwed onto the threaded ends of the pullers 7, the rods of the hydraulic cylinders 5 and the cylindrical shanks 13 of the lugs 9, or are folded

with them. Then, the structure 11 is fixed to the brackets 12 of the crossbars 4 and the assembly extensions 14 are removed. The main hydraulic cylinders 5 load the structure 11 with compressive load Pc, additional hydraulic cylinders 6 create a horizontal (side) load Re. The construction 11 of the position shown by the dotted line in FIG. 3, is deformed into the position shown by the main lines. At the same time, the main loading cylinders 5 remain parallel to the supporting columns 23 of the test structure 11.

If, instead of mounting splices 14, devices are used for angular displacement of the main loading cylinders, the mounting of the test structure 11 into the stand is facilitated. For this purpose, the thrusts 7 with the crossbars 4 hydraulic cylinders 15 are retracted to the sides, fixed in the position shown by the dotted line in FIG. 4, set the structure 11 to the base 1, fix it on the base, return the rods 7 with the crossbars 4 to the initial state shown by the main lines. On the main rods of the main cylinders 5, lower the cross-pieces 4 on the structure 11 and fix them on the structure, for example, by means of the bolted joints of the brackets 12 with the supporting parts of the structure under test 11. When the structure 11 is loaded, the hydraulic cylinders 15 are transferred to the floating state - they close between each piston and rod cavity of each hydraulic cylinder 15, so that they do not create resistances when the structure 11 is deformed. Devices for angular displacement of the main loading hydraulic cylinders also facilitate installation rods 7 at an angle ".vertikal- symmetry axis of the structure 11 which allows the loading structure silami- Pc at an angle to its axis,

If the deformations of the structure are such that it is impossible to neglect the deviation from the initial position of the axes of the main hydraulic cylinders, to eliminate these errors during static loading of the structure, the hydraulic cylinders 5 and b turn off the hydraulic cylinders 18 of the slide positioners of the sliders in the guides 16. The sliders 17. move - hydraulic cylinders 21 from positions ai, bi to position ai, 02, restoring verticality r7. The hydraulic cylinders 18 of the locking devices of the position of the sliders 17 are turned on, their position is fixed in the guides 16. After this, the test structure 11 is cyclically loaded with the hydraulic cylinders 5 and 6.

The proposed stand provides studies of the deformability, static and fatigue strength, not only rigid but also highly deformable, i.e., pliable large-size spatial structures loaded with a spatial system of external forces, approximating the conditions of the structural tests to the conditions of operation. The nomenclatures and sizes of the tested products are expanded, the accuracy of defining the direction of the load is improved, and the maintenance of the stand is facilitated by mechanizing its readjustment to the new sizes of the tested structures.

Claims (3)

1. A stand for testing structures containing a base with power frames installed on it, each of which includes a stand and a cross member connected to it and connected to the cross bars of the corresponding frame of a pair of water surfaces of the loading cylinders, in order to expand the functional capabilities by providing tests not only for rigid but also for malleable structures, it is equipped with pairs of tg, one end of each rod is articulated with the corresponding end of the cross member, and the other is rigidly connected with with the rod of the corresponding loading cylinder, said cylinders are pivotally fixed on the base, and the connection of each pillar and the corresponding crossbar is made in the form of an additional loading cylinder that is mounted coaxially with this crossbar, pivotally connected with it to the specified rack and located in the plane of placement of a pair of main hydraulic cylinders with which the crossbar is connected. 2. A stand according to claim 1, wherein it is equipped with devices for the angular displacement of the main loading hydraulic cylinders. 3. The stand according to claim 1, characterized in that, in order to improve the accuracy in testing compliant structures by eliminating errors resulting from deviations from the initial position of the axes of the respective loading hydraulic cylinders, it is equipped with guides mounted on the base, placed in the corresponding guides of the sliders, locking the position of the sliders in the guides and driving the movement of the sliders, and the main loading cylinders and devices for their angular movement are fixed to the corresponding sliders. HCHL 2 FIG. If FIG.