CS209028B1 - Process for preparing weld metal test specimens for testing its mechanical properties - Google Patents

Abstract

The invention relates to a method of defined clamping of test specimens for the production of weld metal for testing its mechanical properties. The invention represents a new method of obtaining materials for the design of equipment and the production of metal structures and large-scale welds. The essence of the invention lies in the fact that test specimens with welding surfaces are rigidly clamped by friction joints into clamping fixtures - metal of known rigidity, the size of which can be changed, then the weld metal is produced with the test filler material determined by the welding parameters for testing its mechanical properties.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for defining test specimens for welding and metal for testing its mechanical properties.

The present invention provides a new way of obtaining background materials for the construction of devices and the construction of metal structures and large welds.

The essence of the invention is that test specimens with welding surfaces are rigidly clamped by friction joints to clamping jigs with a known stiffness that can be changed in size, then a weld metal is made for the mechanical properties of the test material by the welding parameters determined by the welding parameters.

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The invention relates to a method for preparing weld metal test specimens for testing its mechanical properties. Currently, there are several known methods for preparing weld metals for testing their mechanical properties. Most often, the weld metal is formed by welding between two test metal doughs approximately 20 mm thick with a 16 mm root gap. This gap is provided by a flange J of 8-10 mm thick. The test planks are laid loose before and during the winding. Another way I allows the weld metal to be formed as many! layer coating on the plate into the angle or the willow.

The welding cycle is a superposition of the temperature and its band-deformation cycle, but so far known methods allow only the temperature cycle to be determined. The stress-strain component given by the clamping stiffness is practically ignored. It is always welded in a non-clamped state, while the actual stiffness of the sample is negligible. However, on a real construction, the stiffness ratios are fundamental. This means that the weld metal is tested under other conditions in which it actually works. In addition, the temperature cycle is little similar to the actual, since the heat dissipation in the real structure due to its dimensions is different than the dimensionally insignificant sample. Thus, it can be stated that the prior art processes for the preparation of weld metals do not adequately reflect the conditions in the actual construction. From the previously known methods, the influence of the rigidity of the test plate clamping on the mechanical properties of the weld metal cannot be observed in either case.

The above drawbacks are largely eliminated by the invention. The essence of the method of preparing test pieces with weld metal for testing its mechanical properties according to the invention is that test specimens provided with welded surfaces are clamped by frictional joints by means of screws to clamping fixtures adjustable by a known rigidity and then the test additional material determined by welding parameters is made weld metal between weld surfaces. ____________________ _________

The present invention presents several advantages. The weld metal is prepared in such a way as to bring the test conditions closer to those of a real construction. It allows defining and maintaining temperature and voltage-strain cycle. This method makes it possible, among other things, to determine the influence of the clamping stiffness on the mechanical properties at fixed welding parameters or the influence of welding parameters at a constant known clamping rigidity on the mechanical properties of the weld metal. The method according to the invention makes it possible to compare the influence of the known clamping stiffness on the mechanical properties of the weld metal produced by various additional materials with the same or altered parameters on the attached sculptures, where FIG. Fig. 2 is a cross-section of this fixture with the clamped sample;

The test piece 1 provided with the weld surfaces 4 is clamped rigidly by friction joints by means of high-strength screws 2 to the clamping connections. known rigidity. For this purpose, the friction surfaces are roughened between the test sample 1 and clamp 3 to the desired coefficient; cient trenia. A torque wrench is used to produce the desired stiffness. The stiffness of the clamping increases with the increase of the ridge h of the test sample 1, the ridge H of the clamping device 3 and the reduction of the clamping length L. The following relation is used to determine the clamping stiffness: - 1 - 2bj h where E is the modulus of elasticity (2.1 105 N, mm 2); A is the length of the fixture 3, b is the length of the test sample 1, and bj is the smallest dimension of the fixture 3.

To determine the dimensions of the test specimens is; it is necessary to start from real values of clamping stiffness, in test constructions, which are in the range of 400 h, which is about 5 to 35 kN / mm for h = 10 to 50 mm. mm. i! | An example of an embodiment of the actual clamping flange 3 is shown in Fig. 3. Starting from the above described, the series of five clamping jigs 3 will, moreover, have the following dimensions: H (mm) L (mm) A (mm) Clamping rigidity (kN) mm. mm 12 220 620 10.02 16 170 570 14.71 20 130 530 20.93 25 100 500 29.27 30 80 480 38.54

Claims (1)

Method for preparing weld metal specimens for testing its mechanical properties, characterized in that the specimens provided with weld surfaces are rigidly clamped by friction joints by means of bolts into fixtures of an adjustable known stiffness and then welded between the weld surfaces by a test additive determined by welding parameters. .