PL71520Y1 - Fork-shaped holder for fixing samples in the material crack resistance tests - Google Patents

Abstract

The subject of the application is a fork holder for mounting samples in tests related to determining the material's resistance to cracking, intended for determining the material's resistance to cracking by the critical value of the J integral and the critical value of the stress intensity factor, and the fatigue crack propagation speed da/dN. The handle has the form of a solid (1), with a cuboid outline, and has an upper edge cut at an angle α, creating a cutting plane (6), and rectangular planes, and has a recess in the middle in the form of a groove (7), with a rectangular outline, with a width "a" and length "E", which in the upper part has symmetrical cuts on both sides (2) creating trapezoidal planes. In the side planes, there are two holes (4, 5), running through the body, with the hole (5) having the outline of a stylized triangle, and in the rear plane there is a hole (3), along the x axis, with a diameter of Ø E .

Description

Description of the pattern The subject of the utility model is a fork holder for mounting samples in tests related to determining the material's resistance to cracking, intended for determining the material's resistance to cracking using the method. the critical value of the integral J and the critical value of the stress intensity coefficient, and the propagation speed of the fatigue crack da/dN. The handle is used to determine material constants, which are critical value?? stress intensity coefficient, the critical value J integrals and speed? crack propagation da/dn. All the above-mentioned features can be determined only for the first load state. The handles proposed in the ASTM E399 and PN EN ISO 12737 standards are: most similar to the presented element and were the starting point for designing your own sample mounting holder. Their principle of operation consists in mounting the sample in a testing machine in such a way that it is possible to free measurement of sample opening and elimination of the friction moment using? treadmill, on which you roll si? pins. The differences between the reported solution and the one proposed in the standard are: - Increasing the ratios of the dimensions of individual walls of the handle body so as to limit occurrence of outflows in the raceway. - Allows easy assembly and disassembly of the extensometer in the sample lock. - Limitation of disturbances in the operation of the extensometer by jamming the meter leg from the walls. handle. No solutions were found in the available patent solutions. similar to the design of the handle in question. There are a number of known solutions used by a number of companies: e.g. in the ABQINDUSTRIAL catalog a solution was found, similar but different in construction. A similar solution was found in the KIPP catalog, but in the fork handle there were no significant undercuts on the sides of the handle. A device similar to the proposed one can be found in Mindiamart's offer, but it is built in a circle and has no undercuts in the walls of the forks. The subject of the utility model is a fork holder for mounting samples in testing the material's resistance to cracking, used in destructive mechanical tests related to mechanics. cracking, performed on compact CT samples. The holder allows you to mount the sample on a testing machine and load it, both cyclically and statically. The mounting method does not create a frictional moment when the sample is opened. The handle according to the pattern has the form solid 1, with a cuboid outline, dimensions: height And with a value determined from the ratio A/a = 7, the width? B with a value determined from the ratio B/a = 6, and the thickness? C with a value determined from the ratio C/a = 4.4. In the front part, block 1 has a truncated at an angle ? upper? edge, creating a plane cuts 6, and rectangular planes 8, and has a recess in the middle in the form of a groove 7, with a rectangular outline, width "a" and length "E", which in part The upper part has 2 symmetrical undercuts on both sides, creating trapezoidal planes. In the lateral planes, they are located two holes 4, 5 running through the body, with the hole 5 having the outline of a stylized triangle, and there is a hole 3 in the rear plane, along x axis, with a diameter of Ø E. Hole 5 has the shape of a stylized triangle, the axes of which are shifted relative to each other by a value L determined? from the ratio a/L = 0.1, while the position of the hole axis from the nearest edge of the handle is J, determined from the ratio a/J = 1. Hole 3 is intended for attaching the handle to the pin of a testing machine , and also to align the entire system in such a way that the axes of holes 4 and 5 coincide. from the axis? along X solids. ABOUT? hole 5 is the point of application of force to the compact sample during testing. The values of the hole diameters 4, 5 are related to width? "a" of the groove 7, for mounting the sample in such a way that the ratio a/I = 1, R3/a = 0.5 and a/E = 3. Notches 2, 6 are made to facilitate mounting the extensometer on the sample in the holder and preventing its legs from getting stuck in the groove space ?in the range of 1 PL PL

Claims (1)

A fork holder for mounting samples in testing the material's resistance to cracking, characterized in that it has the form of solid (1), with a cuboid outline, and cut at an angle ? upper? edge, creating a plane cuts (6) and rectangular planes (8) and has a recess in the middle in the form of a groove (7), with a rectangular outline, width "a" and length "E" , which in the upper part has symmetrical cuts on both sides (2) creating trapezoidal planes, in the side planes, they are located two holes (4, 5), running through the body, the hole (5) has a triangle shape, and in the rear plane there is a hole (3) along x axis, diameter Ø E. Handle according to claim 1, characterized in that the opening (5) has the shape of a stylized triangle whose axes are shifted relative to each other by a value? L determined? from the ratio a/L = 0.1, while the position of the hole axis from the nearest edge of the handle is J, determined from the ratio a/J = 1. The handle according to claim 1, characterized in that the geometry of the cut (2) is characterized by the geometric values H and G and is H/G = 1.5 and the angle ?1 = ?2 is 30°-60°.