RU2113702C1 - Device for strength test of tubular specimens - Google Patents

Abstract

FIELD: examination and testing of parts and materials. SUBSTANCE: coaxial holes 2, 17 and 20 are made in base 1, flange 14 of loader 12 and on bottom of sleeve 18, respectively. Bush 8 has blind recesses 9, and loader 12 is provided with vertical 15 and spiral recesses. Device is fitted with turning bush 21 positioned on bush 8. Projections 22 of turning bush contact blind recesses 9 of bush 8. Thrust bush 25 with axles 28 contacting side walls of recess 15 or 16 of loader 12 is installed in space formed by external surface of loader 12 and internal surface of turning bush 21. Vacant ends of axles 28 carry radial bearings 29, external races of which contact side walls of vertical recesses 24 of turning bush 21. Thrust bearing 30 carrying force support 31 is positioned on cylindrical projection 27 of thrust bush 25. Device is also provided with studs 32 and 33 designed to prevent loader 12 and sleeve 18 from turning relative to base 1. EFFECT: higher test results. 1 dwg

Description

 The invention relates to testing equipment, and in particular to devices for testing tubular samples and cylindrical shells.

 Known devices for mechanical testing of thin-walled tubular samples (576525, 729481, 1168820, 1173237, class G 01 N 3/04).

 Known designs of devices and grips do not have versatility, require testing machines that generate torques, and do not exclude possible eccentricity when transmitting axial forces and deviating the torque vector from the axis of the sample. In addition, a number of designs require special preparation of the ends of the sample in the form of various thickenings, and when testing samples made of modern high-strength composite materials, the possibility of slipping or breaking of their ends is not ruled out.

 The prototype of the invention is a device for testing thin-walled tubular samples for strength (see ed. St. N 1836629, class G 01 N 3/04), containing a base, a cylindrical housing placed on it, passive and active grippers placed in the housing, a cylindrical loader , power support and load meter.

 However, the known device does not provide loading of the tubular sample with a torque.

 The technical result from the use of the proposed device is to increase the information content due to the possibility of loading the samples as tensile and compressive forces, and torque.

 The essence of the invention lies in the fact that in the device for testing tubular samples for strength, containing a base, a cylindrical body placed on the base, placed in a cylindrical body, passive and coaxial active grips fixed to it, each of which is made in the form of a shell and installed in a wedge liner for gripping the outer surface of one of the ends of the tubular sample, mounted on the side of the passive capture, coaxially with the shells, the first sleeve, the outer surface of which The swarm is intended for contacting with the inner surface of the end of the sample from the side of the passive gripper, a cylindrical loader made with two flanges, a support installed on the side of the active gripping, made in the form of the first cup and ball bearing, placed coaxially with the cylindrical loader between the outer surface of the bottom of the first cup and the base, as well as the second ball bearing, while one of the ends of the cylindrical loader is placed in the cavity of the first glass, the device is equipped with a second sleeve, being turning rotary and covering the cylindrical loader from the side of passive capture, forming an annular cavity between their facing each other surfaces, the third sleeve, which is persistent and mounted in this cavity with the possibility of axial movement, two axes, persistent and radial bearings, power support and studs, moreover, the end face of the first sleeve is made with four symmetric blind grooves, the second sleeve has four symmetrical protrusions designed to be placed in blind grooves on the end face e of the first sleeve, the second sleeve on the inner surface has two annular protrusions and two vertical grooves diametrically located, the third sleeve is made in the form of a second cup with two holes diametrically located in the wall and an annular protrusion on the outer surface of the bottom, with the base corresponding to the cylindrical loader flange and the bottom of the first glass is made with symmetrically located, coaxial holes, the studs are installed in the holes of the bottom of the first glass and the corresponding cylindrical flange two vertical and two helical grooves are diametrically opposed on the outer surface of the cylindrical loader from the side of the passive gripper, one ends of the axes are in contact with the walls of the screw grooves on the cylindrical loader, radial bearings are installed at the free ends of the axles, the outer cages of which are designed to contact the walls the vertical grooves of the second sleeve, the thrust bearing is mounted on an annular protrusion on the outer surface of the bottom of the second glass, power support mounted on a thrust bearing, and the second spherical bearing is designed to contact the inner surface of the bottom of the second cup and the cylindrical surface of the other flange nagruzhatelya.

 The drawing shows a General view of the proposed device.

 The device comprises a base 1 with holes 2, a cylindrical body 3 located on the base with a support ring 4 mounted on it, passive and active grippers, each of which is made in the form of a shell 5, a wedge liner 6 installed in it, intended for gripping the outer surface of one of the ends of the tubular sample 7, mounted on the passive gripping side, the first sleeve 8 with four symmetrical blind grooves 9, a locking washer 10 and bolts 11, a cylindrical loader 12 with flanges 13 and 14. On the outer surface nagruzhatelya cylindrical spine 12 from the passive grip formed diametrically opposite the two vertical 15 and two helical groove 16. The flange 14 of the cylindrical loader 12 is made with four symmetrical holes 17, coaxial with the holes 2 of the base 1. The support installed on the side of the active gripper is made in the form of the first glass 18 and the ball bearing 19.

 At the bottom of the first cup 18, four symmetrically arranged openings 20 are made coaxial with the openings 2 and 17 of the base 1 and the flange 14 of the cylindrical loader 12, respectively. At the end of the first sleeve 8, a second sleeve 21 is installed, made with four symmetrical protrusions 22, intended for contact with the blind grooves 9 of the first sleeve 8. The second sleeve 21 has two annular protrusions 23 and two diametrically arranged vertical grooves 24. In the annular cavity formed by the outer surface the loader 12 and the inner surface of the second sleeve 21 is mounted axially movable, the third sleeve is made in the form of a second glass 25 with two holes diametrically located in the wall mi 26 and with an annular protrusion 27 on the outer surface of the bottom. Axes 28 are installed in the openings 26 of the second cup, the protruding ends of which on the inside are intended for contacting with the side walls of the vertical 15 or screw 16 grooves of the cylindrical loader 12, and the protruding ends on the outside of the second cup 25 are equipped with radial bearings 29, the outer cages of which are intended for contacting the walls of the vertical grooves 24 of the second sleeve 21.

 A thrust bearing 30 is mounted on the end protrusion 27 on the outer surface of the bottom of the second cup 25, and a power bearing 31 is mounted on it. Studs 32 are installed in the holes 17 of the flange 14 of the cylindrical loader 12, and studs 33 are installed in the holes 20 of the bottom of the first cup 18. Between the inner the bottom surface of the second glass 25 and the outer surface of the flange 13 of the cylindrical loader 12 mounted ball bearing 34.

 The device operates as follows.

 On the first glass 18 put on the test sample 7, the casing 5 with the wedge liner 6 and the locking washer 10 with the bolts 11 of the active grip, turn the washer 10 before entering, the locking protrusions in the grooves of the casing 5, wrapping the bolts 11 displace the casing 5 relative to the first glass 18, making initial compression of one of the ends of the sample 7. Then, a support ring 4 is installed on the shell 5 of the active grip, a shell 5 is put on the shell 5 with a wedge insert 6 of the passive grip, a cylindrical load is inserted into the first glass 18 of the active grip collar 12. Next, in the cavity between the outer surface of the cylindrical loader 12 and the inner surface of the sample 7, insert the first passive capture sleeve 8, onto which the shell 5 with the wedge liner 6 and the lock washer 10 are put on, using the bolts 11, compress the other end of the sample 7. After whereby a tubular sample 7, mounted in grips, is placed in the inner cavity of the cylindrical body 3, one end of which through the shell 5 of the passive gripper and the support ring 4 are supported on the housing 3, and the other end of the sample 7, s Mounts in the active capture is in a suspended position. A second bushing 21 is put on the cylindrical loader 12 from the passive gripper side. In this case, the protrusions 22 of the second bushing are engaged with the grooves 9 on the first bushing 8. On the axis 28, radial bearings 29 are put on and installed in holes 26 of the second cup 25. Then, in the formed a second cup 25 is inserted into the outer surface of the cylindrical loader 12 and the inner surface of the second sleeve 21. Next, a thrust bearing 30 is mounted on the annular protrusion 27 of the bottom of the second cup 25, and a power bearing 31 is mounted on it.

 When testing the tubular specimen 7 for tension, the second sleeve 21, the second cup 25 with axles 28 and bearings 29, the thrust bearing 30 and the power support 31 are not installed, the ball bearing 19 is lowered and a force is applied to the loader 12, tensile stress arises in the sample 7.

 When testing the tubular specimen 7 for compression by a ball bearing 19, a tubular specimen is raised until a gap is formed between the passive grip shell 5 and the support ring 4, and the thrust bearing 30, the power bearing 31 and the ball bearing 34 are not installed, the free ends of the axes 28 are inserted into the vertical grooves 15 cylindrical loader 12 and create a force on the second glass 25, a compression stress arises in the sample 7.

 When testing the tubular sample 7 for torsion, the ball bearings 19 and 34 are not installed, the studs 32 and 33 are inserted into the holes 20 and 2 of the bottom of the first glass 18 and base 1, respectively. The free ends of the axes 28 are inserted into the screw grooves 16 of the cylindrical loader 12 and create a force on the power support 31, torsional stresses occur in the sample 7.

 Similarly, thin-walled tubular specimens are tested on an impact stand.

 The invention allows to expand the functional purpose of the device.

 Tests of the prototype device showed that it meets the goals set during its development.

Claims (1)

 A device for testing tubular samples for strength, containing a base, a cylindrical body placed on the base, housed in a cylindrical body, passive and coaxial active grips fixed to it, each of which is made in the form of a shell and a wedge insert installed in it to cover the outer surface of one from the ends of the tubular sample mounted on the sides of the passive capture coaxially with the shells of the first sleeve, the outer surface of which is designed to contact with the inside the surface of the end of the sample from the side of the passive capture, a cylindrical loader made with two flanges, mounted on the side of the active capture of the support, made in the form of the first glass and ball bearings placed coaxially with the cylindrical loader between the outer surface of the bottom of the first glass and the base, as well as the second ball bearing, while one of the ends of the cylindrical loader is placed in the cavity of the first glass, characterized in that the device is equipped with a second sleeve, which is rotary and coverage a cylindrical loader from the side of passive capture, forming an annular cavity between their facing each other surfaces, the third sleeve, which is a thrust and mounted in this cavity with the possibility of axial movement, two axes, thrust and radial bearings, power support and studs, with the end face of the first the sleeve is made with four symmetrical blind grooves, the second sleeve has four symmetrical protrusions designed to be placed in the blind grooves at the end of the first sleeve, the second w the can on the inner surface has two annular protrusions and two diametrically located vertical grooves, the third sleeve is made in the form of a second glass with two holes diametrically located in the wall and an annular protrusion on the outer surface of the bottom, while the base, the corresponding flange of the cylindrical loader and the bottom of the first glass are made with symmetrically located coaxial holes, the studs are installed in the openings of the bottom of the first glass and the corresponding flange of the cylindrical loader, to the outside two vertical and two screw grooves are made diametrically opposite to the surface of the cylindrical loader from the side of the passive gripper, one ends of the axes contact the walls of the screw grooves on the cylindrical loader, radial bearings are installed at the free ends of the axles, the outer cages of which are designed to contact the walls of the vertical grooves of the second sleeve , the thrust bearing is mounted on an annular protrusion on the outer surface of the bottom of the second glass, the power bearing is mounted on the thrust on bearing, and the second ball bearing is intended for contact with the inner surface of the bottom of the second glass and the surface of the other flange of the cylindrical loader.