RU2468351C1 - Plant for impact loads of sample - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: plant comprises a base, the following components installed on it: a shelf with a grip for a sample, a striker in the form of an elastic plate, a hinged joint for fixation of one end of the plate and an anvil block of controlled weight, fixed at the other end of the plate, and an accessory for cocking and lowering the striker with a drive of rotation. The plant comprises a platform, a mechanism of reciprocal displacement of a platform and a fixator of hinged joint rotation. An accessory for cocking and releasing a striker is arranged on the platform and is arranged in the form of a shaft, connected with the drive of rotation and installed in parallel to the axis of the hinged joint as capable of displacement perpendicularly to the axis of the hinged joint, and a stop radially fixed on the shaft as capable of interaction with the striker.

EFFECT: increased scope of information by testing while loading a sample both under repeated shocks of identical force and in case of single-cycle, double-cycle and triple-cycle loading with an adjustable frequency of applying shocks and controlled level of permanent surcharge.

3 cl, 1 dwg

Description

The invention relates to installations for shock loading of rock samples, models of equivalent materials.

A known installation for shock loading of a sample (patent SU No. 1343291, class G01N 3/32, 1987), containing a base, a shelf mounted on it with a grip for the sample, a hammer and a device for cocking and lowering the hammer with a rotation drive.

The disadvantage of the installation is that it provides testing only when repeatedly striking the same force.

A known installation for impact loading of a sample (patent SU No. 1582067, class G01N 3/32, 1990), containing a base, a shelf mounted on it with a grip for the sample, a drummer in the form of an elastic plate, a hinge for securing one end of the plate and a striker of adjustable weight mounted on the other end of the plate, and a device for cocking and lowering the hammer with a rotation drive.

The disadvantage of the installation is that it provides testing only when repeated strikes of the same and single-cycle force without initial constant load on the sample.

A known installation for impact loading of a sample (patent SU No. 1670499, class G01N 3/32, 1990), containing a base, a shelf mounted on it with a grip for the sample, a drummer in the form of an elastic plate, a hinge for securing one end of the plate and a striker of adjustable weight mounted on the other end of the plate, and a device for cocking and lowering the hammer with a rotation drive.

The disadvantage of the installation also lies in the fact that it provides testing only when repeated strikes of the same or single-cycle force. Tests with two-cycle and three-cycle loading with a given initial constant load are not feasible, which limits the amount of information when testing samples of materials.

The technical result of the invention is to increase the amount of information by conducting tests during loading of the sample both during repeated impacts of the same force, and during single-cycle, two-cycle and three-cycle pulse loading with an adjustable frequency of striking and an adjustable level of constant loading.

The technical result is achieved by the fact that the installation for impact loading of the sample, containing the base, a shelf mounted on it with a grip for the sample, an impactor in the form of an elastic plate, a hinge for fixing one end of the plate and a hammer of adjustable mass fixed on the other end of the plate, and a device for of a cocking and lowering of a striker with a rotation drive, according to the invention, has a platform, a mechanism for reciprocating movement of the platform and a rotation lock of the hinge, while the device for cocking and lowering the hammer is placed on the platform and is made in the form of a shaft connected to a rotation drive and mounted parallel to the axis of the hinge with the ability to move perpendicular to the axis of the hinge, and a stop radially mounted on the shaft with the possibility of interaction with the hammer.

The technical result is also achieved by the fact that it has a second reciprocating movement mechanism and a power spring connected at one end to the reciprocating movement mechanism, and at the other end connected to the hammer.

The technical result is also achieved by the fact that it has additional stops of different stiffness, radially mounted on the shaft with the possibility of interaction with the hammer.

Figure 1 presents the installation diagram.

The apparatus for impact loading of the sample comprises a base 1, a shelf 2 mounted on it with a grip for the sample 4, a hammer in the form of an elastic plate 5, a hinge 6 for securing one end of the plate 5, and a hammer 7 of adjustable mass fixed on the other end of the plate, and fixture 8 for cocking and lowering the hammer with a drive of 9 rotation.

The installation has a platform 10, a mechanism 11 for reciprocating movement of the platform 10 and a latch 12 for turning the hinge 6. A device 8 for cocking and lowering the hammer is located on the platform 10 and is made in the form of a shaft connected to the rotation drive 9 and mounted parallel to the axis of the hinge 6 with the possibility displacement perpendicular to the axis of the hinge, and an abutment 13 radially mounted on the shaft with the possibility of interaction with the hammer.

The installation has a second reciprocating movement mechanism 14 and a power spring 15 connected at one end to the reciprocating movement mechanism 14 and connected to the striker plate 5 at the other end.

The installation has additional stops 16 (figure 1 shows one additional stop) of different stiffness, radially mounted on the shaft of the device 8 with the possibility of interaction with the plate 5 of the hammer.

The load from the plate 5 to the capture 3 is transmitted by the pusher 17.

Sample 4 is mounted on a shelf 2 by a clamp 18. The latch 12 has a typical design (screw, wedge, electromagnetic, etc.) and is shown schematically. The platform 10 is connected to the mechanism 11 by a rigid rod 19 moving in the guides 20. The reciprocating mechanisms are made in the form of frames 11, 14 with slots in which the fingers 21, 22 are placed, connected with the rotation drives 23, 24 and mounted eccentrically relative to the corresponding axes of rotation. The spring 15 is connected to the plate 5 and the mechanism 14 by flexible rods 25 through the block 26.

Installation works as follows.

To create an initial constant load on the sample 4, turn the hinge 6 clockwise and turn on the latch 12 (the device for turning the hinge in Fig. 1 is not shown). This leads to elastic bending of the plate 5 and to create a load on the sample 4 through the pusher 17 and the grip 3.

For testing when applying repeated strokes of the same force, one of the stops 13 or 16 is installed and the lock 12 is turned on. The drive 9 is turned on and the shaft 8 is turned, as a result of which the stop 13 or 16 periodically bends the plate 5. After the stop comes out of contact with the plate, the latter strike on the pusher 17, the capture 3 and the sample 4. The frequency of the blows is determined by the speed of rotation of the shaft 8.

To load the sample with a series of repeated strokes of different strengths, additional stops of 16 different stiffnesses are used according to the number of strokes in the series. The different strength of each impact is determined by the stiffness of the corresponding stop, since the emphasis of greater rigidity deflects the plate at a larger angle.

For tests under two-cycle loading, the drive 23 is turned on and with the help of the pin 21, the frame 11 and the rod 19 cyclically move the platform 10 with the drive 9, the shaft 8 and the stops 13, 16. The distance between the rotation axes of the shaft 8 and the hinge 6 cyclically changes. reducing the specified distance, the stops 13, 16 deflect the plate 5 by a larger angle, which creates shock pulses of greater force, and vice versa.

For tests with three-cycle loading, the latch 12 is turned off and the drive 24 is turned on. A cyclic change in the tension force of the spring 15 and a corresponding change in the magnitude of the shock pulses occur. A constant load level when used when connecting this mode is created by pre-tensioning the spring 15 (devices for the initial spring tension have typical designs, therefore, are not shown in FIG. 1).

In all modes, the frequency of the shock pulses is controlled by the speed of rotation of the drive 9 of the cocking and descent of the hammer.

The proposed installation provides testing of samples both in repeated impacts of the same force, and in single-cycle, two-cycle and three-cycle pulsed loading with an adjustable frequency of striking and an adjustable level of constant loading.

Claims (3)

1. Installation for impact loading of the sample, containing the base, a shelf mounted on it with a grip for the sample, a striker in the form of an elastic plate, a hinge for securing one end of the plate and a striker of adjustable mass fixed on the other end of the plate, and a device for cocking and lowering the striker with a rotation drive, characterized in that it has a platform, a mechanism for reciprocating movement of the platform and a rotation lock of the hinge, while the device for cocking and lowering the hammer is placed on the platform and ying a shaft connected to a rotary drive and mounted parallel to the pivot axis to move perpendicular to the pivot axis and the abutment radially fixed to the shaft to cooperate with a striker. 2. Installation according to claim 1, characterized in that it has a second reciprocating movement mechanism and a power spring connected at one end to the reciprocating movement mechanism and connected to the drummer at the other end. 3. Installation according to claim 1, characterized in that it has additional stops of different stiffness, radially mounted on the shaft with the possibility of interaction with the hammer.