SU796709A1 - Device for measuring fracture work of specimens of materials - Google Patents

Description

The invention relates to measuring technology used in testing the strength properties of materials, in particular, in the study of samples of materials and products that are shock-proof. A pile driver is known for determining the characteristic of the resistance of steel products to shock loads, in which the determination of the energy loss of the pile driver after impact is used to register the work of destruction of material samples. The change of energy is made according to the difference between the speed of the flywheel, the speed of which is constant, and the flywheel, j which committed the blow. The velocity difference is determined by a mechanical device. The disadvantages of this copra are its complexity and low measurement accuracy. The closest to the technical essence of the invention is a device for: measuring the work of destroying material samples, containing a rotary pile driver with grippers for a sample, a tachogenerator and a dial indicator 2. The disadvantage of this device is a small measurement speed, making it impossible to use it for high-performance testing of samples materials and products under conditions of multiseries or in-line production. The purpose of the invention is to increase the measurement speed. This goal is achieved by the fact that the proposed device, comprising a rotor head with specimen grips, a tachogenerator and a dial indicator, is equipped with a detecting element, two filters, a differential amplifier and a relay with a flip contact, and a tachogenerator through the detecting element and the changeover contact of the relay is connected to the filter inputs, the filter outputs are connected to the corresponding inputs of the differential amplifier, to the output of which a dial indicator is connected locator, and; the relay coil is connected to the power source through clamps made of conductors shi and insulated. The drawing shows a circuit diagram of the device. The device contains an alternating current tachogenerator 1, the rotor axis of which coincides with the rotor axis of the serviced copra or is associated with the axle of the friction gear (not shown). The output winding 2 of the tachogenerator 1 is directly connected to one of its ends with the common point of two oppositely connected U-shaped filters 3 and 4 (of the CtiC type), the potential output terminals of which are galvanically connected to the symmetric inputs of the differential amplifier 5 of the direct current loaded by switch panel 6, the second end of the output winding 2 of the tachogenerator 1 through the detecting element 7 is connected to the middle contact of the changeover contact group 8 of the polarized relay 9, the outermost contacts of which are connected to separate Potential input terminals of the above mentioned pair of counter-activated filters 3 and 4. The power supply to the relay coil 9 is carried out through circuit 10, including sample 11 tested for shock discontinuity, fixed in conductive insulated grips 12 and potentiometer 13 of the sensitivity setting from power supply 14 device, and the outputs of the filters 3 and 4 are connected to the contacts of the bipolar button 15. The device operates as follows. After installing and securing the material 11 to be examined (for example, a piece of wire), the drive motor of the rotor head is turned on. When the rotor reaches the required number of revolutions, button 15 is temporarily pressed. Simultaneously, the output capacities of filters 3 and 4 are discharged and their residual voltages are reset. Before giving the command to the Koipy rotor, the current flowing from the source 14 through the potentiometer 13 h is passed through the winding of the relay 9 and the image 11 of the potentiometer 13 h corresponds to this. The top position of the contact group 8 of the polarized relay 9 also corresponds to the charge capacitance elements of the filter 3 through the detecting element 7 d of the amplitude value of the alternating voltage generated in the winding 2 of the tachogenerator 1 at the moment preceding the impact. The output capacitance of the filter 3 is charged to the voltage generated by the tachogenerator 1, which is proportional to the angular rotational speed of the copra rotor at the moment immediately preceding the impact of the copra's shock on the test sample 11. The detecting circuit made up by the winding 2 of the tachogenerator 1, the detecting element 7 and the elements filter 3, connected by contacts 8 of the polarized relay 9 in the upper position of the core of this relay, work in peak detector mode, with its accumulative elements remembers A similar speed of rotation of the copra rotor prior to the impact on sample 11 to be investigated. At the output capacitance of the filter 3 directly connected to the same input terminal of the differential amplifier 5 of direct current, the potential is recorded that corresponds to a certain scale of the angular velocity and the corresponding initial kinetic energy of the rotor Copra parts before the attack on the sample. During a short time interval corresponding to the pulsed impact of the rotor on the sample, when, during the process of stretching the sample 11, it passes through the stages of proportional deformation, reaches the elasticity and yield strength, the winding of the relay 9 is under the current flowing through the sample: 11, until corresponding to the complete destruction (rupture) of the test sample. At the same time, the described detection circuit continues to retain its original state, which existed prior to the impact. Despite the fact that during the shock loading of the test sample 11, the speed of the copra rotor decreases slightly and the level of the variable signal applied to the detecting element 7 from the winding 2 of the tachogenerator 1 drops accordingly, during the interaction interval of the shock part of the pile with the test sample, the voltage recorded at the output capacitance of the filter 3 and corresponding to the initial energy of the rotor of the copra (before the collision with the sample), remains unchanged. This is due to the fact that for an alternating voltage decreasing in the course of an impact on the winding 2 a tachogenerator 1, the detecting element 7 retains the locked state caused by the influence of this element from the filter 3 side of a higher locking constant voltage previously fixed accumulative elements of the filter 3 higher initial speed of the rotor of the copra. At the end of the interval of interaction of the test specimen with the impact part of the copra, that is, at the moment of rupture of sample 11, when the rotor as a result of the sample resisting the destruction loses part of its initial energy and, accordingly, angular velocity, the power supply circuit of the polarized relay 9 interrupts and ensures its winding . The reversal of the corr of the relay 9, which occurs at the same time, interrupts the previously switched initial communication circuit winding 2 of the detecting element 7 with filter 3, and closing through the lower circuit of the contact group 8 the communication circuit of the winding 2 of the tachogenerator 1 and the detecting element 7 with the input of the second filter 4 , the parameters of the resistive and capacitive elements of which, as well as the filter 3, determine the operation of the detection circuit containing elements 2, 7, and 8 and the filter 4, in the peak detection mode. The detecting circuit formed immediately after breaking the sample 11, consisting of winding 2 of tachogenerator 1, detecting element 7, closing lower contacts of group 8, relay 9 and filter 4, captures the amplitude: the value of the alternating signal produced by the tachogenerator 1, right after the destruction of the tested sample 11. At the output capacitance of the filter 4, a constant potential is created, which is proportional to the angular velocity of the rotor of the copra at the moment corresponding to the rupture of the sample under study, when the rotor speed and the corresponding energy of the rotor is reduced relative to the initial values of these parameters by values, determined by the work of destruction of the sample. The output capacitance of the filter 4 stores, thus, the final angular velocity and energy of the rotor head, which correspond to the moment of sample rupture, i.e. the end of the test cycle. 96 The constant potential recorded by the output capacitance of the filter 4, equal to the ac-value of the alternating voltage on the winding 2 of the tachogenerator at the moment the sample is broken, does not change in the future, keeping the initially stored value due to locking the detector output circuit with a constant potential The unlocking of element 7 is a decreasing variable input signal. The operation of the input circuits of the differential amplifier 5 in the mode of microflows, as well as the performance of the input stages of the differential amplifier 5 on the electrometric elements almost completely eliminates any shunting effect of the differential amplifier 5 on the operation of the output capacitors of filters 3 and 4. At the time of completion of the test cycle from the output capacities of the filters 3 and 4 to the balanced input of the differential amplifier 5, two counter-acting and therefore subtractive, OD1Sh from another potential are received, the first of which The output of the filter 3 reflects the initial rotational speed of the rotor heading fixed by the device prior to the shock loading of the specimen, and the second output of the filter 4 reflects the conical working angular velocity of the headframe rotor fixed by the circuit corresponding to the moment of sample failure 11. At the same scale at the output capacitances of filters 3 and 4, the positive pole is applied to the common and bus, and negative to the separate terminals of the balanced input of the differential amplifier 5. The variability of the output voltages of filters 3 and 4 is proportional to the loss of the angular velocity of the copra rotor during the impact and the corresponding part of the initial energy of the rotor spent on the destruction of the test specimen after passing through the differential set-up unit 5 causes the indicator 6 to deflect, the scale of which is graduated in units of angular or linear velocity. With the known mass fn and the initial rotational speed of the rotor of the copra (angular velocity CBJ or linear velocity V), the work A of the destruction of the sample according to the results of measuring the difference between the initial and

Claims (1)

Formula of the invention 10 A device for measuring the destruction of samples of materials containing a rotary head with grippers for the sample, a tachometer, and a dial indicator, characterized in that, in order to increase the measurement speed, it is equipped with a detecting element, two filters, a differential amplifier and a changeover relay contact, and the tachogenerator through 20 · a detecting element and a changeover contact of the relay is connected to the inputs of the filters, the outputs of the filters are connected to the corresponding inputs of the differential amplifier, to course of which pod25 dial indicator keys and the relay winding is connected to a power source via clamps made conductive and insulated.