SU573783A2 - Device for testing moving ferromagnetic materials in the form of drawn rods,wire and strips - Google Patents

Claims (2)

The device's scom, FIG. 2 to work with him. The device contains a measuring coil 1 connected through a serially connected amplifier 2 and a former 3 to the output of a recording device 4, an additional coil 5 located between permanent magnets 6 and 7 in the gradient zone of the magnetic floor created by these permanent magnets and connected via serially connected the driver 8 and the contacts 9 and 1 of the switch 11, the other contacts 12 and 13 of which are connected to the second input of the generator 3. The measuring coil 1 is placed in the place of the maximum changes in induction B to ferromagnetic material 14. The operation of the device is as follows. When contacts 9 and 10 are open, switch 11 is a ferromagnetic material 14, moving in a dlH / a magnetic field gradient, magnetizable-pc over the limiting branch of the hysteresis loop from - W io -tlm о.e Btn is the maximum value of the magnetic field induction. Arising in the measuring coil 1 pulses of emf. amplified by amplifier 2 and passed through the 4UrBiber 3, are fed to a recording device 4, for example, a frequency meter, which determines the pulse frequency. When the contacts 12 and 13 of the switch 11 are closed, the shaper 3 operates as a threshold device. A change in the structure from the test or the occurrence of a defect at the location of the measuring coil 1 leads to a change in frequency, which is detected by the recording device 4. With contacts 9 and 10 closed and contacts 12 and 13 of the switch 11 open, pulses from measuring coil 1 are amplified by amplifier 2 , enter the shaper 3, which forms impulses of sufficiently long duration. A rectangular impulse formed through closed contacts 9 and 1O of switch 11 enters shaper 8, which produces a current pulse in additional coil 5. Ferromagnetic material 14 is magnetized to saturation along the ascending branch of the hysteresis loop. The distribution of induction in the ferromagnetic material 14 after the current pulse ceases to be effective, while dashed lines are shown. The solid line shows the distribution of induction until the current pulse is transmitted to the auxiliary coil 5. From the consideration of FIG. 2 that the point A induction is on the downstream hysteresis loop. When moving the ferromagnetic material 14, the induction at point A will vary in the direction of straight UD (Fig. 2a), i.e. will remain constant, which means there are no pulses on the second amplifier 2. After the point A passes the distance t, the force of the ferromagnetic material 14, in a time equal to T, where V is the speed of the ferromagnetic material 14, pulses appear at the input of the amplifier 2. Next, the device operation cycle repeats. The pulse duration at the output of the imaging unit 3 is adjusted so that during its operation the transient process in the additional coil 5 has ended. The device described allows to expand the range of monitored parameters, such as coercive force, the measured value being converted into a time interval, which allows digital signal processing methods. Claims An apparatus for monitoring moving ferromagnetic materials in the form of drawn rods, wires and tapes according to the authors. St. No. 451970, characterized in that, in order to expand the range of monitored parameters, a switch, two drivers and an additional coil placed between the permanent magnets in the magnetic field gradient zone created by these magnets and connected through the first driver and the first the switch contacts to the output of another driver connected between the amplifier and the recording device, and the second input of the second driver connected to the other contacts of the switch. Sources of information taken into account in the examination: 1. USSR Author's Certificate No. 451970, cl. ®- 01 R 33/12, 1972. p v4orvw AND Have -n /four 4-5, t