SU1272209A2 - Electromagnetic orientator - Google Patents

Abstract

This invention relates to instrumentation and control technology. The purpose of the invention is to increase the orientation accuracy when expanding the capture zone by registering the second component of the electromagnetic field. In the first stage of the operation of the orientator, the signal of the inductive element is compared in the comparison and sampling unit with the value corresponding to the transparency window. If these values are equal, the voltage rise at the generator output stops and then the generator operates at the selected frequency. At the second stage, adjustment of 1 amplification factors of amplifiers is carried out depending on the magnitude of the signal on one of the inductive elements, which, in turn, depends on the thickness of the product under test. In the third stage, the operation is performed on the orientation of the radiator and receiver. In case of misalignment, the difference in the emf of inductive elements is different from zero. This difference is amplified and through the circuit the commands arrive at the indicators, which illuminate the arrows indicating the necessary direction of movement of the receiver to achieve its alignment with the radiator. 1 il.

Description

Yu

Claims (2)

The invention relates to means of measuring and measuring equipment, can be used for the orientation of nodes and elements in screen systems of non-destructive testing, and is an improvement of the device according to the author. Ev, No. 1180775. The purpose of the invention is to improve the accuracy of the orientation when expanding the capture zone by registering the second electromagnetic field. The drawing shows a structural diagram of an electromagnetic orientator. The orientator contains an ultrasonic oscillator 1 connected in series and an emitter 2. I The orientator also contains a receiver 3, made in the form of four inductive elements 4-7, pairwise connected and arranged mutually perpendicularly, two amplifiers 8 and 9, to the outputs of which are connected a pair of inductive elements 4-5 and 6-7, connected in series oppositely in each pair, a correction and measurement unit 10 connected to the inductive element 5, the outputs of which are connected to the control inputs respectively Amplifiers 8 and 9, connected in series with a circuit of 11 commands, connected to the outputs of amplifiers 8 and 9 and generator 1, and an indicator 12 ,, executed in the form of four indicators 13–16. The orientator also contains a comparison and sampling unit 17 connected in series and a sawtooth voltage generator 18 connected between the inductive element 5 and the control input of the ultrasonic oscillator 1. Each inductive element 4-7 is made in the form of two series-connected sections 19 and 20 located mutually perpendicular, one of which is installed parallel to the plane of the radiator 2. The orientator works as follows. The work of the orientator can be divided into three stages. The emitter 2 and the receiver 3 are mounted on opposite surfaces of an object (not shown), which is subject to subsequent non-destructive testing. At the moment of switching on, the emitter 2 from generator 1 is supplied with an alternating sinusoidal 92 current, whose frequency is 20 Hz. In the inductive element 5, an emf is induced whose value is compared in the comparison and sampling unit 17 with the value corresponding to the material transparency window. The input of material 1 receives a smoothly increasing voltage from the saw-voltage generator 18 and the frequency of the alternating sinusoidal current changes from 20 Hz to 20 kHz. When the frequency of the electromagnetic field of the transparency window reaches, the voltage increase at the input of generator 1 stops and then generator 1 operates at the selected frequency. The adjustment operation on the transparency window only when the EMF value induced in the inductive element 5 falls below a predetermined value. At the second stage, the gains of the amplifiers 8 and 9, the orientator, are adjusted depending on the signal size and on one of the inductive elements, which in turn depends on the thickness of the product being tested. In the third stage, the operation is performed on the orientation of the radiator 2 and the receiver 3. This occurs as follows. The generator 1 feeds the emitter 2. In this case, the inductive elements 4–7 of the receiver 3 are excited. In the coaxial position of the emitter 2 and the receiver 3 of the orientator, the difference in the emf induced in each pair of inductance elements 4, 5 and 6, 7 is zero. When the coaxiality is disturbed, the difference in emf is different from zero, the signals from each pair are amplified in amplifiers 8 and 9, and through circuit 11, commands arrive at indicators 13-16, which highlight swept cutouts indicating the necessary directions of movement of the receiver 3 to achieve its alignment with the radiator 2. In the coaxial position of the radiator 2 and the receiver, none of the arrow-shaped cuts are highlighted. The presence of two mutually perpendicular sections 19 and 20 in the inductive elements makes it possible to register both the vertical and horizontal components of the electromagnetic field, which makes it possible to work efficiently both in the near capture zone and in the far field. Claims of the invention Electromagnetic orientator according to the author. St. No. 1180775, characterized in that, in order to increase the accuracy of orientation with the extension of the gripping zone, the inductive elements are made in the form of two series-connected mutually perpendicular sections, one of which is installed parallel to the radiator plane.