SU1441178A1 - Thickness-to-time interval converter - Google Patents

Description

The invention relates to instrumentation engineering and can be used in measuring the thickness of large non-ferromagnetic products.

The aim of the invention is to increase the reliability of control due to the linearization of measurements at large values of the measured thickness,

The drawing shows a block diagram of the proposed device

The device contains a series-connected constant-voltage source 1, a switch 2, a source winding 3 and a resistor 4 connected in series with an inductor; 11 connected to the second input of the integrating amplifier 7. The device also includes a switch 12 connected between the source winding 3 of the field and the input of the integrating amplifier 7, and a switch 13 connected between the output of the zero-organ 8 and the second input of the integrator 10 . The control inputs of all the keys are connected to the outputs of the control unit 9. Integrating amplifier 10 comprises a series-connected resistor 14 and an operational amplifier 15 and N chains, each of which contains a series-connected capacitor 16, j-16.N and a switch 17.1-17, N included in the feedback circuit of the operational amplifier 15, The control inputs of the keys 17,1-17, N are the first input of the integration unit 10, the free end of the resistor 14 is the second input, and the output of the operational amplifier 15 is the output of the integration unit 10.

Integrating amplifier 7 contains a series-connected resistor 18 and an operational amplifier 19, a series-connected capacitor 20 and a switch 21 connected to the feedback circuit of the operational amplifier 19, series-connected resistor 22 and a switch 23 connected to the feedback circuit of the operational amplifier 19 and a resistor 24 connected to the input of the operational amplifier 19. The free cogs of the resistors 18 and 24 are the first and second inputs of the integrating amplifier 7, respectively, and the output is

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amplifier 19 - by the output of the integrating amplifier 7,

The device works as follows.

The winding 3 of the source field and the inductive-Sch1ONN converter 5 is applied coaxially on different sides of the object to be monitored (not shown) in a given control zone. Measurements are taken in five cycles. In the first cycle, the key 2 is closed and the current of the current source 1 has a stationary value,

By the end of the first clock cycle, key 2 is opened, which causes an informative impulse to appear at the output of the induction converter 5. This pulse is integrated by the integrating amplifier 7. The integration is performed during the second and third measurements. At the end of the third cycle, the key 2 is again closed, and on the fourth cycle, the current begins to grow again. In this case, the integrated amplifier 7 is disconnected from the source of the signals and remembers the current value of the signal. On the fifth stroke, the key 12 is closed and the signal is integrated before the zero-organ 8 is triggered, which brings the circuit to the initial state.

The use of the first cycle at a stationary current value makes it possible to avoid interference. This happens as follows. Since the current has a stationary value, then at the output of the induction converter 5 there is only an interfering signal. In this case, the keys 2, 6, 11 are closed, the keys 12 and 21 are open, the integrating amplifier 7 performs the role of a summing amplifier having the same sensitivity on both inputs. In the presence of interference, the signal arrives at the inverting input of the null organ 8, and then at the block 10 of integration. The latter monitors the value of the interference with the opposite sign and delivers a compensation signal to the integrating amplifier 7, allowing the signal to be corrected by the value of the interference voltage.

Claims (2)

1. The thickness converter in the time interval containing the series-connected source of direct voltage, the first switch, the winding of the source, the field and the resistor, the test-connected induction converter and the second switch, the third switch. connected between the output winding of the source field and the second key, a serially connected null organ and a control unit, a fourth key connected to the null organ output, and a fifth key, the control inputs of all the keys are connected to the control unit, characterized in that in order to increase the reliability of the control, it is equipped with an integration unit, the inputs of which are connected to the control unit and the fourth key, and the output is connected to the input of the fifth key, and integrating. an expander whose inputs are connected to the second and the right keys, and the transducer is connected to the input of the null organ. 2. The converter according to claim 1, T is characterized in that the integration unit is in the form of a series-connected resistor and an operative amplifier and N chains of a series-connected capacitor and a key included in the feedback circuit of the operational amplifier, the free end of the resistor is the first input of the integrator, the control inputs of the keys are the second input, and the output of the amplifier - by the output of the integration unit. 3, The converter according to claim 1, 1, and t is characterized in that the integrating amplifier is designed as two resistors, the ends of which are the first and second inputs of the integrating amplifier, an operational amplifier, to the input of which resistors are connected, and the output is the output of the integrating amplifier, connected in series the capacitor and the first switch, included in the feedback circuit of the operational amplifier, and connected in series, the third resistor and the second switch, included in the feedback circuit of the operational amplifier.