DE2219364A1 - Circuit for signaling and resolving the level of received ultrasonic pulses - Google Patents

Description

Circuit for signaling and resolution of the level of received Ultrasonic pulses The subject of the invention is a circuit for signaling and resolution of the level of received ultrasonic pulses occurring in a particular Can be hidden.

In the ultrasonic material testing are used for signaling the presence of a defect in a specific section of the tested material occurs, signaling circuits, that is, monitors are used.

This circuit is based on a time coincidence of the echo or one from the error reflected pulse and a gate pulse, sometimes called a "Aperture" is called. The position and the width of the gate impulse corresponds to Time of passage of the ultrasonic pulse through a desired section of the controlled Material whose faults are to be signaled. These circuits work Satisfy as long as they are only in a YES-NO manner the presence to signal an error whose echo exceeds a response value. However, as soon as a differentiation of the error size according to different response values the echoes is demanded, difficulties arise due to the possibility of Signaling of an error that results in an echo with a higher voltage level, as well as in a lower switching level there. Namely, it is to be considered draw that the echo edges show different, but always finite run-up times, with the result that an echo with a higher voltage level is replaced by a lower one Voltage level passes through earlier.

Depending on the frequency of the ultrasound, the design of the test head and the acoustic coupling, the duration of the rising edge can be 10 7 to 10 s. be.

The object of the present invention is to specify a circuit, which solves the difficulties indicated above in a simple manner.

The above-mentioned disadvantages are achieved by a circuit according to the Invention eliminated, which consists of one or more monitors, at its entrance or whose inputs a selector for the response value is connected, with a Output connected to one of the inputs of a gate circuit with two inputs is connected to the second input of the output of a gate pulse generator is, the output of the gate circuit with two inputs with the help of a right-hand pulse generator and through a subsequent differentiating circuit to the first input of another Gate circuit with two inputs is connected, the second output with one Voltage generator connected i: t while the output the gate circuit with two inputs using a circuit with a switching element, e.g. a Relay, connected0 The device according to the invention solves the problem with several Response levels, the number of which can be as large as desired. The circuit according to the invention can be used for any number of monitors that are mutually parallel are switched. Each monitor is set to a response value and activated the monitor with the lower neighboring response value, whereby he himself through operates a monitor with a following higher switching level or response value will. This simple way of working is made possible by the fact that each monitor has one Right ¢ kimpuls generator, which is activated when the signal the preselected response value is reached at the input of the monitor. Every response value a square pulse with a certain duration is assigned. The essence of Invention lies in the conversion (adaptation) of the pulse height to the pulse length.

In the drawings is an example of the circuit of an inventive Monitor shown. They show: FIG. 1 echoes for the switching of monitors and , Impulses in the monitors the resolution of three different response values represent; Fig. 2 is a block diagram and a mutual connection of the individual monitors for sorting the echoes according to height in three response groups, and Fig. 3 shows a sequence of pulses in the circuits.

Fig. 1 illustrates a waveform or function used in the circuit of monitors occurs, which is responsible for sorting the echoes according to their height into three response levels u1, u2 and are determined in the event that the echo has a height that is up to intervenes in the third response voltage level. which in the present case is the highest Voltage level is. In this case, monitors 1 ~ 5 and 16 will be the lower ones Pickup values, that is, with the first and second voltage level, in action set. The ultrasonic echo (Fig. La) has a rising edge that has a certain Takes time that corresponds in particular to the frequency of the ultrasound. In each Monitor is produced in a square pulse generator 3 (Fig. 2) a square pulse, the beginning of which coincides with the instant tl at which the height of the echo denotes relevant switching level or response value is exceeded.

The square pulse generated in generator 3 has a certain duration (Length), the longer, the higher the response value. In the monitor with the At the lowest response value ul, a square-wave pulse with a duration of .Z is generated (Fig. ib).

In the monitor with the second response value u2, which is the edge of the echo reached in time t2, a square pulse is generated that lasts for the time # + ## 2. Similarly, a third response value u3 appears in the monitor in time t3 Square pulse with the duration of # + # 3.

In the circuit of the monitor according to the invention (Fig. 2) are due the clarity of the mutual Durohschalt three monitors 15, 16 and 17, which is used to sort the echoes according to their height into three voltage response levels u1, uS and u3 are determined. The circuit of all three monitors is equal. A practical circuit, however, is not available on this number of monitors limited and therefore not limited to the number of response voltage levels. the The number of response voltage levels can therefore be as large as desired.

Rectified signals come from the output of an amplifier of the materials testing device and filtered pulses (Fig. 3a) to the input 8 of the individual selector of the response value at.

Signals (FIG. 3b) which determine a specific pass through this selector Exceeding the selected response voltage level. The input of selector 1 of the electrical Switching voltage is at one of the inputs of a gate circuit 2 with two inputs connected, the second input connected to a gate pulse generator 14 is. The time slot and the duration of the gate impulses correspond to the material section, from which errors are to be signaled with the help of the monitor.

If there is a coincidence of the gate pulse (Fig. 3c) and the echo (Fig. 3b), a pulse appears at the output of the gate circuit 2 (Fig. 3d). A two-input AND circuit of the NAND type is advantageously used. In this Trap arises on the output a pulse with a negative polarity, which continues to the square pulse generator 3, which is a generator of square pulses with the duration of r or # + A t (Fig. 3e), depending on whether it is a Monitor with a first or a further response level acts. At the exit of the Square-wave pulse generator 3 generates right-hand peak pulses with a negative polarity (Fig. 2e) removed, which go through a differentiating circuit 4, at its output then a needle pulse with a negative polarity and a pulse with a positive polarity occurs in relation to the instantaneous Switching process t1 is delayed by the time #. This pulse is applied to input 9 of another Gate circuit 5 with two inputs, for example again a positive one AND circuit of the NAND type. To a second input 10 of the gate circuit 5 with two inputs is either an opening voltage or a reverse voltage created. In the case of a positive gate circuit 5 with two inputs (NAND gate) is it a voltage of a logical t? 1fl or a voltage of a logical "O". As far as it is a monitor with the highest required response level acts, the second input of the gate circuit 5 with two inputs to one Generator 13 connected to a positive voltage of a logic "1". This is in the exemplary embodiment the case at input 10 of gate circuit 5 in monitor 17 for the third switching voltage level u3. In the monitor 15 with the first switching voltage level ul is the second input 10 of the gate or blocking circuit 5 with two inputs on connected to the output 11 of the square-wave generator 3 in the monitor 16, and with a higher, that is, the second response level u2, which is a square pulse is of the duration of # 1 + A1r2 (Fig. lc). Similarly, the second input 10 is the Gate circuit 5 with two inputs in the monitor 16 with the second response level u2 to the input 12 of the right pulse generator 3 in the monitor 17 with the third Response level u connected, where a square pulse of duration # + t'3 (Fig. 1d) is located. If the echo at the output of the amplifier (Fig. La) is so large that all three levels appear at output 11 of the square-wave generator 3 in the monitor 16 with the second switching level u2 a pulse of a negative polarity a logical "O" whose duration # + ## 2 is longer than the duration 1 of the square wave signal, that in the square pulse generator 3 is created. That's why in the moment t1 + # the arrival of the pulse from the differentiating circuit 4 at the first input of the Gate circuit 5 with two inputs this circuit is blocked, and at its output there is no impulse which is sent to an output Kippschaltuiig 6 with a switching element 7 could pass over. This is analogously the case in monitor 6 at the second response level u2, whose gate circuit 5 with two inputs in the interval from t2 to t2 2 through the voltage from the output 12 of the square wave; pulse generator 3 in the monitor 17 is blocked is.

The case is different in the monitor 17 with the third response level U3. The second input 10 of the responsible gate circuit 5 with two inputs permanently connected to the generator 13 of the opening voltage. In our case it is a logical "1". The gate circuit 5 was in action set. The pulse from the output has the trigger circuit 6 with the switching element 7 put into operation.

The operation of the above circuit can be explained in more detail of Fig. 3 will be described. In input 8 of counter 1 of the response value signals from the output (Fig. 3a) of the amplifier are fed in. If the height of the ultrasonic pulses (Fig. 3e) arriving in the time interval of the gate pulse If the response level exceeds u1, it appears on the output of the square-wave generator 3 a pulse according to FIG. 3d. This pulse triggers the square-wave pulse generator in the time period t1 3, which is usually formed by a monostable multivibrator, on its output Square pulse of duration # (Fig. 3e) is obtained. By differentiating it the course shown in Fig. 3 £ is obtained. With an open Gate-5 with two inputs is what always happens when through the Selector 1 of the response value in the monitor 16 for the second response level no dem second response level u2 corresponding impulse has come through, the impulse through the gate circuit 5 slides to the input of the bistable multivibrator 6, the overturns in the time interval t + HL and returns in the time interval to.

The reversible overturning of the bistable tilting circuit or multivibrator 6, for example, by connecting its second input to the gate pulse generator 14 causes the gate impulses. The voltage curve at one of the outputs of the breakover circuit 6 can be seen from Fig. 3h.

The circuit described can either be integrated with logic Circuits can be realized with semiconductors or with electron tubes. The circuit can not only be used in material testing, it can also be used on various areas of ultrasound measurement technology, in medical diagnostics and the like find application.

Claims (4)

Patent claims - 1 circuit for signaling and differentiating the level of the ultrasonic pulses received in a certain time interval, d a d u r c h g e k e n n -z e i c h n e t that the circuit through one or more Monitors (15, 16, 17) is formed that starting from the input of each monitor (e.g. 15) a selector (1) of the response value is provided, the output of which is marked with a the inputs of a first gate circuit (2) is connected to two inputs, with the second input of which is connected to the output of a gate pulse generator (14), that the output of the gate circuit (2) with two inputs via a square pulse generator (3) and a differentiating circuit (4) following behind this to a first input (9) a further gate circuit (5) with two inputs is connected, whose second input (10) to the output of the rectangular pulse generator (3) of the monitor (e.g. 16) is connected with a following response value or switching level, and that the output of the gate circuit (5) with two inputs with the help of a breakover circuit 66) is switched through with a switching element (7). 2. A circuit according to claim 1, characterized in that the monitor (e.g. 17) with the highest response value is the second input (10) of the gate circuit (5) with two inputs to a direct current generator (13) of the opening voltage is closed. 3. Circuit according to claims 1 and 2, characterized in that that the @ real pulse generator (3) is a monostable Multivibrator is, with a greater time constant, the greater the response value of the responsible Monitor is. 4. Circuit according to claims 1 to 3, characterized in that that the breakover circuit (6) for the actuation of the switching element (7) as a bistable Tilt circuit is switched with two separate inputs, one of which is connected to the Output of the gate circuit (5) and the other connected to the gate pulse generator (14) is.