DE1473849A1 - Ultrasonic device for measuring the thickness of objects - Google Patents

Description

4 DÜSSELDORF, DIPL.-ING. H. MAHSCH i ™ d _B may «* stras _S « si

TBLEroi * era «4e PATENT ADVOCATE

P 14 75 849.9 H73849 Rochar Electronlque

New registration documents

"Ultrasonic device for measuring the thickness of objects"

The invention relates to an ultrasonic device for measuring the thickness of objects by the reflection method.

Usually used to measure under a millimeter The resonance method used at lying thicknesses has numerous disadvantages. First of all, the object to be measured is allowed to do so The forming material does not absorb too much, so that there is a resonance phenomenon between the opposing surfaces can be generated, which must also be sufficiently flat and parallel. Since multiple resonances can occur, particular difficulties of interpretation arise, which entail an intricate apparatus for carrying out the process which are often difficult to use. (U.S. Patent 3,053,080).

The reflection method is used very widely; however, their use is to measure thicknesses in excess of limited to two millimeters. This is due to the difficulty

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New documents ^ 7 _§ , ^ _{2 N} ,,

speed, which the production of ultrasonic pulses beetet, the width of which is small compared to the duration of their transit time through the material. The maximum frequency of the acoustic vibrations used is about 15 MHz. The duration of the pulse is approximately 0.5 microseconds. The amount of time separating two consecutive ground echoes, i.e. two echoes coming from the side of the object which is opposite to that which is in contact with the transducer is to that Thickness of the item proportional. For steel, a thickness of one millimeter gives two µm o.3 microseconds apart different echoes.

With such devices, the thickness can be read in three ways, namely on a cathode ray tube, on a split drum, or on a pointer device. (French patent specification 1 Io5 6j51; British patent specification 813 039). Every type of material is a calibration and several previous settings are required before each measurement. In addition, especially in the case of devices with a cathode ray tube, the reading of the result is proportionate uncomfortable and imprecise

In order to be able to measure even very small thicknesses, a very high ultrasonic frequency must be used, reading the result becomes more and more difficult as the distance between the individual echoes is shortened accordingly. For this reason, the reflection method has so far only been used for steel above a thickness of about 2mm, for example, Or else the devices used were so sensitive that each measurement was one or even several Calibrations had to precede. <

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The invention seeks to solve the problem of an ultrasonic device for measuring the thickness of objects to create; "t> ei" which the display of the result in numerical form takes place, so the difficulties outlined above are avoided.

The ultrasonic device according to the invention for measuring the thickness of objects by the reflection method, which has a piezoelectric transducer, which is on the one hand in acoustic contact with the test object and on the other hand with a transmitting and a receiving circuit is connected, which mainly consists of an amplifier and bistable trigger circuits for the selection two specific ground echoes and for the delivery of a measuring pulse with the duration ^. t that the two bottom echoes

there
separates, is characterized in that the measuring pulse is fed to a pulse duration multiplication circuit which essentially comprises a capacitor which is charged by a first current during the time ^ t and then discharged by a second current, with a ratio of the first current to the second, which is adjustable and proportional to the propagation speed of the acoustic waves in the material to be examined of the object to be measured, after which the stretched pulse emitted by the multiplier circuit is fed to a numerical timer which indicates the desired thickness

It is desirable to be able to automatically check the function of the device at all times. This functional check can be implemented according to the invention by means of a further development which is characterized by a malfunction indicator comprising a group of bistable trigger circuits has for the selection of three consecutive

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Ground echoes and for the delivery of a measuring pulse of finer duration equal to the interval between the first and the third echo and a control pulse of a duration equal to the time interval between the first and the second echo, further characterized in that the measuring pulse of a first pulse duration multiplication circuit with a multiplication factor "X" is supplied, and that the control pulse is supplied to a second pulse duration multiplication circuit with a multiplication factor of "2X" so that the return of the pulses emitted by the multipliers form a first and a second reference pulse in the order in which they arrive which is only supplied to the input of a bistable multivibrator together with the first selected echo, which sends an output signal with a duration equal to the time interval between the first echo and the first reference pulse to a third pulse duration multiplier circuit with a multiplier Aktor ¹¹ I + jnJ ¹ emits, so that its output pulse return pulse represents a third reference pulse, and that the second and third reference pulse is fed to a logic comparator circuit, whose acoustic or light output signal then signals a malfunction to the operator if the second reference pulse is later than the third arrives

This puncture check can be carried out according to the invention but can also be realized by means of a further development which is characterized by a malfunction display, the a group of unstable tilting circles for the selection of three having successive ground echoes and for the delivery of a measuring pulse with a duration equal to the time & bstand between the first and the third echo as well as a control pulse with a duration equal to the time interval between

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see the second and the third echo, further characterized in that the measuring pulse is fed to a first pulse duration multiplication circuit with a multiplication factor "X + 1" and the control pulse of a second pulse duration multiplication circuit with a multiplication factor "2X +1", that the trailing edges of the Pulse duration multiplication circuits form a first and a second reference pulse according to the sequence of their arrival, of which the former is fed together with the first selected echo to the input of a bistable trigger circuit, which emits an output signal with a duration equal to the time interval between the first echo and the first reference pulse to a third pulse duration multiplication circuit with a multiplication factor "1 + .'xJ ¹ , so that the output pulse trailing edge represents a third reference pulse, and that the second and the third reference pulse of a logic comparator circuit whose acoustic or light output signal then indicates a malfunction to the operator when the second reference pulse arrives after the third reference pulse.

Thanks to these measures, the numerical display of the thickness of the object is thus obtained using a Counters and timers with low performance, which thus are cheap, with the correct functioning of the device being constantly monitored.

It can thereby be achieved that the operator always has information regarding the quality of the measurement made. (This information is expediently formed by the lighting up of a neon lamp in the event of faulty work.). ; _: jl; I '

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The malfunction display device takes namely, a comparison between the duration of the measuring impulses and the control impulses for each work cycle, which have been obtained on the output of three successive selected ground pulses, such that checked whether the duration of the control pulse except for an error coefficient half as long as the duration of the measuring pulse. As a first approximation, these echoes are the same Time interval '_ t, in reality, however, if A t is the time between the first and the second echo, it must consist of multiples Founding (l + £.) &. t the time between the second and third echo, where £ _ be positive or negative can. In order for a measurement to be considered good, the absolute value of £> less than 2 «- which is determined by the circuit for comparing processes, which determines whether the first two are separated from each other by a time of size X.f. Δ. t separate reference pulses the third Reference pulse which is separated from the first reference pulse by a time which is practically equal to 2 X. <* ~. k. t is input one or not.

In addition, since the third reference pulse is delayed by a time T before it is transmitted to the circuit for comparing events, this comparing circuit actually determines whether / <tA »t / <. 7 / X + 2 <κ. At is, that is, whether the error committed during the measurement is smaller than the sum of an absolute error T ~ / X and a relative error 2 * ». Ot is.

The invention is explained below by way of example with reference to the drawing.

Fig. 1 shows the block diagram of the device according to the invention;

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Pig · 2 shows the Pig at various points in the circuit. I signals picked up;

Fig. 3 is a circuit for multiplying the Duration of an impulse.

In Fig. 1 Io is the plate whose thickness is to be measured, and 12 is a piezoelectric transducer which is in acoustic contact (for example by means of an oil drop) with the plate Io . A transmitter 14 triggered by a time base 16 is connected to the transmitter 12, which is also connected to a receiving amplifier 18, which is followed by a detector and filter sound system 2o and a trigger circuit 22. Behind the circuit 22 there is a gate 24 with an electrode 25 for controlling the closing and an output which is applied to the input of a series of three bistable flip-flops 26, 28 and 3o, each of which has an electrode 27, 29, 31 for zeroing which is connected to the output of the time base 16. The output Γ of the flip-flop 26 and the output 1 (Spg in FIG. 2) of the flip-flop 28 are both applied to the input of a logical AND circuit 32. The output of the flip-flop 3o is applied to the electrode 25 of the gate 24. The output of the flip-flop 28 is also connected to the input of a circuit t) 4 for multiplying the duration of the type described below with reference to FIG. The multiplication coefficient X of the duration of the circuit 34 can vary between about 25 and 75. The output S, ₂ (Fig. 2) of the circuit 32 is applied to another circuit 36 for multiplying the duration which has a multiplying coefficient of 2X. The circuits 34 and 36 are connected to the output of the same device 38 for regulating the current, the changes of which reduce the value of the

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Determine parameter X which is included in the multiplying coefficients of the duration of the circuits 34 and 36. The output of circuit 34 is triggered at the input of a Oscillator 4o, which is connected to a three-digit decimal counter 42. In the special case of the 1, the decimal counter 42 can display thicknesses to a tenth of a millimeter up to 99> 9 millimeters.

The output signals S, ^ and S>. (Fig. 2) of the multiplication circuits 34 and 36 are applied to differentiating circuits 44 and 48, respectively, which supply a negative pulse at the moment of the occurrence of the falling edge of the signals generated by the multiplication circuits 31 and 36. The output pulses of the differentiating circuits 44 and 48 are applied to the input of a logical OR circuit 46, the output of which is connected to the electrode for returning to the passive state of a flip-flop circuit 5o, while the electrode for producing the active state of the flip-flop circuit is connected via a differentiating circuit 52, which is designed like the circuits 44 and 48, is applied to the output Γ of the flip-flop 28. _{The pulse S 1} supplied by the bistable multivibrator 5o. (Fig. 2) is applied to a third stage for the multiplication of the duration, the multiplication coefficient of which is equal to (^ + 1), the coefficient «~ being, for example, o, ol. The output signal Sc ^ (Fig. 2) of the stage is applied to a differentiating circuit 56 identical to 44, which supplies a pulse S ^ and is connected to a delay circuit 58 which introduces a delay of one microsecond. The output signal S ₁ -Q of the delay circuit 58 is applied to the input for transferring a bistable multivibrator 60 into the active state, the input 6l of which for returning to the passive state with the output of the time

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base l6 is connected. The output of the flip-flop 60 is sent to the electrode for controlling the opening of a gate 62, the input of which is connected to the output of the logical ODEh circuit 46. The exit of gate 62 is at the input for transferring a bistable Flip circuit 64 is applied to the active state, which has an input 65 for returning to the passive state which is connected to the output of the time base l6. The bistable flip-flop 64 can be a neon lamp 66 light up when it is in the active state.

The time base l6 supplies pulses, the frequency of which is a few tens of Hz. With each pulse delivered by the time base 16, the transmitter 14 applies a voltage pulse of a few tens of volts to the piezoelectric transmitter 12, the duration of which is approximately one microsecond. As a result of this excitation, the piezoelectric transformer 12 vibrates at its natural frequency (which is selected in the inverse proportion to the thicknesses to be measured between 5 and 15 MHz). The transmitter 12 is generally provided with a damper made of a heterogeneous material (dense powder embedded in a thermosetting plastic), so that the free oscillations of the transmitter last at most a few periods. A short acoustic pulse is applied to the plate Io, whereupon a series of different echoes (surface and ground echoes) are received by the transmitter 12 and transmitted to the receiving amplifier 18. After detection and filtering by stage 2o, a signal Sp shown in FIG. 2 is obtained, where t is the transmission pulse, t, a surface _{echo, t, to t c} a series of ground echoes, t> a ρ 5 ο

other surface echo, etc. are. Since only the bottom echoes to Making the thickness measurement are interesting, the echo must t. be ignored.

- Io -

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At the time of transmission, the time base 16 supplies the flip-flops 26, 28 and 3o with a pulse for zero setting, which converts the flip-flops into a passive state. Under these conditions, the gate 24, which is closed when the flip-flop Jo is in the active state, is opened.

The totality of the flip-flops 26, 28, and 30 forms a binary divider stage. The first pulse applied to this stage is the pulse t, since the flip-flops 26, 28, 30 have been returned to the passive state in synchronism with the pulse t_. The flip-flop circuit 26 has an active state at its output 1 during the time-r points which separate the pulses t ^ - tp on the one hand and t, - t ^ on the other hand. The output 1 of the flip-flop 28 is under these conditions in the active state during the time that the pulses tp and t. separates. The signal S ₂ Q (Fig. 2) represents this state.

At the output of the logic UND circuit 32, which receives the output variable 1 of the flip-flop 28 and the output variable T of the flip-flop 26, the pulse, S-, appears whose duration is equal to the time between the pulses tp and; ν-t, is. When the pulse tu is applied to the flip-flops 26, 28 and 30, the flip-flops 26 and ^; 28 again into the passive state, while the tilting tray ¹ Γ device 30 changes over to the active state, which causes the gate 24 to close. Under these conditions, the various echoes received by the transmitter 12 after the echo tu are not transmitted to the computing circuits nL'ct / v

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Let At be the time between the echoes t, and tp and (l + £ L) & t be the time between the echoes t ^. and called t ^. As a result, the signal S ₂ g has a duration of (2 + £) £ \ t and S, ρ a duration of ^ t. The signals S ^ g and S, ₂ are then applied to the circuits for multiplying the duration 3 ^ and 36.

According to a particular characteristic of the invention, a circuit for multiplying the duration of a pulse is characterized in that it contains a capacitance which is charged during the duration of the pulse by the difference (L · - Ip) ™ of two currents I. and I ₂ and can then be discharged through the sole current I. until it assumes its original potential again, the total time during which the capacitance is charged to a potential decribed from its original potential is determined by an amplitude comparison circuit with a binary output, this The binary output variable is the pulse sought, the duration of which is Ipt / I.

By means of such a circuit, the duration of the pulse £ can be multiplied by a considerable coefficient, for example by 100 or 200.

By way of example is described below with reference to FIG. 3, such a multiplication circuit.

In Pig. 3 , S. is a transistor pnp, the base of which is connected to a voltage source supplying a potential of +6 V , while the emitter is connected to a resistor R. supplied by a voltage source of +12 V. A capacitor C is placed between the collector of the transistor S and the body. The emitter of transistor S.

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is on the other hand connected to the emitter of a transistor S ₂ , which is similar to S. and whose collector is shorted to ground.

The capacitor C is connected to the collector of a transistor npn S ^, whose base is connected to a voltage source of -6 V and whose emitter is connected to a resistor Rp fed by a voltage source of -12 V. The emitter of the transistor S- is also connected to the emitter of a transistor Su , which is similar to S, and whose collector is shorted to ground. The base of the transistor Su is fed by an input pulse source IS, which brings the potential of the base from -5 V in the absence of pulses to -7 V during the duration of a pulse.

The capacitor Io, on the other hand, is connected to the base of a transistor npn S ₁ -, the emitter of which is shorted to ground, and the collector of which is connected to the base of the transistor Sp and a resistor IU which is fed by the voltage source of -12 V. The output pulse of the computing circuit formed in this way is applied to the collector of the transistor S ₁ . removed.

In the absence of an input pulse at the base of the transistor S ^ the voltage of -5 V applied to this base makes the transistor Su conductive. A voltage of -5 V practically appears at the emitter of S ^, whereby the transistor npn S ^, whose base has a potential of -6 V, is blocked.

The through the transistors S ₁ , S ^, S ,. and the condensate

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Sator C formed arrangement forms a negative feedback loop, the ^ at the terminals of the capacitor C an open circuit voltage that is slightly larger than the unlocking voltage of the

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of the transistor S ₁ - is. The transistor S. supplies the basal current required for the operation of the transistor S _1. It should be noted that if the current flowing through R i changes for any reason, the quiescent voltage of capacitor C and the base current of transistor S ₁ - flowing through S are thereby changed very little while transistor Spfast absorbs the entirety of this change.

When the input pulse source applies a pulse of duration _t to the base of the transistor Su, which is similar to that shown in FIG. 3, the transistor Su is blocked, while the transistor S i becomes conductive. Since the transistor S, operates in a common base circuit, a current Ip determined by the resistor R «and the two voltage sources feeding the transistor flows through the capacitor C and the transistor S.,. The voltage at the terminals of the capacitor C decreases immediately. This change is amplified by the transistor S ^ and the transistor S_, so that the transistor Sp is quickly blocked, while a current I ₁ flows through the transistor S. in base circuit, which flows through the resistor R and the two voltage sources for supplying the transistor is determined. During the duration of the pulse t_ , the capacitor C is charged with a current I. - I «.

In the particular embodiment described, Ip must necessarily be greater than I. As a result, the voltage across the terminals of the capacitor C decreases linearly like this is shown in FIG.

At the end of the _t pulse, the charge on capacitor C has changed by Q - Q = (Ip - I.) t. As soon as the pulse £ disappears, the transistor S becomes ₁ . immediately conductive again, while the transistor S i is blocked and S_ and Sp blocked

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stay. Under these conditions, only current I feeds. the capacitor C further.

The voltage at the terminals of C therefore increases linearly until it reaches the unlocking threshold of transistor S again. Exactly at this moment the transistor Sjwleder becomes conductive and a rapidly increasing current flows through the resistor R ^. The effect of this is that the transistor Sp becomes conductive and almost the entire current I. is diverted through this transistor in order to allow only the current required _{to feed the base of the transistor S 1 to flow through the transistor S1.} At this exact moment one finds the idle state in which the circuit was before the application of the pulse with the duration £. The time T which the capacitor C needs to lose the charge (Q - Q) absorbed during the pulse of duration £ and thus to return to its initial state is defined by 1..T = QQ. These relationships arise immediately T / t = I ^_2/1! - 1. Since the supply voltages of the transistors S ₁ and S are equal in absolute terms, T / t = (R ₁ ZR ₂ ) - 1. The one at the collector of the transistor S ₁ . appearing square pulse has a duration which is equal to the blocking time of the transistor, namely (t + T), ie (R ₁ ZR ₂ ) t.

The device according to the invention thus forms a circuit for multiplying the duration, which supplies an output pulse, the duration of which is proportional to the duration of the control pulse £, the coefficient of proportionality in the example under consideration being equal to the ratio of the resistors R ₁ and R ₂ . Since R ₁ may be compared with R "very large, the circuit thus produced can multiplication

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the duration have a multiplication coefficient that can reach several hundred.

In an ultrasonic device for measuring the thickness of objects, the interest of the circuit 34 for multiplying the duration is that a counter 42 with inferior operating characteristics (which is cheap) for measuring the duration of the pulse S _? g can be used, the Dayer of which can be tens of nanoseconds at low thicknesses.

In the special case of the multiplier circuits J> k and 36 used in the device according to the invention, the charging currents I ¹ «and I" of the capacitors of circuit 34 and circuit 36 have a constant value with I "g = 21 'j while the discharge currents I ¹ , and I "of these capacitors are variable, where I ^1. and I". is. With a single current regulating device 38 one can therefore constantly change the current I ₁ and give the multiplication coefficient of the circuits 34 and 36 values X or 2X, where X changes from about 25 to 75, as explained above.

In practice, each of the resistors R, is formed by a resistor and a transistor that are stacked on top of each other are tuned, while the base electrodes of these transistors are from the same current control potentiometer be fed.

If one considers the multiplication coefficient X of the multiplication stage 34 gives a value which corresponds to the propagation speed of the acoustic pressure waves (which generally with the usual coupling between the

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carrier and the object by means of an intermediate liquid are to be considered alone) in which the plate Io forming Material is proportional, a pulse is obtained at the output of stage 34, the duration of which is only dependent on the thickness of the plate is proportional. The triggered oscillator 4o, to which the pulse S, j, is applied, therefore supplies the counter 42 a number of pulses precisely proportional to the thickness being measured. Using a sample of precisely known thickness, which is similar to the plate Io, one can easily adjust the coefficient X. Change Φ until this thickness is indicated by the counter 42. The thickness of the plate Io can then be measured immediately.

At the output of the differentiating circuits 44 and 48 appear the first two reference pulses S ^, which are synchronous with the falling edges of the signals supplied by the multiplication stages 34 and 36. These signals have the duration X (2 + £ _) At or 2X.A. Under these conditions, the pulses Su ^ have a time interval of Xt ^ t.

The flip-flop 50, which changes to the active state at the moment of the occurrence of the first ground echo tp, changes to the passive state again at the moment of the occurrence of the first reference pulse supplied by the OR circuit 46. The duration of this pulse S is therefore either 2X.At or (2 -t) X «^ - t, depending on the polarity of the measurement error coefficient.In reality, the signal S ₁ - is the shortest of the signals S_ ^ and S, g, so that the through the circuits 60 to 64, the symbol of this coefficient £ does not need to be taken into account for the comparison of processes.

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The pulse S ₁ - is applied to the stage for multiplying the duration 5 ^, the multiplication coefficient of which is equal to (l + ^), where o \ in the example under consideration is o, oil. The signal S ^ ₁ . has a rising edge that corresponds to the rising edge of signal S ₁ . is synchronous, but its duration is 2 o ^ .x.zit greater than that of the signal S (-. The rear front of the signal S ^ _1. appears at the output of the differentiating circuit 56 in the form of a pulse S ^ g, which the third reference pulse forms.

It should be noted that the multiplier circuit 54 is somewhat different from the circuits 35 and 36 shown in FIG. In the case of circuit 54, it is desired that the duration of the output pulse S ^ is practically \% greater than that of the input pulse S ₁ . is, and it is then easier to charge the capacitor C with a single current I with a precisely determined value during the input pulse Sp- and then to discharge it with another single current with the value I loo. The modification which must then be made to the device shown in Fig. 3 is to connect the base of the transistor S to a blocking circuit (formed by a transistor) which receives the input pulse and the transistor S a during the whole Can keep locked for a duration of £. In general, such a modification must be used if one wants the multiplication coefficient to be equal to (m + 1), where the term m can be either very small (but not zero) or very large.

If again FIG. 1 is taken into consideration, it can be seen that the third reference pulse S_g is applied to the input of the Kipj circuit 60 is only applied after a delay /,

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whose value in the present case is one microsecond, (which after a multiplication of orders of magnitude & Sig 7o corresponds to the transit time through 0.1 millimeter of steel).

As a result, the flip-flop S ^ - , which would be brought into the passive state by the zero setting pulse supplied by the time base 16 at the moment t of the transmission, goes into the active state at the moment of the occurrence of the pulse S _{1 -Q supplied by the delay circuit 58} .

Under these conditions the gate 62 is closed at the precise moment of the occurrence of the second reference pulse Shg. In the special case of the cycle of the signals E shown in FIG. 1, the flip-flop 64 remains in the passive state and the neon lamp 66 remains extinguished, indicating that the measurement is correct. ;

If, on the other hand, the second reference pulse S ^, / - occurs after the pulse S ₅ -Q during another cycle, it is transmitted through the gate 62 to the flip-flop 64, which causes the neon lamp 66 to light up until the next cycle . This would mean that the measurement made during this cycle is not good and that the operator must change the connection between the transmitter and the object so that their acoustic contact is better and the false echoes no longer interfere with the measurement The safety indicator combined with the thickness measuring device thus forms a comparison logic which indicates that the measurement is good (and the neon lamp 66 has gone out) as long as JX. £ _. At / <. 2ev.X. ^ t +7 ", ie as long as | i. At / <»2owA.t +77" X or as long as the error ε. ^ Xt at the position of the third echo used for the measurement is not greater than the sum of a relative error 2 * \. Δ-t and an absolute error T. / TL is.

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The, invention is of course not based on the above Execution formats are limited, but can vary be modified.

For example, instead of the echoes tp, t ^ and t ^ one could choose the - echoes tp, t, and t ^. The duration of the measurement pulse, the front and rear of which are tp and t, - would then amount to (5 + £) & t, while the duration of the control pulse remains unchanged. One would then use circuits to multiply the duration, the coefficients of which are X and ^ X, so that the shift between the first and the second reference pulse S ^ is always e_.X .At. It should be noted, however, that this solution has the disadvantage that it requires a greater transmission power than in the case of FIG. 1 and / or more complicated reception amplifiers and filters. In general, the embodiment of FIG. 1 is therefore preferable.

Furthermore, instead of the echoes tp and t, the echoes t and tj. This would be achieved by applying the output 1 of the flip-flop 26 instead of the output T to one of the inputs of the AND circuit 32. The duration of the control pulse would then be (I + C) ^ t. The circuits} 4 and } 6 would then receive multiplication coefficients for the duration of (X + 1) and (2X +1), so that the falling edges of the pulses supplied by these multiplication circuits again in time by X. £ . (St are shifted, ie that the time separating the first two reference pulses is directly proportional to the measurement error coefficient t.

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The multiplication circuits used would then be designed like the circuits 54 of Fig. 1, i. they would take the form of the modifications described above with reference to FIG. For the sake of simplicity the embodiment of FIG. 1 is therefore preferred.

From the description of the two above design modifications it can be seen that in a device for display the devices for the delivery of the two reference pulses generally a group of switching

φ can include responses which select three specific ground echoes and at the output of these can generate a measuring pulse and a control pulse, one of these pulses has a duration that except for the measurement error coefficient is a whole multiple of the duration of the other, these measuring and control pulses to a first and a second circuit to multiply the duration, their multiplication coefficients are in such proportions that the falling flanks of the multiplication circles supplied Pulses are shifted from one another by a duration equal to the product of the two successive echoes separating time and the error coefficient and the smallest of these multiplication coefficients, these edges

w form these first and second reference pulses according to the order in which they occur.

- patent claims -

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Claims (1)

P 14 75 849.9 (R 42 191 IXb / 42b) Koohar JSleotronique ■ Claims Ultrauchallßorät door Hesoung the thickness of articles according to the Keflexionsmethode that aufweint a piezoelectric transformer which oineroeito communicates with the Heßobjekt in acoustic contact, andereroeito with a transmitter and a is iäupfancuachaltunß connected, the aua mainly a VerotUrker and bictabilen Kippkreioen is for the Selection of two bootiiouter Bodonechoo and for the delivery of a Keßimpulses with the Sauer ^ t, which separates the two bottom echoes "characterized in that the measurement pulse of a pulse duration multiplier (34) is performed, which essentially has a capacitor (ü), which is from one The first current is charged before the time <^ -, t and then discharged by a εν oi ton St ro u, r.it a ratio of the first current to the swoiton, dna adjustable and proportional to the port size (lor ulcuutiochen Vellen in to be examined rintorial of the objects to be named lot, from now that of the multiplier The extended pulse given off by aging is fed into a new numerical time sensor (42) which indicates the maximum thickness. Device according to Anapruoh 1, skillfully linked by a malfunctions ance has for the selection of three consecutive bottom echoes - 2— BAD 809811 / 07.3.4. ·,.,. ;; ^ Un.ürlagen ιλγ ». ? -: ι aö-. · > -Tr. ι j..t. ·. a ^ uändivun ^ r · «· · '· * · and for Uio Abgabe eino tteßinpuloeo (S 28) of a JJauer equal to don j <eitabatnnd table the eroten and the third ücho as well as a Kontrullinpuloee (S 32) of a duration equal to don üeitabatand between the »red and the sveiton UOhO ₉ fern & r that the Ileßinpulo (3 20) of a first Pulcdauervorvioiraohuncnochaltunc (34) with a Yorviolfaohun ^ afaktor "X" is fed, and that the control Pulo of a second Iapulcdauvorfachungsochaltung (36) by means of a multiplication factor ^M 2X * EUgofUhrt is that the return The inpulee given out in the keihonfolgo their temporal incomes form a first and a second reference inpulö (3 46), of which the eroto zuoioaen nit dea eroten uuassov / ole the £ inßanc oinor biotable kippa circuit (50) , which is an announcement ^ rinl with a duration equal to the time limit between de; a eroten üoho and the first Bosugeinpulo to a third - Inpuledauorvcrvielfa chunßoochaltunß (54) nit emits a Vorviolfaohungafaktor "1 4>cX", oo daa whose off ^ an ^ uiiapulerllokflanke represents a third Bezußnimpulo (U 56) _y and that the cwoito and the third bout ^ sinpulo of a logisohen; ».T Comparative Crachaltuni; (60; 62) su ^ efu} irt is "whose alnioti- ': ■ sches or Lichtauo ^ an ^ oaißnal, then the Bodienunßspereon egg A malfunction si ^ naliated, uenu the second ob ^ oinpule epUter when the third arrives. . Device naoh Annyruch 1 »marked tiurc! I eino malfunction-. Advertisement that lists a group of biutaMl ^ r Kippkroiae (26; 2ύ \ UO) for the selection of three successive Uodenochos and for the delivery of aoo üeüiopulsos (S 23) with a duration equal to the "oitatotnnd ewiochcn dea" i \; ton and the third echo as well as a control inpulceo nit «iner dcuer equal to the time ahotand cwioohon dom second and oeu third Hoho, £« rn * r d & i characterized by »that dor MeJJiapulo an erotic Zupule · Äauerverviolfaohun ^ oocnultune (34) is carried out with one "BATH - 80981 1/073 1 * 73849. Ycrrielfaehuiigefaktor ⁹ X ♦ 1 · and the XontroUiapul ·, • liier a wider lapuladajierYervielfacnungaaohaXtung (36). with min · * deficiency factor "2X ♦ 1% AaA dl · BUoJofflanken represent the lapule given by the Xapule long-term multiplication according to the order of your arrival 2cho of the input elnea bistable Klppkreiaea (50), which emits an Auagangeaignal Bi.t a duration equal to the other Abatand eviaohen the ereten Beho and de »eraten Besugelapule to a third Inpuladauervrvlel focussed hold (54) old a yorrlelfactor ⁰ ^) · eo DAA whose AuagangaiapularUoldLanke a third Beauga "Inpule (8 56) daratellti and daft the aweite and the third Beaugeiapule a loglaohen Terglelohereahaltunfi (60 | 62) augefUhrt whose akuatlaohea or Llontauagangaal ^ Bal then represents Bedlenuageperaon a Pehlfunktloa anseigt ₉ when the other Beaogalnpula near the third Beaugeiapula arrives. Oerftt naoh Anopruoh 2 or 9 "Kannaeiobnet Auroh one Yeretfgerungeechaltung (59) alt a tera delay xactor ⁷ ^ _v the swlaehen the banal- » ä delivering the third Beaugeiapula tang (56) and the Yergleieereehaltung (60 »62) geaoneltet Oertt after one of the aneprüone 1 ble 4 _t daduroh kennaeiohnet »that the ZapuladauerTerrlelfaehungaeonaltung a · power source (-11), which · to the · Kleaaen of an distributor attitude altogether let branches, whose • rater la legs an ereten Trane la gate ( S 1) la Barteeohelung and a KOndeneetor (0) and its a further a · «awel · ten translator (Q 2) in XoUakteraoaaltuag contains» as the TCondaator (0) old the Biogang a Y «retarkera (85) old - 4 ·.; .. 809811/0734 bad original a Sohwellanwert connected let «whose output is connected to the dt · Baals doa swelten transistor · (S2), so that this arrangement is a negative feedback ashlelfe SlIdSt ₉ which the voltage at the clear dso capacitor (C) to a certain quiescent value with» the something ςτ & 0 · τ as the Eatoperrungsschwelle of the amplifier (S5) is "and that a Strooquelle (+12) continues, which is applied to the lines of a second inverter circuit old branches" of which the first in series the capacitor (C) and a third transistor (ti3) 1 »basic circuit, while the second branch formed by a fourth translator (34) lot» whose Baals old the su stretching Kingangsia pulses are fed by a Stroaquelle (IS) »so that the lepulae the fourth Traneistor (ί > 4) block while the third transistor (S3) becomes conductive and since the duration of the amplifier increases the duration of its output pulse. Device according to claim 5 sit slnor lapuladauervervielfaohungesohaltung · whose terrlelfaohungakoafrisleat has the pore (1 ♦ m) , thereby gakenaselchnot »da dless SohaXtung In combination old the first transistor has a binary control circuit whose input is connected to the pulse source, and there is no pulse source ^ angelapulees the binary circuit assumes a passive state and since the first tranaletor la brings the state of the hold "while every XUr the duration of an in-going pulse an active so" atand anniniat and thereby blocks the first transistor " 0 0 9 8 1 1/073 * \