FR2526167A1 - Meter for resolving power of ultrasonic source - generates adjustable reference pulse doublet triggered by sync. pulse - Google Patents

Abstract

The resolumeter is intended for measuring the resolving power of an ultrasonic station such as is used for detecting discontinuities in materials. The resolumeter is connected by a single line to the ultrasound station and generates a doublet of reference pulses triggered by the reception of a sync. pulse (6) from the station. The time intervals separating the two pulses of the reference doublet and separating the reference doublet from the synchronisation pulse are adjustable. The pulse generator of the resolumeter is a calibrated pulse generator triggered on one hand by a direct transmission circuit of the sync. pulse and on the other hand by a delayed sync. pulse transmission circuit. To measure the intrinsic resolving power of the ultrasonic station two superimposed reference pulses triggered by the sync. pulse are sent to the station. Then the second pulse of the doublet is progressively delayed w.r.t. the first until the two are completely separate. The delay time of the second pulse then corresponds to the intrinsic resolving power of the ultrasonic station.

Description

 The invention relates to a resolutometer and to a method for measuring the intrinsic resolution power of an ultrasound station.

The invention will particularly find its application in determining the technical characteristics of ultrasonic stations, in particular intended for detecting discontinuities in materials.

 It is currently known to use ultrasonic stations to detect, for example, the presence of internal cracks in mechanical parts. The ultrasound station is connected via a cable to a probe placed on the part to be tested. The ultrasound station emits a so-called synchronization pulse which is transmitted to the probe which transforms it into an ultrasonic mechanical pulse, this ultrasonic pulse traversing the material in a preferred direction. As soon as the ultrasonic synchronization pulse encounters a material change, which may be an internal crack, or an external surface of the part, it generates an echo. This echo travels through the room in the opposite direction and is detected by the probe which transforms it into an electric pulse. This electric echo pulse will be displayed on the cathode screen towards the US station.

 One of the essential characteristics of an ultrasound station is its resolving power, that is to say its ability to be able to discern two neighboring echoes. These would for example be produced by a crack close to the external surface of the part as well as by this surface itself.

 Currently, there are devices generating artificial echoes to test ultrasound stations. However, these devices do not make it possible to define or quantify the behavior of the ultrasound station as regards its influence on the resolution power.

There are also special shims which are provided with a series of recesses, which makes it possible to generate neighboring echoes to test the resolving power of the ultrasound station. However, on the one hand the gap between the different echoes is fixed which does not allow the resolution power to be determined precisely and on the other hand, the measurement which is made, concerns not only the position
US but also the cable and the probe. Therefore, it is impossible to determine from the results the resolution power of the ultrasound station alone.

 The influence of the ultrasound station on the resolution is essentially due to two concepts, it is the amplitude response or bandwidth, and the phase response. We know that these two elements condition the quality of the transmission by the ultrasonic station of the pulses without altering their front and their width. However, access to these two parameters is difficult if not impossible because it is necessary to integrate in the measurement the cathode ray tube which can modify the amplitude response, like the phase response.

 Also, we have come to create the notion of intrinsic resolving power. The intrinsic resolution power (PRI) is a new parameter specific to the ultrasound station. Its interest is to be able to characterize and quantify the resolution or more exactly the contribution of the ultrasound station alone to the resolution of an equipment of which it is a part, that is to say an ultrasound station set , cable and probe.

 It is defined in microseconds and corresponds to the minimum time between two perfectly identical calibrated reference pulses, such that these two pulses are separated without ambiguity.

 The advantage of this concept is the access to the role played by the bandwidth and the phase response of the ultrasound station alone.

 The main object of the present invention is to provide a resolver which is an apparatus which very simply allows the characterization of the intrinsic resolving power of an ultrasound station.

The resolver can be plugged directly into the ultrasound station, eliminating the influence of the cable. However, the resolueter can be connected in place of the probe, which thus makes it possible to measure the influence exerted by the cable on the resolution of the station pair with ultrasound cable.

 The intrinsic resolution power of the ultrasound station is determined in microseconds by direct display of the value on the resolver.

 Another object of the present invention is to present a method for measuring the intrinsic resolution power of an ultrasound station by generating two reference pulses, the time interval between them being varied.

 Other objects and advantages of the present invention will appear during the description which follows which is however given only for information and which is not intended to limit it.

 The resolutometer, in particular intended for testing the resolving power of an ultrasound station to which it is connected and from which it receives the synchronization pulse, is characterized in that it has means for generating a doublet of reference pulses triggered by the synchronization pulse.

 The method for measuring the intrinsic resolution power of an ultrasound station which emits a synchronization pulse is characterized in that two superimposed reference pulses are returned to the ultrasound station, then the second pulse is gradually delayed until perfect separation of the two pulses, the delay time of the second pulse then corresponds to the intrinsic resolving power of the ultrasound station.

 The invention will be better understood if reference is made to the description below and to the accompanying drawing which forms an integral part thereof.

 Figure 1 shows schematically the operating diagram of the various constituents of the resolver according to the invention.

 The ultrasonic station is a device which is intended to supply an electrical pulse called synchronization to a probe via a cable, so that the probe transforms this electrical pulse into an ultrasonic pulse. In general. this electrical synchronization pulse is negative and of high value of the order of - 700 to - 1000 Volts. Then, once this transmission has been carried out, the ultrasound station is transformed into an echo detector which is the ultrasound waves reflected inside the room in which the synchronization pulse has been sent. These echoes which are actually first ultrasonic pulses then transformed via the probe into electrical pulses are generally of low value, of the order of one Volt. These echo pulses 3 are displayed on a cathode ray tube 2 which generally equips the ultrasound station 1.

 When the part tested has an internal crack, one can observe on the cathode ray tube of the ultrasound station, the echo which corresponds to the reflection of the synchronization pulse on the internal crack. It is essential to be able to distinguish two neighboring echoes which would correspond for example to two distinct cracks but nevertheless very close to each other.

 The resolver 4 according to the invention is an apparatus which is intended to measure the intrinsic resolution power of an ultrasound station 1. It can be connected directly to the output of the US station, or by using a weak cable. length, in order to eliminate all influences external to the ultrasound station, and possibly by adapting the impedances.

 The role of the resolver 4 will be to send back to the ultrasound station 1 a doublet of reference pulses 5 after reception of a synchronization pulse 6 coming from the ultrasound station.

The reception of the synchronization pulse 6 and the transmission of the doublet of pulses 5 can be carried out on a single link line 7 between the ultrasound station 1 and the resolver 4.

 For this, the resolver 4 will be connected to the ultrasound station 1 from which it will receive the synchronization pulse 6 and will present means for generating a doublet of pulses 5 in return for the synchronization pulse 6. The reference doublet 5 makes it possible to simulate the presence of two neighboring reflections of two neighboring discontinuities in a room subjected to a synchronization pulse. This simulation is directly displayed on the screen of the cathode ray tube 2 of the ultrasound station 1.

 In order to be able to determine the intrinsic resolution power of an ultrasound station 1, it is necessary to be able to adjust the time interval separating the two pulses from the pulse doublet 5.

The principle consists in bringing the two pulses as close together as possible while clearly distinguishing them on the screen of the cathode ray tube 2 of the ultrasound station 1.

 Another characteristic which can influence the intrinsic resolving power of an ultrasound station, is the delay between the moment when the synchronization pulse is emitted and the moment when the reference pulse doublet is returned. This variation corresponds to simulating the use of the ultrasound station I with test pieces of different thicknesses.

 The resolver 4 will have a generator of free AC pulses 8 whose role will be to provide at output 9 an electrical pulse of well defined shape and characteristic, which will simulate a reference pulse, when it receives a signal at input 11 electric determined 10.

 This electrical signal which will trigger the calibrated pulse generator 8 will be supplied by the synchronization pulse 6 of the ultrasound station 1. This synchronization pulse 6 will pass to the calibrated pulse generator 8 firstly by via a direct transmission circuit 12 which will directly attack the calibrated pulse generator 8 and on the other hand, the synchronization pulse 6 will pass through a delayed transmission circuit 13 before attacking the calibrated pulse generator 8. This delayed transmission circuit will create a delay D2 between the moment when it receives the synchronization pulse 6 shaped and the moment when it transmits a signal 14 towards the pulse generator calibrated 8.

 In this way, when the resolver 4 receives a synchronization pulse 6 from the ultrasound station, the calibrated pulse generator will generate a pair of pulses 15 which will be returned to the ultrasound station 1 so that it is displayed on the standard tube 2 of station 1.

 It will also be advantageous in certain cases to equip the resolver 4 with a retarder 16 which will be placed upstream of the direct transmission circuit 12 and of the delayed transmission circuit 13. This retarder 16 will make it possible to generate a delay D1 between the moment when it receives on its input 17 a pulse 18 which corresponds to the synchronization pulse 6 coming from the ultrasound station 1, and the moment when it emits a pulse 19 in the direction of the direct transmission circuit 12 and the delayed transmission 13.

 The delay D1 can be adjusted as required. This delay D1 makes it possible in particular to simulate parts to be tested of variable thicknesses.

 Since the reference doublet passes through the same line 7 as the synchronization pulse 6 emitted by the US station, it is necessary to provide special circuits in the resolver to adapt it to this situation.

 First of all, the calibrated pulse generator 8 will be followed by an impedance adapter and separator 20. The role of this circuit 20 will firstly be to adapt the characteristics of the calibrated pulses 15 emitted by the generator 8 , to the characteristics of the ultrasound station 1. On the other hand, it is necessary that the synchronization pulse 6 of high amplitude does not come to damage the calibrated pulse generator 8. Consequently, the separator 20 will have for mission to protect the generator 8 from the synchronization pulse 6. emitted by the ultrasound station 1.

 - On the other hand, it will be necessary to sufficiently reduce the amplitude of the pulse 6 at the input of the resolver 4 by an aperiodic voltage divider 21.

 The aerodynamic voltage divider 21 will be followed by a pulse selector 22. This pulse selector 22 will have the function of filtering the synchronization pulse 6 emitted by the ultrasound station 1. Indeed, because that the resolver generates a doublet of pulses 5, it is essential that this doublet of pulses does not itself in turn generate a second doublet of pulses which would have the effect of causing the resolver to oscillate. This function can possibly be realized by playing on differences in amplitude and sign.

 It should be noted that the aperiodic voltage divider 21 preferably has a high input impedance so as not to influence the pulse doublet 5.

 The pulse selector 22 may be followed by a pulse shaper 23 which will have the function of shaping the pulse so that it can attack the following electronic circuits frankly.

 The pulse shaper 23 in general will be placed directly upstream of the retarder 16.

 According to the method of the invention for measuring the intrinsic resolution power of an ultrasonic station which emits a synchronization pulse, this consists in sending two ultrasonic pulses back to the ultrasonic station 1. reference echoes first of all superimposed, then the second echo is gradually delayed until a perfect separation of the two echoes 3 on the display screen 2 of the cathode ray tube of the ultrasound station. The delay time of the second echo compared to the first, then corresponds to the intrinsic resolution power of the ultrasound station.

 Since this value of the intrinsic resolution power is a function of several variables, it will be necessary to carry out different measurements by varying for example the transmission power of the ultrasound station, the setting of the bandwidth switch , the gain of the ultrasound station tested the time separating the emission pulse from the doublet, ie different delays D1.

 The embodiment which has just been described is given for information only, and other implementations of the present invention, within the reach of a person skilled in the art, could have been adopted without as well go beyond the framework of this one.

Claims (10)

 1. Resolumeter in particular intended to test the resolving power of an ultrasonic station (1) to which it is connected and from which it receives the synchronization pulse (6), characterized in that it has means to generate a pair of reference pulses (5) triggered by the synchronization pulse (6).  2. Resolumeter according to claim 1, characterized in that the time interval which separates the two pulses from the pulse doublet (5) is adjustable.  3. Resolumeter according to claim 1, characterized in that the time interval which separates the synchronization pulse (6) from the doublet of pulses (55 of reference is adjustable.  4. Resolumeter according to claim 2, characterized in that the means are in the form of a generator (8) of calibrated pulses, triggered on the one hand by a direct transmission circuit (12) of the pulse synchronization (6) and secondly, by a delayed transmission circuit (13) of said pulse (6).  5. 5. Resolumeter according to claim 4, characterized in that a retarder (16) is placed upstream of the direct transmission circuits (12) and delayed (13 !.  6. Resolumeter according to claim 4, characterized in that the pulse generator (8) returns to the input of the resolver its pulses (9) via an impedance adapter and separator (20).  7. Resolumeter according to claim 4, characterized in that the synchronization pulse (6) is directed at the input of the resolumeter (4) to the calibrated pulse generator (8) passing first through a aperiodic voltage divider (21) a pulse selector (22) and a pulse shaper (23).  8. Resolumeter according to claim 7, characterized in that the voltage divider has a high input impedance.  9. Method for measuring the resolving power. intrinsic of an ultrasonic station which emits a synchronization pulse, charac terized in that one returns to the ultrasonic station, two superimposed reference pulses, then that the second pulse is gradually delayed until the two pulses are perfectly separated, the delay time of the second pulse then corresponds to the intrinsic resolution power of the ultrasound station.  10. A method of measuring the intrinsic resolution power of an ultrasound station according to claim 9. characterized in that the resolution power is measured for different values of the transmission power, of the setting of the switch of bandwidth, the gain of the ultrasound station tested and the time separating the transmission pulse from the doublet.