NL9302247A - Pulse-echo system with a multiple reflection system. - Google Patents

Description

PULS-ECHO SYSTEM WITH A MULTIPLE REFLECTION SYSTEM

The applicant mentions as inventor:

Johan BLACK in STATE COLLEGE, USA

The invention relates to a pulse-echo system with a multiple reflection system comprising a transducer for transmitting and receiving pulse-shaped ultrasound signals over a first transmission path located between the transducer and the multiple reflection system, which first transmission path runs substantially parallel to a examine pipe wall, and which multiple reflection system includes a first reflection surface and a second reflection surface.

Such a pulse echo system is known from US patent US 4,022,055. This publication describes the use of two reflection surfaces for ultra-sound waves in which the transmission path located between the transducer and the reflection means runs substantially parallel to the wall to be examined. The reflection means according to this patent each define a further transmission path between the reflection means and the wall to be examined. One of the two further transmission paths is perpendicular to the wall to be examined and the second transmission path is directed at an angle to said wall. The perpendicularly directed transmission path serves to generate reflection signals which provide information about the thickness of the wall to be examined. With the angled transmission path, irregularities such as cracks in the pipe wall must be detected.

Pulse ultrasound systems as to which the invention relates are used in practice to detect cracks in the steam pipes of water-cooled nuclear installations, for which early detection of these cracks is important for safety reasons.

In practice, the majority of the occurring cracks appear to have a reflection plane that is perpendicular to the wall of the pipe in which the crack is located. The energy of the sound waves which according to the prior art serve to detect the wall thickness and which are directed perpendicularly to the pipe wall for this purpose therefore do not contribute to signaling such cracks. Only the part of the emitted energy with which the wall to be examined is irradiated at an angle is suitable for detecting these cracks. At the location of such a crack, reflection then takes place, in which part of the ultrasound wave propagates in the opposite direction in the direction of the transducer, where the reflection is detected. However, much of the energy is scattered in the pipe wall and is not useful for crack detection or otherwise.

The object of the invention is now to provide a pulse-echo system which has a greater sensitivity for detection of cracks of the described type and at the same time information about the thickness of the wall and the inner profile of the wall can be obtained.

According to the invention, the pulse echo system is designed for this purpose such that during use both the first and the second reflection plane each define a further transmission path according to which the ultra-sound waves from the transducer are projected at an angle to the pipe wall, which angle of each of the two further transmission channels is greater than the critical angle of incidence, so that the ultra-sound waves projected on the pipe wall move substantially further in the pipe wall, and the angle of both transmission channels is determined such that the two further transmission channels are brought to the pipe wall ultra-sound waves converge in the vicinity of the pipe wall.

In a particular aspect of the invention, it is characterized in that the angle of the first reflection plane with the first transmission path and the angle of the second reflection plane with the second transmission path together are approximately 90 °. Sound energy emitted by the transducer and reflected by the first reflection surface gives reflections against the inside of the pipe wall, and after entering the wall also on the outside of the pipe wall. These reflections partly follow the same path, but in the opposite direction as in which they reached the wall, and partly reflections take place according to a second path which lies between the pipe wall to be examined, the second reflection surface and the transducer. According to the invention, the transmission paths between transducer, first reflecting surface and pipe wall and between transducer, second reflecting surface and pipe wall connect to each other, so that any reflections formed by the inside and outside of the pipe wall to be examined, as well as from irregularities in the pipe wall, via both ways be able to reach the transducer again. This provides an optimum yield of the total energy emitted by the transducer, so that the sensitivity to crack detection is optimal. In addition, it is possible to obtain thickness information about the pipe wall from the reflections that arise at the inside and the outside 4 of the pipe wall and - in connection with the reflections of the inside of the wall - also information about the profile of this pipe wall.

According to the invention, the best results are obtained if the angle of the first reflection plane with the first transmission path is in the range 35-37 ° and the angle of the second reflection plane with the first transmission path is in the range 55-53 °. It has been found that with respect to the optimum angle adjustment, an angle selection deviating from this by 1 ° produces a yield difference of 6 decibels.

The invention will now be further elucidated with reference to the drawing, in which Fig. 1 shows the invented pulse echo system when examined on a pipe wall part without cracks and Fig. 2 shows the pulse echo system according to the invention when examined on a pipe wall part in which there is a crack. Like reference numbers are like parts.

A pipe wall 4 with an inner wall 5 and an outer wall 6 is examined with the pulse echo system according to the invention. For this purpose, a transducer 1 transmits a pulse-shaped sound signal in the direction of the reflection surfaces 2 and 3 cooperating with transducer 1. Reflection surfaces 2 and 3 are arranged at different angles to the transducer 1 and are offset. The transmission path 7, which lies between transducer 1 and the multiple reflection system comprising the reflection surfaces 2 and 3, runs substantially parallel to the pipe wall 4 to be examined. Reflection surfaces 2 and 3 reflect the sound signal received via the transmission channel 7 in the direction of the pipe wall 4 such that both further from reflection plane 2 and from reflection plane 3 to the pipe wall two further transmission paths are defined which converge in the vicinity of the pipe wall 4.

According to a particular aspect of the invention, the angle of the first reflection surface 2 with transmission path 7 together with the angle of reflection surface 3 with transmission path 7 is approximately 90 °. Preferably, the angle of the first reflection surface 2 with the first transmission path 7 is located in the range 35-37 ° and the angle of the second reflection plane 3 with the first transmission path 7 situated in the range 55-53 °. Sound waves reaching pipe wall 4 via transmission path 7 after being reflected by reflection plane 2 or 3 reach pipe wall 4 via both transmission path 8 and transmission path 9. Arriving at the inside of pipe wall 4, partial reflection of the sound waves takes place which for the part that the inside has reached 5 via transmission path 8, partly following the same path but in the reverse direction, and partly reaching transducer 1 again via the road formed by transmission path 9 and transmission path 7.

A corresponding route is followed by the sound waves reaching the inside 5 of the pipe wall 4 via transmission path 9. These are also partly reflected which reflections reach the transducer 1 again by traversing transmission path 9 and transmission path 7 in reverse direction, and partly reflect however, place where the sound waves propagate in the direction of transducer 1 via transmission path 8 and transmission path 7. However, most of the sound energy reaching the pipe wall 4 via the transmission paths 8 and 9 enters the pipe wall 4 and causes only further reflections against the outside 6 of the pipe wall 4 (as shown in fig. 1) in case no cracking in the pipe wall 4 is present, or (as shown in fig. 2) further gives reflections which the transducer 1 through the distinct trans Missing paths 7, 8 and 9 reach if a crack is present in the pipe wall 4.

Claims (3)

A multiple reflection system pulse echo system comprising a transducer for transmitting and receiving pulse ultrasonic signals over a first transmission path located between the transducer and the multiple reflection system, said first transmission path extending substantially parallel to a pipe wall to be examined, and which multiple reflection system comprises a first reflection plane and a second reflection plane, characterized in that during use both the first and the second reflection plane each define a further transmission path according to which the ultrasound waves from the transducer are projected at an angle to the pipe wall, which angle of each of the two further transmission channels is greater than the critical angle of incidence so that the ultra-sound waves projected on the pipe wall move substantially further into the pipe wall, and wherein the angle of both transmission channels is adjusted such that the via both further transmis ultrasound waves brought to the pipe wall converge in the vicinity of the pipe wall. Pulse echo system according to claim 1, characterized in that the angle of the first reflection plane with the first transmission path and the angle of the second reflection plane with the second transmission path together is approximately 90 °. Pulse echo system according to claim 1 or 2, characterized in that the angle of the first reflection plane with the first transmission path is in the range 35-37® and the angle of the second reflection plane with the first transmission path is in the range 55-53®.