How sound waves detect faults in girders

AI Thread Summary
Sound waves are utilized to detect faults in girders by analyzing the signals received from a pulse producer and a detector positioned on opposite sides. The safe detector shows spikes at 0 and 10 microseconds, indicating normal reflections, while the unsafe detector displays an additional spike at 4 microseconds, suggesting an internal flaw. This spike occurs because sound waves traveling around the crack take longer to return, leading to a delay in detection. The presence of this additional spike indicates a discontinuity in the metal, marking the girder as unsafe. Understanding these sound wave patterns is crucial for assessing structural integrity.
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[PLAIN]http://postimage.org/image/4ure9j3sr/[b]1. Homework Statement [/b]

i have a physics questions about sound Sound waves are used to detect faults in girders. a cro is used to detect these faults, a pulse producer and a detector is placed on opposite sides of the detector.

The safe detector has a upwards spike at 0microseconds and at 10 microseconds.

The unsafe detector has a upwards spike at 0 microseconds and 10 mircroseconds and also one additional but smaller upwards spike at 4 microseconds.

why is the the unsafe detector considered unsafe?

Homework Equations





The Attempt at a Solution


my understanding: there is a crack in the girder so when the sound waves is sent in, some of the waves will have to go around it so it causes it to be slower than the sound waves which do pass the crack. because it is slower, so it is shown in the 4 microseconds. meaning that if another pulse is sent out one of the recorded one will be at 10microseconds from the previous one and another which is 4 microseconds ahead of just detected pulse

the image i drew of the CRO is here http://postimage.org/image/4ure9j3sr/


 
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