Method of measuring the delay of ultrasound in the pulse reflection method

1. A delay time measuring method for ultrasound employing the pulse reflection method, wherein at least one excitation pulse that is as close as possible to the shape of a shock wave is emitted by a testing head and traverses a pretravel path until the excitation pulse reaches an object to be examined which has a front wall and a rear wall, with at least one reflected echo pulse being generated at the front wall of the object and at least two reflecting echo pulses being generated at the rear wall of the object, and wherein the reflected echo pulses are detected by at least one ultrasound detector and are amplified by analog signal matching, and wherein:

• (a) a time window is set for receiving the reflected echo pulses following the excitation pulse, with the width of said window being such that the front wall echo pulse and at least the two rear wall echo pulses lie within the window, and said received reflected echo pulses are digitized;
  
  then(b) the reflected echo pulses lying within the time window are digitally filtered and parametrized, wherein for each one of said reflected echo pulse lying within the time window, the time and amplitude are detected for the maximum and for when a digital threshold value is exceeded and fallen below;
  
  whereupon(c) the times and amplitudes of the filtered and parametrized reflected echo pulses are fed to a computer unit, wherein the parametrized reflected echo pulses are checked with respect to time from the most recently received rear wall echo pulse to the front wall echo pulse, and the parameterized reflected echo pulse being checked is considered to be relevant and is stored when the amplitude of the echo pulse being checked is nearly identical to or greater than the amplitude of the most recently stored echo pulse; and
  
  finally(d) the lead time and the wall thickness delay time of the object are determined and stored when the distance in time between the front wall echo pulse and the first rear wall echo pulse coincides with the distance between the first and second rear wall echo pulses within a tolerance band, and the times and amplitudes of all filtered and parametrized reflected echo pulses belonging to said one excitation pulse are stored when the distance in time between the front wall echo pulse and the first rear wall echo pulse does not coincide with the distance between the first and second rear wall echo pulses within the tolerance band.