Ultrasonic test equipment and evaluation method thereof

What is claimed is: 1. An ultrasonic test equipment comprising: a signal generating mechanism that generates a voltage waveform; an ultrasonic transmitting mechanism that excites ultrasonic vibrations having a lower frequency than a predetermined frequency to an object to be tested; an ultrasonic receiving mechanism that receives an ultrasonic response from the object to be tested; an AD converting mechanism that digitizes the received ultrasonic waveform; an analyzing mechanism that performs frequency analysis of the digital ultrasonic waveform digitized by the AD converting mechanism; an evaluating mechanism that extracts a variation of a nonlinear ultrasonic component from a frequency component of the digital ultrasonic wave obtained by the frequency analysis, compares the variation with defect data information in a defect information database, identifies a physical quantity of defect information of the object to be tested, and evaluates a defect in the object to be tested; and a control mechanism that partly or entirely controls a measurement system. 2. The ultrasonic test equipment according to claim 1 , wherein at least one of the ultrasonic transmitting mechanism and the ultrasonic receiving mechanism includes a plurality of ultrasonic transmitting mechanisms or a plurality of ultrasonic receiving mechanisms and a recording device that records a reference waveform obtained from an object to be tested with no defect, wherein the analyzing mechanism performs correlation processing between the digital ultrasonic waveform obtained from the ultrasonic receiving mechanism through the AD converting mechanism and a signal obtained from the reference waveform, and, performs a removal process of removing, from the digital ultrasonic waveform, a signal with the reference waveform exhibiting a correlation equal to or more than a predetermined value in the correlation processing, and the analyzing mechanism identifies a defect position based on a characteristic ultrasonic signal of the digital ultrasonic waveform after the removal process. 3. The ultrasonic test equipment according to claim 1 , wherein at least one of the ultrasonic transmitting mechanism and the ultrasonic receiving mechanism includes a scanning mechanism that moves a plurality of ultrasonic transmitting mechanisms or ultrasonic receiving mechanisms relative to each other, wherein the analyzing mechanism includes a position identifying device that identifies a defect position by performing correlation processing between the digital ultrasonic waveform obtained from the ultrasonic receiving mechanism through the AD converting mechanism and a reference ultrasonic signal obtained from a reference waveform of an object to be tested with no defect. 4. The ultrasonic test equipment according to claim 1 , wherein the analyzing mechanism analyzes a generation efficiency of the nonlinear ultrasonic component from the frequency component of the digital ultrasonic waveform obtained from the ultrasonic receiving mechanism through the AD converting mechanism, and the evaluating mechanism is configured to achieve a function to acquire at least one of physical quantities of a length, a depth, an opening width, and an opening stress of the defect in the object to be tested by matching frequency information of the analyzed digital ultrasonic waveform with known defect data information in the defect information database. 5. The ultrasonic test equipment according to claim 1 , wherein the signal generating mechanism is configured to achieve a function to sweep a frequency of the voltage waveform, the analyzing mechanism analyzes a tendency of a generation efficiency of the nonlinear ultrasonic component in response to a frequency change in the digital ultrasonic waveform obtained from the ultrasonic receiving mechanism through the AD converting mechanism, and the evaluating mechanism is configured to achieve a function to acquire at least one of physical quantities of a length, a depth, an opening width, and an opening stress of the defect in the object to be tested by matching frequency information of the analyzed digital ultrasonic waveform with known defect data information in the defect information database. 6. The ultrasonic test equipment according to claim 1 , wherein the signal generating mechanism has a function to generate the voltage waveform having a plurality of mixed frequencies, the analyzing mechanism analyzes a tendency of a generation efficiency of the nonlinear ultrasonic component in response to a frequency change in the digital ultrasonic waveform obtained from the ultrasonic receiving mechanism through the AD converting mechanism, and the evaluating mechanism is configured to achieve a function to acquire at least one of physical quantities of a length, a depth, an opening width, and an opening stress of the defect in the object to be tested by matching frequency information of the analyzed digital ultrasonic waveform with known defect data information in the defect information database. 7. The ultrasonic test equipment according to claim 1 , wherein the ultrasonic receiving mechanism is composed of a hydrophone and uses only an ultrasonic component leaking into water from the defect in the object to be tested for analysis. 8. The ultrasonic test equipment according to claim 1 , wherein a remote viewing camera is used to observe a same range as a flaw detection range of the object to be tested, and the defect information of the object to be tested is superimposed on an image obtained by the remote viewing camera and displayed. 9. The ultrasonic test equipment according to claim 1 , wherein an acoustic impedance matching layer that improves an ultrasonic propagation efficiency is provided between at least one of the ultrasonic transmitting mechanism and the ultrasonic receiving mechanism, and the object to be tested. 10. A method for evaluating a test result by an ultrasonic test equipment, comprising the steps of: transmitting an ultrasonic wave having a low frequency lower than a predetermined frequency to an object to be tested; receiving an ultrasonic response from the object to be tested by an ultrasonic receiving mechanism; converting the received analog ultrasonic waveform to a digital ultrasonic waveform; performing frequency analysis of the converted digital ultrasonic waveform by an analyzing mechanism; and extracting a variation of a nonlinear ultrasonic component from frequency information of the digital ultrasonic waveform of the object to be tested obtained by the frequency analysis, matching the variation with known defect data information in a defect information database, identifying a physical quantity of defect information of the object to be tested, and then, evaluating a defect in the object to be tested by an evaluating mechanism. 11. An ultrasonic test equipment comprising: a signal generating mechanism that generates a voltage waveform; an ultrasonic transmitting mechanism that excites ultrasonic vibrations having a lower frequency than a predetermined frequency to an object to be tested; an ultrasonic receiving mechanism that receives an ultrasonic response from the object to be detected; an AD converting mechanism that digitizes the received ultrasonic waveform; a calculating mechanism that performs an inverse problem calculation of a spatial intensity distribution from the digitized ultrasonic waveform; a filtering mechanism that calculates the spatial intensity distribution filtered by any frequency component; a variation extracting mechanism that extracts an intensity variation of a nonlinear ultrasonic component; a display mechanism that displays at least the filtered spatial intensity distri