KR20100072820A - System and method for detecting inner defects of strip using non-linear ultrasonic generation - Google Patents

Abstract

PURPOSE: A system for detecting inner defect of steel strip using non-linear ultrasonic generation is provided to detect minute internal defect inside a steel sheet using nonlinear ultrasonic wave. CONSTITUTION: A system for detecting inner defect of steel strip using non-linear ultrasonic generation comprises an ultrasonic transmitter(1000), an ultrasonic receiver(2000), and a signal processing unit(500). The ultrasonic transmitter generates ultrasonic plate wave to the inside of a rolling steel sheet through online. The ultrasonic receiver receives the ultrasonic plate transmitted in the width direction of the steel sheet through online. The ultrasonic receiver filters and amplifies ultrasonic plate wave of specific frequency band among ultrasonic plate waves. The signal processing unit obtains the value of the nonlinear parameter from the first high frequency and the second high frequency which is identical with the ultrasonic plate wave.

Description

System and method for detecting inner defects of strip using non-linear ultrasonic generation}

The present invention relates to a system and method for detecting internal defects of a steel sheet using nonlinear ultrasonic generation, and more particularly, to a system and method for detecting internal defects of a small size that do not generate a reflected wave of sufficient amplitude in the process of detecting defects of a steel sheet. will be.

Conventional steel sheet internal defect inspection method, the pulse / echo method of the guided ultrasonic wave can detect only relatively large defects, there was a problem that does not detect small internal defects that do not appear on the surface during the rolling process. In this technique, the guided ultrasonic wave generated by the ultrasonic transducer and propagated along the inside of the steel sheet is reflected at the boundary of the internal defect existing on the propagating path and received by the ultrasonic transducer. As such, it is possible to detect only the signal of the guided ultrasonic waves reflected from the significantly larger internal defects in order to receive the guided ultrasonic waves reflected from the internal defects again.

The huge internal defects that can be detected by the pulse / echo method by reflecting the guided ultrasonic waves are exposed to the surface after cold rolling to become surface defects, and thus, the surface defect detector (SDD) can perform the function. Do.

In addition, since the incidence of such a huge internal defect has decreased with the recent development of steelmaking technology, the usefulness of the internal defect detector for detecting the huge internal defect is poor. In recent years, since the plastic workability is required more when producing the final product from the steel sheet, the criteria for internal defects such as inclusions are becoming more stringent. Therefore, a satisfactory internal defect detector method should be capable of detecting a defect of a much smaller size than the conventional one.

Recently, among the defect detection methods using ultrasonic waves, there is a technique using a nonlinear ultrasonic phenomenon, which detects a small initial crack that cannot be detected by a general ultrasonic flaw detection method that receives ultrasonic reflected waves from a defect.

When a mechanical load is subjected to fatigue loads, a large number of fine cracks are generated, they are connected and grown, leading to breakage of the structure, and the cracks detected by ultrasonic flaw have already grown considerably. Should be detected to ensure proper response.

As such, the nonlinear ultrasonic phenomenon is caused by the interaction with the fine cracks, and the second harmonic component of the transmitted ultrasonic waves is increased. Such a characteristic is expressed by Equation 1 as the nonlinear parameter β.

Here, A ₁ and A ₂ are amplitudes of the first harmonic and the second harmonic, respectively, k is a wave number and x is a propagation distance. The first harmonic means an ultrasonic wave of a frequency component equal to the frequency of the transmission wave, and the second harmonic means an ultrasonic wave of a high frequency component having a frequency twice the frequency of the transmission wave.

However, the above-described internal defect flaw detection of the steel sheet does not provide a system and method for detecting fine internal defects inside the steel sheet by using nonlinear ultrasonic waves.

It is an object of the present invention to provide a system and method for detecting fine internal defects in a steel sheet using nonlinear ultrasonic waves in internal defect inspection of the steel sheet.

One aspect of the present invention, the ultrasonic transmission unit for generating the ultrasonic wave wave on-line inside the steel sheet being rolled by generating a tone-burst; An ultrasonic receiver for receiving the ultrasonic wave wave propagated in the width direction of the steel sheet online and filtering and amplifying the ultrasonic wave wave of a specific frequency band among the received ultrasonic wave waves; And calculating a value of a nonlinear parameter obtained from a first harmonic that is the same frequency as the generated ultrasonic wave wave and a second harmonic that is twice the frequency of the generated ultrasonic wave wave in the signal of the amplified ultrasonic wave wave. An internal defect of the steel sheet using nonlinear ultrasonic generation, comprising: a signal processing device for determining whether the value of the nonlinear parameter is equal to or greater than a preset reference value and detecting the internal defect of the steel sheet when the value of the nonlinear parameter is equal to or greater than the predetermined reference value. Provide a detection system.

In one embodiment of the present invention, the ultrasonic transmitter is a non-contact transmission transducer including an electromagnetic-ultrasound transducer or an air defect transducer, or a piezoelectric material inside the tire filled with a liquid and capable of rolling on the steel sheet. It provides an internal defect detection system of a steel sheet using a non-linear ultrasonic generation, characterized in that it comprises a continuous contact type transmission transducer including a wheel-type transducer built in the ultrasonic sensor.

In another embodiment of the invention, the ultrasonic receiver is a non-contact receiving transducer including an electromagnetic-ultrasound transducer or an air defect transducer, or a piezoelectric material inside the tire filled with a liquid and capable of rolling on the steel sheet. Provided is an internal defect detection system of a steel sheet using a non-linear ultrasonic generation, characterized in that it comprises a continuous contact type receiving transducer including a wheel-type transducer built in the ultrasonic sensor.

In another embodiment of the present invention, when the frequency of the receiving transducer is adjusted to the wavelength, the wavelength of the receiving transducer is characterized in that half of the wavelength of the transmitting transducer. An internal defect detection system of a steel sheet using nonlinear ultrasonic generation is provided.

In another embodiment of the present invention, when the frequency of the receiving transducer is adjusted to the resonance frequency of the receiving transducer, the resonance frequency of the receiving transducer is twice the frequency of the transmitting transducer. Provided is an internal defect detection system of a steel sheet using non-linear ultrasonic wave generation.

Another aspect of the invention, generating the tone-burst to generate the ultrasonic wave wave on-line inside the steel sheet being rolled; Receiving an ultrasonic wave wave propagated in the width direction of the steel sheet online, and filtering and amplifying the ultrasonic wave wave of a specific frequency band among the received ultrasonic wave waves; Obtaining, from the signal of the amplified ultrasonic wave wave, a value of a nonlinear parameter obtained from a first harmonic at the same frequency as the generated ultrasonic wave wave and a second harmonic at twice the frequency of the generated ultrasonic wave wave; And determining whether the value of the nonlinear parameter is equal to or greater than a predetermined reference value, and detecting the internal defect of the steel sheet when the value of the nonlinear parameter is equal to or greater than a predetermined reference value. The present invention provides a method for detecting internal defects.

According to the present invention, since fine internal defects inside the steel sheet can be detected using nonlinear ultrasonic waves in the internal defect flaw detection of the steel sheet, it is possible to produce a high quality cold rolled steel sheet which greatly reduces internal defects.

In addition, according to the present invention, it is possible to reduce defects in plastic working due to internal defects in processing using cold rolled steel sheets as raw materials.

In addition, according to the present invention, internal defects or inclusion defects present in the steel sheet during the rolling process can be used for on-line detection.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention may be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shape and the size of the elements in the drawings may be exaggerated for clarity and the same elements are denoted by the same reference numerals in the drawings.

In the present invention, the steel sheet is a steel having a constant width and thickness in the steel manufacturing process as an object of internal defect detection, and is a strip continuously moving in the longitudinal direction, that is, the rolling direction, in the rolling process. In addition, an internal defect is a defect which exists in the inside of a steel plate, and contains interpositional defects by impairing the quality of a steel plate.

1 is a schematic diagram of an internal defect detection system of a steel sheet using nonlinear ultrasonic wave generation of the present invention, and FIG. 2 is a state diagram of ultrasonic wave waves propagated in the steel sheet of the present invention.

As shown in FIG. 1, the internal defect 90 detection system of the steel sheet 50 using non-linear ultrasonic generation includes an ultrasonic transmitter 1000, an ultrasonic receiver 2000, and a signal processing apparatus 500.

The ultrasonic transmitter 1000 includes an ultrasonic generator 100 and a transducer 200 for transmission. The ultrasonic generator 100 generates ultrasonic waves by generating a high output tone-burst, and the transmitting transducer 200 has an inside of the steel sheet 50 being rolled by ultrasonic waves generated by the ultrasonic generator 100. The ultrasonic wave wave 60 is generated online.

Transmitting transducer 200 may be a non-contact transducer including an electromagnetic-ultrasonic transducer (EMAT) or an air-coupled transducer, or a tire filled with liquid and rollable on a steel sheet 50. It is a continuous contact transducer including a wheel-type transducer with an ultrasonic sensor made of piezoelectric material inside.

The ultrasonic receiver 2000 includes a receiving transducer 300 and an ultrasonic receiver 400. The ultrasonic receiver 400 includes a filter 410 and a signal amplifier 420. The receiving transducer 300 receives an online ultrasonic wave wave 60 generated by the transmitting transducer 200 and propagated in the width direction of the steel sheet 50 online. The filter 410 filters the ultrasonic wave wave 60 of a specific frequency band among the ultrasonic wave waves 60 received by the receiving transducer 300, and the signal amplifier 420 filters the ultrasonic wave filtered by the filter 410. Amplify the wave wave 60. In this case, a band pass filter, a high pass filter, and a low pass filter are used to effectively receive twice the frequency components of the transmitted ultrasonic wave wave 60. .

Like the transmitting transducer 200, the receiving transducer 300 is also a non-contact transducer including an electromagnetic-ultrasound transducer or an air-defect transducer, or a liquid filled and rollable on a steel sheet 50. It is a continuous contact transducer that includes a wheel-type transducer with an ultrasonic sensor made of piezoelectric material inside the tire.

Two methods are used to adjust the frequency of the receiving transducer 300. That is, when the frequency of the receiving transducer 300 is adjusted to the wavelength, the wavelength of the receiving transducer 300 is transmitted. Half the wavelength of the credit transducer 200 is assumed. When the frequency of the receiving transducer 300 is adjusted to the resonant frequency of the receiving transducer 300, the resonance frequency of the receiving transducer 300 is adjusted to 2 of the frequency of the transmitting transducer 200. Double it.

The transmitting transducer 200 and the receiving transducer 300 may be provided near the work side of the steel sheet 50 or near the drive side of the steel sheet 50. When the transmitting transducer 200 is provided near the work side of the steel sheet 50, the receiving transducer 300 is provided near the drive side of the steel sheet 50. When the receiving transducer 300 is provided near the work side of the steel plate 50, the transmitting transducer 200 is provided near the drive side of the steel plate 50. In this way, the guided ultrasonic waves can be propagated across the full width of the steel sheet 50.

The signal processing apparatus 500 includes the first harmonic 70 having the same frequency as the ultrasonic wave wave 60 generated by the transmitting transducer 200 in the signal of the ultrasonic wave wave 60 amplified by the signal amplifier 420. The value of the nonlinear parameter obtained from the second harmonic 80, which is twice the frequency of the ultrasonic wave wave 60 generated by the transmitting transducer 200, is determined, and it is determined whether the value of the nonlinear parameter is equal to or greater than a preset reference value. If the value of the nonlinear parameter is greater than or equal to the preset reference value, the internal defect 90 of the steel sheet 50 is detected.

The signal processing apparatus 500 may generally be a hardware driving PC of a measurement system, and receives an ultrasonic signal finally output from the signal amplifier 420 to convert analog / digital signals. The signal processing apparatus 500 extracts the amplitude of the first harmonic 70 and the second harmonic 80 by performing a fast fourier transform (FFT) on the converted ultrasonic signal, and then calculates a value of the nonlinear parameter.

While the ultrasonic wave wave 60 generated from the transmitting transducer 200 propagates inside the steel sheet 50, the second harmonic 80 is scattered and interacts with the internal defect 90 of the steel sheet 50. The component is increased, and the receiving transducer 300 receives the ultrasonic wave wave 60 in which the component of the second harmonic 80 is increased, so that the signal processing apparatus 500 receives the first harmonic 70 and the second harmonic. The internal defect 90 of the steel sheet 50 can be detected by the nonlinear parameter represented by the relationship of 80.

3 is a flowchart of a method for detecting internal defects of a steel sheet using nonlinear ultrasonic generation of the present invention. Looking at Figure 3 along with Figures 1 and 2 as follows.

First, after the ultrasonic generator 100 generates a high output tone-burst to generate ultrasonic waves (S100), the transmitting transducer 200 of the steel sheet 50 being rolled by the ultrasonic waves generated by the ultrasonic generator 100. The ultrasonic wave wave is generated online (S200).

Thereafter, the receiving transducer 300 receives the ultrasonic wave wave generated in the transmitting transducer 200 and propagated in the width direction of the steel sheet 50 online (S300), and the filter 410 is for receiving. The ultrasonic wave wave of the specific frequency band is filtered out of the ultrasonic wave wave received by the transducer 300, and the signal amplifier 420 amplifies the ultrasonic wave wave filtered by the filter 410 (S400).

Subsequently, the signal processing apparatus 500 includes the first harmonic, which is the same frequency as the ultrasonic wave wave generated by the transmitting transducer 200, in the signal of the ultrasonic wave wave amplified by the signal amplifier 420, and the transmitting transducer ( The value of the nonlinear parameter obtained from the second harmonic, which is twice the frequency of the ultrasonic wave wave generated by 200), is obtained (S500).

Thereafter, the signal processing apparatus 500 determines whether the value of the nonlinear parameter is greater than or equal to the preset reference value (S600), and detects an internal defect of the steel sheet 50 if the value of the nonlinear parameter is greater than or equal to the preset reference value (S710). . However, if the value of the non-linear parameter is not more than the predetermined reference value, the signal processing apparatus 500 determines that there is no internal defect in the steel sheet 50 (S720). The preset reference value should be appropriately selected by the operator according to the type of steel sheet to be detected and the working situation.

The present invention is not limited by the above-described embodiment and the accompanying drawings. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims, .

1 is a schematic diagram of an internal defect detection system of a steel sheet using nonlinear ultrasonic generation of the present invention.

2 is a state diagram of the ultrasonic wave wave propagated in the steel sheet of the present invention.

3 is a flowchart of a method for detecting internal defects of a steel sheet using nonlinear ultrasonic generation of the present invention.

                 <Explanation of symbols for the main parts of the drawings>

50: steel plate 60: ultrasonic wave wave

70: 1st harmonic 80: 2nd harmonic

90: internal defect 100: ultrasonic generator

200: transmitting transducer 300: receiving transducer

400: ultrasonic receiver 410: filter

420: signal amplifier 500: signal processing device

1000: ultrasonic transmitter 2000: ultrasonic receiver

Claims (6)

Ultrasonic transmitting unit for generating an ultrasonic plate wave on the inside of the steel sheet being rolled by generating a tone-burst; An ultrasonic receiver for receiving the ultrasonic wave wave propagated in the width direction of the steel sheet online and filtering and amplifying the ultrasonic wave wave of a specific frequency band among the received ultrasonic wave waves; And In the signal of the amplified ultrasonic wave wave, a value of a non-linear parameter obtained from a first harmonic at the same frequency as the generated ultrasonic wave wave and a second harmonic at twice the frequency of the generated ultrasonic wave wave is obtained. A signal processing device that determines whether a value is equal to or greater than a preset reference value and detects an internal defect when the value of the nonlinear parameter is equal to or greater than a preset reference value; Internal defect detection system of the steel sheet using non-linear ultrasonic waves, characterized in that it comprises a. The method of claim 1, The ultrasonic transmitter includes a non-contact transmission transducer including an electromagnetic-ultrasound transducer or an air defect transducer, or a wheel type with an ultrasonic sensor made of piezoelectric material inside a tire filled with liquid and capable of rolling on the steel sheet. An internal defect detection system of a steel sheet using non-linear ultrasonic wave generation comprising a continuous contact type transmission transducer including a transducer. The method of claim 2, The ultrasonic receiver includes a non-contact receiving transducer including an electromagnetic-ultrasound transducer or an air defect transducer, or a wheel type with an ultrasonic sensor made of piezoelectric material inside a tire filled with a liquid and capable of rolling on the steel sheet. An internal defect detection system of a steel sheet using nonlinear ultrasonic generation, comprising a continuous contact type receiving transducer including a transducer. The method of claim 3, In the case where the frequency of the receiving transducer is adjusted to the wavelength length, the internal defect of the steel sheet using nonlinear ultrasonic generation, characterized in that the wavelength of the receiving transducer is half the wavelength of the transmitting transducer. Detection system. The method of claim 3, In the case where the frequency of the receiving transducer is adjusted to the resonance frequency of the receiving transducer, non-linear ultrasonic wave generation is characterized in that the resonance frequency of the receiving transducer is twice the frequency of the transmitting transducer. Internal defect detection system of used steel sheet. Generating a tone-burst to generate ultrasonic wave waves online inside the rolling steel sheet; Receiving an ultrasonic wave wave propagated in the width direction of the steel sheet online, and filtering and amplifying the ultrasonic wave wave of a specific frequency band among the received ultrasonic wave waves; Obtaining a value of a nonlinear parameter obtained from the amplified ultrasonic wave wave signal, the first harmonic wave having the same frequency as the generated ultrasonic wave wave and the second harmonic wave having a frequency twice the generated ultrasonic wave wave; And Determining whether a value of the nonlinear parameter is equal to or greater than a preset reference value and detecting an internal defect when the value of the nonlinear parameter is equal to or greater than a preset reference value; Internal defect detection method of the steel sheet using non-linear ultrasonic waves, characterized in that it comprises a.

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