KR102133455B1 - Ultrasonic testing apparatus using inertia sensor - Google Patents

Abstract

An ultrasonic inspection apparatus using an inertial sensor according to an embodiment converts a probe that receives and receives ultrasonic waves into a pipe, an inertial sensor connected to the probe to measure the position information of the probe, and converts the position information of the inertial sensor into a pulse signal. And a conversion device for outputting, and receiving the pulse signal from the conversion device, measuring a moving distance of the probe using the pulse signal, and displaying ultrasonic signals inside the pipe including position information of the probe It includes a display device.

Description

Ultrasonic inspection device using an inertial sensor{ULTRASONIC TESTING APPARATUS USING INERTIA SENSOR}

The present invention relates to an ultrasonic inspection device using an inertial sensor.

In general, an optical encoder is used to acquire position information when performing ultrasonic inspection of a pipe. It is possible to check the moving distance and position of the ultrasonic probe using an optical encoder.

Since the encoder wheel of the optical encoder needs to be in smooth contact with the pipe to be inspected, it requires a complex mechanical device such as a spring device for constant contact. Therefore, manufacturing cost and volume become large.

In addition, when slipping occurs between the pipe and the optical encoder wheel, measurement errors may occur in ultrasonic inspection.

The present embodiment relates to an ultrasonic inspection apparatus that uses a non-contact method for obtaining location information and minimizes volume.

The ultrasonic inspection apparatus according to an embodiment includes a transducer that receives and receives ultrasonic waves through a pipe, an inertial sensor connected to the transducer to measure position information of the probe, and converts and outputs position information of the inertial sensor into a pulse signal A device and an ultrasonic display device that receives the pulse signal from the conversion device, measures the moving distance of the probe using the pulse signal, and displays an ultrasonic signal including location information of the probe inside the pipe do.

The probe may contact the surface of the pipe.

The inertial sensor can rotate with the probe.

The converter comprises a pulse signal period setting unit for setting the period of the pulse signal, an inertial sensor position calculation unit for calculating the circumferential position of the inertial sensor, and a pulse for continuously outputting the pulse signal according to the movement of the probe It may include a signal output.

The pulse signal output unit may generate a pair of pulse signals having a phase difference of 90 degrees and compare them to determine the moving distance of the inertial sensor and whether to rotate in the forward or reverse direction.

According to one embodiment, since the ultrasonic inspection is performed using an inertial sensor without using an optical encoder, the volume of the ultrasonic inspection device can be minimized.

In addition, by using an inertial sensor instead of an optical encoder and generating a signal identical to that of an optical encoder using a conversion device that generates a pulse signal, it is compatible with a conventional ultrasonic display device.

In addition, since the inertial sensor performs ultrasonic inspection without contacting the pipe, it is possible to solve the sliding problem of the optical encoder.

1 is a schematic diagram of an ultrasound inspection apparatus according to an embodiment.
2 is a view illustrating an output value of an inertial sensor according to a circumferential position of an inertial sensor of an ultrasonic inspection apparatus according to an embodiment.
3 is a view specifically showing a conversion device of an ultrasound inspection apparatus according to an embodiment.
4 is a view illustrating a method of outputting position information of an inertial sensor of an ultrasonic inspection apparatus as a pulse signal using a conversion device according to an embodiment.
FIG. 5 is a graph showing pulse signals A and B output at a two-degree cycle according to a continuous movement of the probe in the conversion apparatus of the ultrasonic inspection apparatus according to an embodiment.
6 is a graph showing pulse signals A and B output at a 3-degree cycle according to a continuous movement of a position of a transducer in a conversion device of an ultrasonic inspection apparatus according to an embodiment.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice. The present invention can be implemented in many different forms and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar elements throughout the specification.

In addition, since the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, the present invention is not necessarily limited to what is illustrated.

1 is a schematic diagram of an ultrasonic inspection apparatus according to an embodiment.

As shown in FIG. 1, an ultrasound inspection apparatus according to an embodiment includes a frame 10, a probe 20, an inertial sensor 30, a conversion device 40, and an ultrasonic display device 50.

The frame 10 may have a cylindrical shape to surround the circumference of the pipe 100. In this embodiment, the probe 20 is connected to the frame 10, but is not limited thereto, and the structure in which the probe 20 is directly connected to the pipe 100 is also possible.

The probe 20 may be installed on the frame 10. In addition, the probe 20 may come into contact with the surface of the pipe 100 to enter ultrasonic waves into the pipe 100 and receive ultrasonic waves reflected from defects inside the pipe 100. The probe 20 may rotate along the circumference of the pipe 100 to measure all areas of the pipe 100.

The inertial sensor 30 may rotate with the probe 20. To this end, the inertial sensor 30 may be attached to the probe 20 or the frame 10 and connected. Therefore, the conversion device 40 can measure the position information of the probe 20 using the information of the inertial sensor 30.

2 is a view illustrating an output value of an inertial sensor according to a circumferential position of an inertial sensor of an ultrasonic inspection apparatus according to an embodiment.

As shown in Fig. 2, when the axis direction of the pipe 100 is defined as the Y axis, and the axis of the pipe thickness direction (perpendicular to the surface) is defined as the Z axis and the circumferential axis as the X axis, the inertial sensor 30 When rotating from 0 to 360 degrees, the output values of the Z axis and the X axis of the inertial sensor 30 are displayed according to the circumferential position θ.

The position angle θ in the circumferential direction of the inertial sensor 30 can be obtained by calculating inversely from the output values of these two axes, and the positional position of the probe 20 through the position difference between the inertial sensor 30 and the probe 20 I can get it.

The conversion device 40 may calculate position information of the inertial sensor 30 and convert the amount of movement according to the rotation of the inertial sensor 30 into a continuous pulse signal.

3 is a view specifically showing a conversion device of an ultrasound inspection apparatus according to an embodiment.

3, the conversion device 40 may include a pulse signal period setting unit 41, an inertial sensor position calculation unit 42, and a pulse signal output unit 43.

The pulse signal period setting unit 41 sets the period T of the pulse signal at an angle. The smaller the period of the pulse signal, the better the resolution, so more sophisticated ultrasonic inspection is possible.

The inertial sensor position calculator 42 calculates the position angle θ in the circumferential direction of the inertial sensor 30 using the output values of the X and Z axes output from the inertial sensor 30.

The pulse signal output unit 43 may output a pair of pulse signals A and B.

4 is a view for explaining a method of outputting the position information of the inertial sensor of the ultrasonic inspection apparatus according to an embodiment as a pulse signal according to the continuous movement of the probe using a conversion device.

4, first, the pulse signal period setting unit 41 sets the period T of the pulse signal (S10). Then, the inertial sensor position calculator 42 calculates the circumferential position θ of the inertial sensor 30 using the output values of the X and Z axes output from the inertial sensor 30 (S20). Then, the pulse signal output unit 43 continuously calculates the circumferential position θ according to the rotation of the inertial sensor 30 and outputs a pair of pulse signals A and B according to the period T. (S30).

At this time, the pulse signal A calculates the decimal point value R1 of the rotation angle/cycle and calculates and outputs 1 when R1 is greater than or equal to 0.5 and 0 when R1 is less than 0.5. The outputs 0 and 1 correspond to digital outputs, and output according to the voltage level used by the ultrasonic display device 50. If the digital outputs 0 and 1 of the ultrasonic display device 50 use voltages of 0V and 5V, the voltage is output accordingly.

Then, the pulse signal B calculates the value (R2) of (rotation angle-period/4)/period decimal point, and 1 when R2 is greater than or equal to 0.5 and 0 when R2 is less than 0.5. And output. The outputs 0 and 1 correspond to digital outputs, and output according to the voltage level used by the ultrasonic display device 50. If the digital outputs 0 and 1 of the ultrasonic display device 50 use voltages of 0V and 5V, the voltage is output accordingly.

In this way, a pair of pulse signals A and B having a phase difference of 90 degrees can be output.

FIG. 5 is a graph showing pulse signals A and B output at 2-degree cycles according to a continuous movement of the probe in the conversion device of the ultrasound inspection apparatus according to an embodiment, and FIG. 6 is a view of the ultrasound inspection apparatus according to an embodiment It is a graph showing the pulse signals A and B output by a 3-degree cycle according to the continuous movement of the position of the transducer in the converter.

5 and 6, the rotational travel distance can be known through the number of pulses of the pulse signals A and B, and the inertial sensor 30 through comparison between the pulse signal A and the pulse signal B having a phase difference of 90 degrees It can be seen whether is rotated forward or reverse.

In addition, it can be seen that when the period is set to 2 degrees, the number of pulses is larger than when the period is set to 3 degrees, so that the ultrasonic examination can be performed in more detail by setting the period to be small.

The pulse signals A and B are transmitted to the ultrasonic display device 50. The ultrasonic display device 50 may calculate the moving distance of the probe 20 using the pulse signals A and B, and through this, display the ultrasonic signal including the location information of the probe 20.

As described above, an embodiment of the present invention converts the position information of the inspection position of the pipe 100 into a pulse signal using the inertial sensor 30 and transmits it to the ultrasonic display device 50 to enable ultrasonic inspection.

In addition, since an embodiment of the present invention performs ultrasonic inspection using the inertial sensor 30 without using an optical encoder, the volume of the ultrasonic inspection device can be minimized.

In addition, by using the inertial sensor 30 and the conversion device 40 instead of the optical encoder to generate the same signal as the optical encoder, it is possible to be compatible with a conventional ultrasonic display device.

In addition, since the inertial sensor 30 performs ultrasonic inspection without contacting the pipe 100, it is possible to solve the sliding problem of the existing optical encoder wheel.

Although the present disclosure has been described through preferred embodiments as described above, the present invention is not limited thereto, and various modifications and variations are possible without departing from the scope of the claims described below. Those in the field will readily understand.

10: frame 20: probe
30: inertial sensor 40: converter
50: ultrasonic display device

Claims (6)

A probe that receives and receives ultrasonic waves through the pipe,
Inertial sensor connected to the probe to measure the position information of the probe,
A conversion device for converting and outputting the position information of the inertial sensor into a pulse signal, and
An ultrasonic display device receiving the pulse signal from the converter, measuring the moving distance of the probe using the pulse signal, and displaying the ultrasonic signal inside the pipe including location information of the probe
Including,
The conversion device
Pulse signal period setting unit for setting the period of the pulse signal,
An ultrasonic inspection device using an inertial sensor comprising an inertial sensor position calculating unit for calculating the circumferential position of the inertial sensor, and a pulse signal output unit for continuously outputting the pulse signal according to the movement of the probe. In claim 1,
The probe is an ultrasonic inspection device using an inertial sensor in contact with the surface of the pipe. In claim 2,
The inertial sensor is an ultrasonic inspection device using an inertial sensor rotating with the probe. delete In claim 1,
The pulse signal output unit generates a pair of pulse signals having a phase difference of 90 degrees, and compares them, an ultrasonic inspection device using an inertial sensor to determine the moving distance and forward or reverse rotation of the inertial sensor. In claim 1,
Further comprising a frame surrounding the pipe,
The probe is an ultrasonic inspection device using an inertial sensor connected to the frame.

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