The present application claims priority from Japanese application serial no. 2006-266254, filed on Sep. 29, 2006, the content of which is hereby incorporated by reference into this application.
The present invention relates to an ultrasonic testing apparatus and method thereof that are suitable for shortening time taken to inspect turbine forks.
To facilitate the manufacturing and maintenance of a turbine used in a power generating plant, its rotor and turbine blades are manufactured separately, and the structural portions of the forks of the turbine blades are inserted to the disc on the rotor and fixed by inserting pins into holes formed in the forks, as shown in
In conventional inspection for cracks in the fork holes, the turbine blades are taken off and magnetic particle testing (hereinafter referred to as MT) is then performed.
The MT is a method for detecting a leak of a magnetic flux from a defect when a magnetic field is applied to a test object as illustrated in
Accordingly, in fork hole inspection, there is an approach to ultrasonic testing (hereinafter referred to as UT). The UT is a method for sending an ultrasonic wave to a test object and receiving a reflected wave. Whether there is a defect can be determined on the basis of whether there is the reflected wave from the defect. If a UT sensor is placed at the root of the blade to make an ultrasonic wave directly incident to a place of a defect as shown in
As described above, non-destructive inspection targeted at embedded fork portions having complex shapes has not been considered.
An object of the present invention is to achieve non-destructive inspection of turbine forks without having to disassemble them.
The main feature of the present invention is to provide a sensor mounting tool for restricting the degree of freedom of UT sensor motion to rotation and parallel motion or a sensor moving apparatus for controlling the rotation and parallel motion of the UT sensor by using actuators and to identify a reflected wave coming from a defect by comparing ultrasonic testing signals with reference signals being geometric echoes.
A ultrasonic testing apparatus for turbine forks and method thereof of the present invention shorten inspection time because inspection is performed without the turbine blades and disc having to be separated.
In an ultrasonic testing method for turbine forks of turbine blades, by which the turbine blades are joined to a turbine disc, an ultrasonic testing sensor is mounted on a flat portion on a side surface of the turbine fork in a state that the turbine blades are joined to the turbine disc, and the ultrasonic testing sensor is used for ultrasonic testing of internal and external surfaces of the turbine fork by use of reflected waves from the internal surface of the turbine fork. Thus, the UT inspection can be performed without the turbine blade and turbine disc having to be separated.
To shorten the inspection time, a sensor mounting tool or sensor moving apparatus is provided to perform ultrasonic testing by sending and receiving ultrasonic waves from a side surface of the fork. This ultrasonic testing has a step for identifying a reflected wave from a defect of comparing ultrasonic testing signals with reference signal being geometric echoes by comparing ultrasonic testing signals with reference signal being geometric echoes.
A embodiment concerning ultrasonic testing of a fork, in which a UT sensor mounting tool is used, will be described according to
Since the UT sensor mounting tool 3 is provided, the sensor 2 can be appropriately mounted with ease on a flat portion on a side surface of the turbine fork. Since ultrasonic testing is performed for the flat side, the magnitudes of incident echoes can be equalized, enabling defects (flaws) to be appropriately detected.
The fixing pawls 4 are setted to the elementary part of the turbine blades 41 so that the UT sensor mounting tool 3 is fixed by means of the magnetic force of the magnet holder 5. The UT sensor 2 is screwed to the UT sensor rotating knob 6. When the UT sensor rotating knob 6 is rotated, the UT sensor 2 rotates in the θ1 direction in
The arm 7 is provided with a through-groove. Since the UT sensor rotating knob 6 is installed in such a way that it passes through the groove, the sensor can move in the Y direction in
Since a means for rotating the ultrasonic testing sensor 2 is provided as described above, the sensor 2 can be appropriately mounted with ease on a flat portion on a side surface of the turbine fork, and thereby mounting conditions can be set with ease during ultrasonic testing.
An incident angle of an ultrasonic wave to the target under inspection is adjusted by providing a wedgy shoe 19 (acrylic) between the UT sensor 2 and the target under inspection.
sin(θ1)÷V1=sin(θ2)÷V2 (1)
V1: Ultrasonic velocity in the shoe
θ1: Incident angle of an ultrasonic wave from the shoe to the test object (=angle at the end of the shoe)
V2: Ultrasonic velocity in the test object
θ2: Incident angle of an ultrasonic wave in the test object
By screwing the shoe 19 of this type to the UT sensor 2, the incident angle of an ultrasonic wave can be adjusted.
Since the ultrasonic testing sensor 2 is used for ultrasonic testing of internal and external surfaces of the turbine fork by use of reflected waves from the internal surface of the turbine fork, it becomes possible to perform inspection without the turbine blade and turbine disc having to be separated.
The ultrasonic testing steps in the embodiment 1, which are indicated in
In step 201, the UT sensor mounting tool 3 is mounted to a reference test piece having no defect and the same size as the test object.
In step 202, geometric echoes (reference echoes) reflected at concavities and convexities on the reference test piece as shown in
In step 203, the UT sensor mounting tool 3 is mounted to the test object, ultrasonic testing is performed, and ultrasonic testing signals as shown in
In step 204, the shoe is replaced to change the ultrasonic wave incident angle, that is, the place to which the ultrasonic wave is incident is changed.
As described above, the ultrasonic testing sensor is used for ultrasonic testing of internal and external surfaces of the turbine fork by use of reflected waves from the internal surface of the turbine fork, desired reflected ultrasonic waves generated in the turbine fork are used as reference signals, and a reflected wave from a defect is identified by comparing detected ultrasonic testing signals with the reference signals. Thus, it becomes possible to detect a defect in ultrasonic testing without the turbine blade and turbine disc having to be separated.
Furthermore, since an ultrasonic wave is made incident and skipped, problems with, for example, steps of the fork portion having a complex geometric can be avoided. An ultrasonic wave is also made incident from a side surface of the fork portion and skipped, both the internal surface and external surface of the fork portion can be inspected from the same testing surface.
In present embodiment with the structure described above, since the scale of the UT sensor mounting tool 3 is used to enable the quantification of the incident direction of the ultrasonic wave, the location at which an ultrasonic wave is incident can be determined. Furthermore, since the presence or absence of a defect signal is determined by using geometric echoes as the reference echoes, whether there is a defect can be easily determined. Accordingly, time taken to inspect the turbine fork can be shortened.
An embodiment of the present invention related to ultrasonic testing of turbine forks in which a UT sensor moving apparatus is used will be described according to
dt=(max(L)−Li)÷V (2)
Lij=((xij−xf)2+(yij−yf)2+(zf)2)1/2 (3)
max (L): Maximum distance [m] between the element and the focus point
Lij: Distance [m] between the i-th device in the j-th row and the focus point
V: Ultrasonic velocity [m/s]
xij: x coordinate [m] of the i-th element in the j-th row
xf: x coordinate [m] of the focus point
yij: y coordinate [m] of the i-th element in the j-th row
yf: y coordinate [m] of the focus point
zf: z coordinate [m] of the focus point
V=5900 [m/s]
xij=(0.5×i−0.25)×10−3 [m] (i=1 to 8)
yij=(1.3×j−0.65)×10−3 [m] (j=1 to 3)
xf=2×10−3 [m]
yf=3×10−3 [m]
zf=10×10−3 [m]
The above V, xij, yij, xf, yf, and zf are substituted into equations (2) and (3) and the differences in ultrasonic oscillation start time is calculated. A result shown in
In step 211, the UT sensor mounting apparatus is mounted to a reference test piece having the same size and same shape as the test object and no defect.
In step 212, the three-dimensional shape of the test object and the coordinates of a place of a defect in the test object are input to the personal computer 17.
In step 213, ultrasonic wave propagation paths are analyzed by using the three-dimensional geometric data.
In step 211, ultrasonic wave propagation paths when an ultrasonic wave is emitted are calculated with the input coordinates of the defect place being set as a start point. The calculation is based on the fact that the ultrasonic wave propagates straight until it hits the external periphery of a fork and that when the ultrasonic wave hits the external periphery and reflects, the incident angle and reflection angle are symmetrical with respect to the normal line at the reflection point as shown in
In step 214, coordinates of a central point of the UT sensor 2 and a distance of the ultrasonic wave propagation path to the side surface of the fork, obtained in step 213, are substituted in equations (4) and (5) to obtain Lij. The central point uses a point from which the ultrasonic wave is emitted to the side surface of the fork, obtained in step 213. The obtained Lij is substituted into equation (2) to calculate differences in ultrasonic wave oscillation start time among the ultrasonic elements 31 including in the UT sensor 2.
Lij′=((xs−xij)2+(ys−yij)2+(zs−zij)2 (4)
Lij=(L12+Lij′2)1/2 (5)
L1: Distance [m] of the ultrasonic wave propagation path to the side surface of the fork, obtained in step 213
Lij′: Distance [m] between the central point of the sensor and the i-th element in the j-th row
xs: x coordinate [m] of the central point of the sensor
ys: y coordinate [m] of the central point of the sensor
zs: z coordinate [m] of the central point of the sensor
xij: x coordinate [m] of the i-th element in the j-th row
yij: y coordinate [m] of the i-th element in the j-th row
zij: z coordinate [m] of the i-th element in the j-th row
In step 215, the UT sensor 2 is moved to the ultrasonic wave incident position on the reference test piece and the reference signals (geometric echoes) are obtained.
In step 216, the UT sensor moving apparatus is mounted to the test object and an ultrasonic testing signal is obtained.
In step 217, the reference signals are subtracted from the ultrasonic testing signals and determine the presence or absence of a defect is determined according to whether the value obtained by subtracting the reference signal from the ultrasonic testing signal is plus value. If the value obtained is plus value, it indicates that there is a defect.
The three-dimensional geometric data on the test object is input from a storage medium 27 such as a magneto-optical disc (MO), compact disc (CD), or digital versatile disc (DVD), and the coordinates of a position of a defect are input from the keyboard 26. The three-dimensional geometric data and the coordinates of the defect position are passed to the CPU 21 through an I/O port 25 in the personal computer 17. The CPU 21 then calculates the ultrasonic wave propagation path and a difference in ultrasonic wave oscillation start time.
The UT sensor 2 is moved to the ultrasonic wave incident position based on the analysis result for the ultrasonic wave propagation path by supplying power to the actuators 11 through the I/O port 25 in the personal computer 17 and the actuator driver 12. An ultrasonic wave is sent into the test object (turbine fork) by applying a voltage according to the differences in ultrasonic wave oscillation start time to the ultrasonic elements 31 through the I/O port 25 in the personal computer 17, and an I/O port 25 and a D/A converter 30 in the ultrasonic test equipment 1. The ultrasonic wave reflected at a concavity and convexity on the test object is converted by the UT sensor 2 into a voltage. This converted voltage is transmitted to the CPU 21 through an A/D converter 29 and the I/O port 25 in the ultrasonic test equipment 1, and the I/O port 25 in the personal computer 17.
The sensor position, the differences in ultrasonic wave oscillation start time, and ultrasonic testing results are stored in at least one of a hard disc drive 22 (HDD), a random access memory (RAM) 23, and a read-only memory (ROM) 24 by the CPU 21. The CPU 21 also subtracts the reference signals from the ultrasonic testing signals and displays the result on a monitor 28 through the I/O port 25 in the personal computer 17.
As described above, in the present embodiment, since the location to mount the UT sensor 2 and the incident angle of an ultrasonic wave are obtained through analysis, and movement of the UT sensor 2 and ultrasonic testing are automatically performed, the inspection time of the turbine forks is further shortened, as compared with the embodiment 1.
Number | Date | Country | Kind |
---|---|---|---|
2006-266254 | Sep 2006 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4887648 | Cunnane | Dec 1989 | A |
5239218 | Hashimoto et al. | Aug 1993 | A |
5445027 | Zorner | Aug 1995 | A |
5942690 | Shvetsky | Aug 1999 | A |
6668651 | Beausseroy et al. | Dec 2003 | B2 |
7428842 | Fair et al. | Sep 2008 | B2 |
7543506 | Merendino, Sr. | Jun 2009 | B2 |
Number | Date | Country |
---|---|---|
57-120858 | Jul 1982 | JP |
62-261955 | Nov 1987 | JP |
2000-214136 | Aug 2000 | JP |
2002-090348 | Mar 2002 | JP |
2002-310998 | Oct 2002 | JP |
Number | Date | Country | |
---|---|---|---|
20090120192 A1 | May 2009 | US |