ELECTROMAGNETIC ULTRASONIC DOUBLE-WAVE TRANSDUCER

Abstract

An electromagnetic ultrasonic double wave transducer, comprising a shell (1), and a permanent magnet assembly, a coil (4), a shielding layer (5), and a wire (6) which are provided in the shell (1). The permanent magnet assembly comprises a first permanent magnet (2) and a second permanent magnet (3) sleeved on the first permanent magnet (2). The magnetizing directions of the first permanent magnet (2) and the second permanent magnet (3) are perpendicular to the bottom of the shell (1), and the magnetic field directions of the first permanent magnet (2) and the second permanent magnet (3) are opposite. A non-conducting non-magnetic bushing material (9) is provided between the first permanent magnet (2) and the second permanent magnet (3), and upper end faces of the first permanent magnet (2) and the second permanent magnet (3) realize magnetic circuit closing by means of a magnetic circuit closing element (8). The coil (4) is fixed on the bottom of the shell (1) and is located below the first permanent magnet (2). The shielding layer (5) is provided between the lower end of the first permanent magnet (2) and the coil (4) and below the second permanent magnet (3). One end of the wire (6) is connected to the coil (4), and the other end is connected to the power supply and signal plug (7). The electromagnetic ultrasonic double-wave transducer can simultaneously stimulate longitudinal wave and transverse wave on the surface of the part to be inspected, and the inspection accuracy is improved.

Claims

1. An electromagnetic ultrasonic double wave transducer, comprising a shell (1), and a permanent magnet assembly, a coil (4), a shielding layer (5), and a wire (6) which are provided in the shell (1); said permanent magnet assembly comprises a first permanent magnet (2) and a second permanent magnet (3) sleeved on the first permanent magnet (2); the magnetizing directions of the first permanent magnet (2) and the second permanent magnet (3) are perpendicular to the bottom of the shell (1), and the magnetic field directions of the first permanent magnet (2) and the second permanent magnet (3) are opposite; a non-conducting non-magnetic bushing material (9) is provided between the first permanent magnet (2) and the second permanent magnet (3), and upper end faces of the first permanent magnet (2) and the second permanent magnet (3) realize magnetic circuit closing by means of a magnetic circuit closing element (8); said coil (4) is fixed on the bottom of said shell (1) and is located below said first permanent magnet (2); said shielding layer (5) is provided between the lower end of said first permanent magnet (2) and said coil (4) and below said second permanent magnet (3); one end of said wire (6) is connected to said coil (4), and the other end is connected to the power supply and signal plug (7).

2. The electromagnetic ultrasonic double-wave transducer of claim 1 wherein said first permanent magnet (2) is cylindrical while said second permanent magnet (3) is annular.

3. The electromagnetic ultrasonic double-wave transducer of claim 2 wherein the inner diameter of said second permanent magnet (3) is 1-15 mm larger than the outer diameter of said first permanent magnet (2).

4. The electromagnetic ultrasonic double-wave transducer of claim 2 wherein the lower end faces of said first permanent magnet (2) and said second permanent magnet (3) have a height difference of −3 mm to 3 mm.

5. The electromagnetic ultrasonic double-wave transducer of claim 2 wherein said coil (4) is helical, and the outer diameter thereof is larger than or equal to the outer diameter of said first permanent magnet (2) and smaller than the inner diameter of said second permanent magnet (3).

6. An electromagnetic ultrasonic double-wave transducer, comprising a shell (1), and a permanent magnet assembly, a coil (4), a shielding layer (5), and a wire (6) which are provided in said shell (1); said coil (4) is fixed on the bottom of said shell (1) and is located below said permanent magnet assembly; said shielding layer (5) is arranged between said permanent magnet assembly and said coil (4); one end of said wire (6) is connected to said coil (4) while the other end thereof is connected to the power supply and signal plug (7); said permanent magnet assembly comprises a third permanent magnet (12) and a fourth permanent magnet (13) wherein the fourth permanent magnet (13) are arranged side by side with said third permanent magnet (12) and located on two sides of the width direction of said third permanent magnet (12), and said fourth permanent magnet (13) and said third permanent magnet (12) are arranged at intervals and said intervals are made of non-conducting non-magnetic bushing material (9); the upper end faces of said third permanent magnet (12) and said fourth permanent magnet (13) realize magnetic circuit closing by means of a magnetic circuit closing element (8).

7. The electromagnetic ultrasonic double-wave transducer of claim 6 wherein the cross sections of every magnet of said third permanent magnet (12) and said fourth permanent magnet (13) is rectangular.

8. The electromagnetic ultrasonic double-wave transducer of claim 6 wherein said coil (4) is butterfly shaped.

9. The electromagnetic ultrasonic double-wave transducer of claim 1 or claim 6 wherein the non-conductive material (10) is filled between said coil (4) and said shielding layer (5), and the non-conducting non-magnetic material (11) is filled between said permanent magnet assembly and said shell (1).

10. The electromagnetic ultrasonic double-wave transducer of claim 1 or claim 6 wherein said shell (1) includes a shell body (1-1) and a wear plate (1-2) disposed at the lower end of said shell body (1-1).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] In order to more clearly illustrate the technical solutions of the embodiments of the invention, the drawings required to be used in the description of the embodiments are briefly introduced below, the drawings in the description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

[0026] FIG. 1 is a schematic structural diagram illustrating the embodiment 1 of the electromagnetic ultrasonic double-wave transducer in the invention;

[0027] FIG. 2 is a schematic structural diagram of embodiment 2 of the invention;

[0028] FIG. 3 is a sectional view of FIG. 2 along line A-A;

[0029] FIG. 4 illustrates that the electromagnetic ultrasonic double-wave transducer of embodiment 1 simultaneously excites transverse wave signals and longitudinal wave signals when detecting the Young's modulus and the Poisson's ratio of isotropic materials;

[0030] FIG. 5 is an enlarged view illustrating the gain of the electromagnetic ultrasonic double-wave transducer of embodiment 1 simultaneously excites transverse wave signals and longitudinal wave signals when detecting the Young's modulus and the Poisson's ratio of isotropic materials;

[0031] FIG. 6 is the longitudinal wave signals and the transverse wave signals generated simultaneously when the electromagnetic ultrasonic double-wave transducer of embodiment 1 detects tension of a bolt;

[0032] FIG. 7 illustrates that time-of-flight ratio of the transverse wave sound to the longitudinal wave sound generated simultaneously when the electromagnetic ultrasonic double-wave transducer of embodiment 1 is used for bolt tension detection is in one-to-one relationship;

[0033] FIG. 8 is an enlarged view illustrating the gain of the electromagnetic ultrasonic double-wave transducer of embodiment 2 simultaneously excites transverse wave signals and longitudinal wave signals when detecting the Young's modulus and the Poisson's ratio of isotropic materials;

[0034] Wherein:

[0035] 1. Shell; 1-1. Shell body; 1-2.Wear plate;

[0036] 2. The first permanent magnet;

[0037] 3. The second permanent magnet;

[0038] 4. Coil;

[0039] 5. Shielding layer;

[0040] 6. Wire;

[0041] 7. Power supply and signal plug;

[0042] 8. Magnetic circuit closing element;

[0043] 9. Non-conducting non-magnetic bushing material;

[0044] 10. Non-conductive material;

[0045] 11. Non-conducting non-magnetic material;

[0046] 12. The third permanent magnet;

[0047] 13. The fourth permanent magnet.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0048] The above-described solution is further illustrated below with reference to specific embodiments. It should be understood that these embodiments are for illustrative purposes and are not intended to limit the scope of the invention. The conditions used in the embodiments may be further adjusted according to the conditions of the particular manufacturer, and the conditions not specified are generally conditions used in routine experiments.

[0049] As is shown in FIG. 1, a schematic structural diagram of the embodiment in the invention provides an electromagnetic ultrasonic double-wave transducer, comprising a shell 1, and a permanent magnet assembly, a coil 4, a shielding layer 5, and a wire 6 which are provided in the shell 1.

[0050] The permanent magnet assembly comprises a first permanent magnet 2 and a second permanent magnet 3 sleeved on the first permanent magnet 2. The magnetizing directions of the first permanent magnet 2 and the second permanent magnet 3 are perpendicular to the bottom of the shell 1, and the magnetic field directions of the first permanent magnet 2 and the second permanent magnet 3 are opposite. A non-conducting non-magnetic bushing material 9 is provided between the first permanent magnet 2 and the second permanent magnet 3, and upper end faces of the first permanent magnet 2 and the second permanent magnet 3 realize magnetic circuit closing by means of a magnetic circuit closing element 8.

[0051] Said coil 4 is fixed on the bottom of said shell 1 and is located below said first permanent magnet 2. Said shielding layer 5 is provided between the lower end of said first permanent magnet 2 and said coil 4 and below said second permanent magnet 3. One end of said wire 6 is connected to said coil 4, and the other end is connected to a power supply and signal plug 7.

[0052] In this embodiment, the magnetic circuit closing element 8 is made of mild steel or ferrite with a thickness greater than 3 mm. The non-conducting non-magnetic bushing material 9 is made of plastic, rubber or polymer material, such as bakelite.

[0053] The inner diameter of said second permanent magnet 3 is 1-15 mm larger than the outer diameter of said first permanent magnet 2, and said coil 4 is helical, and the outer diameter thereof is larger than the outer diameter of said first permanent magnet 2 and smaller than the inner diameter of said second permanent magnet 3. The lower end face of the first permanent magnet 2 can be flush with that of the second permanent magnet 3, and they also can have a height difference of less than 3 mm, which means that the lower end face of the first permanent magnet 2 is located above that of the second permanent magnet 3, or is located below that of the second permanent magnet 3.

[0054] In this embodiment, the shielding layer 5 is a highly conductive copper sheet or silver sheet, and is attached to the lower ends of the first permanent magnet 2 and the second permanent magnet 3.

[0055] In order to further optimize the implementation effect of the invention, the non-conductive material 10 is filled between said coil 4 and said shielding layer 5, such as air, resin and non-conductive soft magnetic material; the non-conducting non-magnetic material is filled between said permanent magnet assembly and said shell 1, i.e., epoxy resin.

[0056] In this embodiment, said coil 4 is made of double-layer PCB board or wound by enameled wire.

[0057] In this embodiment, said shell 1 includes a shell body 1-1 and a wear plate 1-2 disposed at the lower end of said shell body 1-1; the wear plate 1-2 is made of ceramic wafer or epoxy plate and the shell body 1-1 is made of stainless steel, aluminum alloy or red copper material; the power supply and signal plug 7 is fixed at the upper part of the shell body 1-1.

[0058] As is shown in FIGS. 2 and 3, the schematic structural diagram of embodiment 2 is the same as the embodiment 1 except structure of the permanent magnet assembly and structure of the coil 4; the permanent magnet assembly comprises a third permanent magnet 12 and a fourth permanent magnet 13 wherein the fourth permanent magnet 13 are arranged side by side with said third permanent magnet 12 and located on two sides of the width direction of said third permanent magnet 12, and between said fourth permanent magnet 13 and said third permanent magnet 12 are non-conducting non-magnetic bushing material 9;

[0059] In this embodiment, the cross sections of said third permanent magnet 12 and said fourth permanent magnet 13 are rectangular and said coil 4 is butterfly shaped.

[0060] In the implementation, the first permanent magnet 2, the second permanent magnet 3, the third permanent magnet 12 and the fourth permanent magnet 13 are all made of NdFeB materials.

[0061] The electromagnetic ultrasonic transducer can simultaneously excite vertical downward-transmitted ultrasonic transverse waves and ultrasonic longitudinal waves on the near surface of a conductive or magnetic testing part such as low-carbon steel, aluminum alloy and the like, and the amplitude of the longitudinal waves excited by said electromagnetic ultrasonic transducer can reach 20% to 30% of the transverse waves at most in a test with a matched instrument. While the conventional electromagnetic ultrasonic transducer can hardly excite longitudinal wave.

[0062] For example, the Young's modulus and the Poisson's ratio of isotropic materials were detected by using the electromagnetic ultrasonic double-wave transducer of embodiment 1.

[0063] In isotropic materials, the elasticity modulus E and Poisson's ratio v are related to the velocity of the longitudinal wave C.sub.l and the transverse wave C.sub.S as follows:

[00001]$\begin{array}{cc}E=\frac{\rho C_s^2\left(3T^2-4\right)}{T^2-1}& \left(1\right)\\ v=\frac{T^2-2}{2\left(T^2-1\right)}& \left(2\right)\end{array}$

[0064] where T is defined as T≡C.sub.l/C.sub.S, ρ is the density, and taken 7.87×10.sup.3 kg/m.sup.3 for 20# carbon steel.

[0065] Therefore, the Young's modulus and the Poisson's ratio of the material can be estimated by detecting the longitudinal wave velocity, the transverse wave velocity and the density of the material.

[0066] A hand-held high-power ultrasonic testing instrument PREMAT-HS200 manufactured by Suzhou Phaserise Technology Co., Ltd. is used as an electromagnetic ultrasonic pulser/receiver equipped with the electromagnetic ultrasonic double-wave transducer of the invention. The testing part is selected from a CSK- II A standard sample according to JB/T 4730-2005 standard. The sample dimension is 300 mm long, 60 mm wide and 40 mm in height The electromagnetic ultrasonic transducer is placed in the middle of the upper surface of the sample to be tested, and is 170 mm away from the left edge of the sample, and 35 mm away from the upper edge. The test frequency is 4 MHz, the excitation voltage 1200 Vpp, the display delay 10 μs, the sampling time 80 μs, the sampling speed 100 MS/s, and the repetition rate 200 Hz. The test data for the automatic gain is shown in FIG. 4. Increasing the gain further on the basis of FIG. 4 results in FIG. 5. In FIG. 5, multiple periodic echoes and mode-converted waves are labeled, and it can be seen that the electromagnetic ultrasonic double-wave transducer of the invention excites longitudinal waves (first echo is LL) and transverse waves (first echo is SS) simultaneously on the surface of the sample.

[0067] Calculations from equations (1) and (2) using the data in table 1 lead to:

E=2.1226×1011 Pa   (3)

v=0.285   (4)

[0068] The results are very close to the nominal value of the sample.

TABLE-US-00001 TABLE 1 Time-of-flight of longitudinal wave and transverse wave excited on surface of the testing part. Average wave velocity of transverse LL SS SSSS SSSSSS wave Time (ns) 1354.13 24707 49402 74097 3239.5 m/s Sound velocity 5907.85 — — — — of longitudinal Waves (m/s)

[0069] The transducer of the invention can be used for accurate detection of bolt tension. According to the open literature 5(Yuping Shen, G. B. Ma, C. Ma, X. X. Zhu and J. H. Zhao, “Bolt stress inspection by EMAT and PZT”,15th Asia Pacific Conference for Non-Destructive Testing, Singapore), the Bolt tension σ can be expressed as

[00002]$\begin{array}{cc}\sigma =\frac{TO{F}_S.Math.C_{S0}-TO{F}_l.Math.C_{l0}}{\gamma \left(\partial +1/E\right)TO{F}_l.Math.C_{l0}-r\left(\beta +1/E\right){\mathrm{TOF}}_S.Math.C_{S0}}& \left(5\right)\end{array}$

[0070] wherein γ is the clamping length ratio of the bolt, namely the ratio of the length of the bolt under tension to the total length; E is the Young's modulus; a is the acoustic elastic coefficient of the transverse wave; β is the acoustic elastic coefficient of the longitudinal waves; C.sub.S0 and C.sub.l0 are transverse and longitudinal wave velocities in the absence of tension; TOF.sub.S is the fight time of bolt transverse wave; TOF.sub.l is the fight time of bolt longitudinal wave. For the bolt with calibrated material parameters, the tensile stress applied to the bolt can be calculated as long as TOF.sub.S and TOF.sub.l can be accurately measured. The transducer used by the invention can simultaneously excite longitudinal waves and transverse waves on the inspection surface end of the bolt. FIG. 6 shows that longitudinal wave (LL) and transverse wave (SS) signals are simultaneously excited on the tested surface end of a bolt with 42 mm nominal diameter by using the electromagnetic ultrasonic double-wave transducer of the invention. Thus, TOF.sub.S and TOF.sub.l values can be simultaneously and accurately measured. FIG. 7 is the experimental raw data of TOF.sub.S and TOF.sub.l ratio versus tensile stress applied to the 42 mm-nominal-diameter bolt in FIG. 6. during calibration by a hydraulic bolt tensile machine. As can be seen from FIG. 7, the correspondence between the two is a relatively smooth monotonous function in one-to-one correspondence, and the corresponding bolt tensile stress error range is relatively small. Professional data processing methods can also be applied to process the one-to-one monotone function shown in the FIG. 7, so as to obtain higher inspection precision for the bolt tensile stress.

[0071] For instance, Young's modulus and the Poisson's ratio of isotropic materials were measured by using the electromagnetic ultrasonic double-wave transducer of embodiment 2.

[0072] After selecting the same sample and measurement parameters as in embodiment 1, The FIG. 8 in embodiment 2 corresponds to FIG. 5 of embodiment 1. In FIG. 8, the amplitude of the longitudinal wave generated simultaneously with the transverse wave on the surface of the testing sample is about one third of that of the embodiment 1, but the final detection results of the Young's modulus and the Poisson's ratio are not much different from that of the embodiment 1. In addition, the electromagnetic ultrasonic double-wave transducer of embodiment 2 is directional, and is very advantageous for detecting the sound velocity of transverse waves and the longitudinal waves in each direction of a material having a regular texture, such as a cold-rolled steel sheet or an aluminum sheet.

[0073] The above embodiments are provided only for illustrating the technical concepts and features of the invention, and the purpose of the invention is to provide those skilled in the art with the understanding of the invention and to implement the invention, and not to limit the scope of the invention. All equivalent changes and modifications made according to the spirit of the invention should all fall within the protection scope of the invention.