JPH0249661B2 - TANSHOHOHO - Google Patents
TANSHOHOHOInfo
- Publication number
- JPH0249661B2 JPH0249661B2 JP4891884A JP4891884A JPH0249661B2 JP H0249661 B2 JPH0249661 B2 JP H0249661B2 JP 4891884 A JP4891884 A JP 4891884A JP 4891884 A JP4891884 A JP 4891884A JP H0249661 B2 JPH0249661 B2 JP H0249661B2
- Authority
- JP
- Japan
- Prior art keywords
- magnetic field
- detection
- coils
- magnetic
- inspected
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Classifications
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/72—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables
- G01N27/82—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws
- G01N27/90—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws using eddy currents
- G01N27/904—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws using eddy currents with two or more sensors
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/72—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables
- G01N27/82—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws
- G01N27/90—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws using eddy currents
- G01N27/9046—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws using eddy currents by analysing electrical signals
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- Chemical & Material Sciences (AREA)
- Chemical Kinetics & Catalysis (AREA)
- Electrochemistry (AREA)
- Physics & Mathematics (AREA)
- Health & Medical Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Analytical Chemistry (AREA)
- Biochemistry (AREA)
- General Health & Medical Sciences (AREA)
- General Physics & Mathematics (AREA)
- Immunology (AREA)
- Pathology (AREA)
- Investigating Or Analyzing Materials By The Use Of Magnetic Means (AREA)
Description
【発明の詳細な説明】
〔産業上の利用分野〕
本発明は鋼管、スラブ等の被検査材の表面に存
する割れ疵、穴状のピツト疵等の表面疵をその性
状に関わりなく正確に検出できる探傷方法を提案
するものである。[Detailed Description of the Invention] [Field of Industrial Application] The present invention is capable of accurately detecting surface flaws such as cracks and pit flaws existing on the surface of inspected materials such as steel pipes and slabs, regardless of their properties. This paper proposes a possible flaw detection method.
金属材の表面疵の探傷方法としては種々の非破
壊検査法が実用化されており、存在が予想される
欠陥に応じて一種若しくは複数種類の方法が適用
されている。
Various non-destructive testing methods have been put into practical use as methods for detecting surface flaws in metal materials, and one or more methods are applied depending on the defects expected to exist.
例えば予想される疵の方向がある程度定まつて
いる割れ疵の検出には主として被検査材の表面か
らの漏洩磁束を検出する磁気探傷法が適用され、
厚み方向に延びるだけのビツト疵の検出には渦流
探傷法が適用されている。 For example, magnetic flaw detection, which detects leakage magnetic flux from the surface of the material to be inspected, is mainly applied to detect cracks where the expected direction of the flaw is determined to some extent.
Eddy current flaw detection is applied to detect bit flaws that only extend in the thickness direction.
前者の磁気探傷法は鉄鋼材料等の強磁性体の
表面欠陥の検出に優れている。割れが開口して
いない地きずのような欠陥でも検出できる。欠
陥の位置、表面上の長さの検出が可能であるとい
う長所を有している。 The former magnetic flaw detection method is excellent for detecting surface defects in ferromagnetic materials such as steel materials. Even defects such as ground scratches without open cracks can be detected. It has the advantage that it is possible to detect the position of the defect and its length on the surface.
また、後者の渦流探傷法は探傷結果が直接的
に電気的出力として得られる。非接触であるの
で試験速度が速い。表面欠陥の検出に適してい
る。欠陥、材質、寸法変化等に対しても追従で
き適用範囲が広い。信号と欠陥体積とが略比例
関係になる、等の長所を有している。 Furthermore, in the latter eddy current flaw detection method, the flaw detection results are directly obtained as electrical output. Since it is non-contact, testing speed is fast. Suitable for detecting surface defects. It can also track defects, material changes, dimensional changes, etc., and has a wide range of applications. It has advantages such as a substantially proportional relationship between the signal and the defect volume.
また、上記磁気探傷法では、疵と直角な方向に
磁化した場合には有効であるが、疵と同方向に磁
化した場合には、疵部分には磁極が生じないので
被検査材表面からの漏洩磁束が微少であり、探傷
が不可能であつた。しかし現在では下記に示す様
に、複数の磁場を利用する方法で疵の方向に関係
なく探傷できるようになつてきた。 In addition, the magnetic flaw detection method described above is effective when magnetized in the direction perpendicular to the flaw, but if it is magnetized in the same direction as the flaw, no magnetic pole is generated in the flaw, so there is no magnetic pole from the surface of the material to be inspected. The leakage magnetic flux was so small that flaw detection was impossible. However, as shown below, it has now become possible to detect flaws regardless of their direction by using multiple magnetic fields.
例えば第1図に示す様に丸棒鋼1に直接軸方向
の通電を行つて円周方向に磁化し、また、丸棒鋼
1を囲繞するコイルに通電して軸方向に磁化し、
前者にて周方向の表面疵1aを、後者にて軸方向
の表面疵1bを各検出する方法が知られている。 For example, as shown in FIG. 1, a round steel bar 1 is directly energized in the axial direction to magnetize it in the circumferential direction, and a coil surrounding the round bar 1 is energized to be magnetized in the axial direction.
A method is known in which the former detects surface flaws 1a in the circumferential direction, and the latter detects surface flaws 1b in the axial direction.
また、第2図に示す様に管材1′を囲繞する1
対のコイル2,2と、管材1′の直径方向両側に
磁極を対向させた磁石3とをタンデムに配し、前
者にて管材1′の軸方向に磁化し、その磁場にて
円周方向の表面疵1′bを磁場検出器2aにて検
出し、後者にて管材1′の周方向に磁化し、その
磁場にて軸方向の表面疵1′aを磁場検出器3a
にて検出する方法も知られている。 In addition, as shown in FIG.
A pair of coils 2, 2 and magnets 3 with magnetic poles facing each other on both sides of the tube 1' in the diametrical direction are arranged in tandem, and the former magnetizes the tube 1' in the axial direction, and the magnetic field generates magnetization in the circumferential direction. The surface flaw 1'b is detected by the magnetic field detector 2a, and the latter magnetizes the tube material 1' in the circumferential direction, and the magnetic field detects the surface flaw 1'a in the axial direction by the magnetic field detector 3a.
Detection methods are also known.
しかしながら、金属材の表面に発生する疵は割
れ疵以外にピツト疵と呼ばれるものもあり、上記
した磁気探傷ではピツト疵を検出し難い。従つて
ピツト疵の検出が必要な場合は渦流探傷法に依る
必要がある。このために被検査材、その疵性状に
よつては複数の探傷法に依らざるを得ないという
煩わしさがあつた。 However, in addition to cracking defects, there are also defects called pit defects that occur on the surface of metal materials, and it is difficult to detect pit defects by the magnetic flaw detection described above. Therefore, if it is necessary to detect pit flaws, it is necessary to rely on eddy current flaw detection. For this reason, depending on the material to be inspected and the nature of the flaw, it is necessary to use a plurality of flaw detection methods, which is cumbersome.
そして、複数の探傷法を適用する場合には、被
検査材のパスラインに割れ疵、ピツト疵夫々専用
の探傷装置を設置する必要があり、このため設備
が大型化しそのコストが高くなり、みた、各探傷
装置にて独立的に検査を行うものであるので検査
コストが高くなるという難点があつた。また、上
記の如く従来の磁気探傷法においては被検査材の
磁化手段が大型のものとなり、その検出部の被検
査材への追随性が悪く精度の良い検出が行えない
という難点もあつた。 When multiple flaw detection methods are applied, it is necessary to install dedicated flaw detection equipment for cracks and pit flaws on the pass line of the inspected material, which increases the size of the equipment and increases the cost. However, since each flaw detection device performs the inspection independently, there was a problem in that the inspection cost was high. In addition, as mentioned above, in the conventional magnetic flaw detection method, the means for magnetizing the material to be inspected is large, and the detection part has a poor ability to follow the material to be inspected, making it impossible to perform accurate detection.
本発明は斯かる事情に鑑みてなされたものであ
り、被検査材の表面に沿う方向の同一線上に軸心
を位置せしめた、または夫々の軸心が被検査材の
表面に直交するようにして位置せしめた2つのコ
イルに、それらの波形が共に正極性(又は負極
性)となる期間及び相互に逆極性となる期間を有
するように同周波数の励磁電流を通電することに
より、両コイルと対向する被検査材の表面部分
に、これに沿う向きとなる磁場及びこれに直交す
る向きとなる磁場を周期的に形成せしめ、これら
の磁場の磁束変化を両コイル間に設けた磁場検出
器にて同期的に検出することとして、磁気探傷、
渦流探傷を間欠的に行わしめる如くになし、割れ
疵、ピツト疵等の疵の種類に関係なく正確な検出
が行える探傷方法を提供することを目的とする。
The present invention has been made in view of the above circumstances, and provides a method of arranging the axes on the same line along the surface of the material to be inspected, or making the respective axes perpendicular to the surface of the material to be inspected. By applying an excitation current of the same frequency to two coils positioned at the same position, the waveforms of both coils have a period in which they have positive polarity (or negative polarity) and a period in which they have mutually opposite polarity. A magnetic field oriented along this and a magnetic field oriented perpendicular to this are periodically formed on the surface of the opposing inspected material, and changes in the magnetic flux of these magnetic fields are detected by a magnetic field detector installed between both coils. Magnetic flaw detection,
To provide a flaw detection method that performs eddy current flaw detection intermittently and enables accurate detection regardless of the type of flaws such as cracks and pit flaws.
本発明に係る探傷方法は、夫々の軸心が被検査
材の表面に沿う同一線上にあるように、または
夫々の軸心が被検査材の表面に直交するように並
設した2つのコイルに同周波数の位相の異なる励
磁電流を通電し、前記被検査材の表面の両コイル
と対向する部分に、これに沿う向きとなる磁場及
びこれに直交する向きとなる磁場を夫々周期的に
形成せしめ、この部分に設けた磁場検出器にて各
磁場形成時の磁束変化を検出することを特徴とす
る。
The flaw detection method according to the present invention uses two coils arranged in parallel so that their axes are on the same line along the surface of the material to be inspected, or so that their axes are orthogonal to the surface of the material to be inspected. Excitation currents of the same frequency and different phases are applied to periodically form a magnetic field along the surface of the material to be inspected and a magnetic field perpendicular to the coils on the surface of the material to be inspected, respectively. , is characterized in that a magnetic field detector provided in this part detects changes in magnetic flux when each magnetic field is formed.
先ず本発明の原理について説明する。第3図に
示す様に軸長方向に移送される被検査材たる鋼管
11の中心の真上から左右方向に同一距離離隔し
た位置には、夫々励磁コイル31a,31bを配
置してある。両励磁コイル31a,31bの軸心
は鋼管11の接線方向を向き、同一の軸心を共有
している。両励磁コイル31a,31b配置位置
の中央であつて、鋼管11の最上側面から僅かに
上方に離隔した位置には感磁ダイオードからなる
磁場検出器32を設けてある。
First, the principle of the present invention will be explained. As shown in FIG. 3, excitation coils 31a and 31b are respectively arranged at positions spaced apart from each other by the same distance in the left-right direction from directly above the center of the steel pipe 11, which is the material to be inspected, which is being transported in the axial direction. The axes of both excitation coils 31a and 31b face the tangential direction of the steel pipe 11, and share the same axis. A magnetic field detector 32 made of a magnetosensitive diode is provided at the center of the excitation coils 31a, 31b at a position slightly upwardly separated from the uppermost side surface of the steel pipe 11.
このような構成において、コイル31aには第
4図aに示す如き正弦波形の励磁電流を通電し、
また、コイル31bにはこの励磁電流よりも位相
が90゜進んだ第4図bに示す如き余弦波形の励磁
電流を通電する。コイル31a,31bの巻回方
向が同一であるとすると、両電流の極性が一致す
る期間又は逆になる期間が存在する。例えば、第
4図では位相が0゜〜90゜に相応する期間では共に
正極性であり、180゜〜270゜に相応する期間では共
に負極性であり、一方90゜〜180゜、270゜〜360゜に相
応する期間では逆極性になつている。両電流の極
性が一致する期間では鋼管11の表面における両
電流による磁場の方向は同一になる。 In such a configuration, the coil 31a is supplied with an excitation current having a sinusoidal waveform as shown in FIG. 4a,
Further, an excitation current having a cosine waveform as shown in FIG. 4b, which is 90 degrees ahead of this excitation current in phase, is applied to the coil 31b. Assuming that the winding directions of the coils 31a and 31b are the same, there is a period in which the polarities of both currents are the same or opposite. For example, in Fig. 4, the phase is both positive in the period corresponding to 0° to 90°, negative polarity in the period corresponding to 180° to 270°, while the phase is negative in the period corresponding to 90° to 180°, 270° to In the period corresponding to 360°, the polarity is reversed. During the period when the polarities of both currents match, the directions of the magnetic fields due to both currents on the surface of the steel pipe 11 are the same.
この場合に両励磁コイル31a,31bの下方
に位置する鋼管11の表層部には第5図aに示す
如く鋼管11の表面に沿う磁場(以下、同方向磁
場という)が形成される。一方、両電流の極性が
逆になる期間では鋼管11の表面における両電流
による磁場の方向は逆になる。 In this case, a magnetic field along the surface of the steel pipe 11 (hereinafter referred to as a co-directional magnetic field) is formed in the surface layer of the steel pipe 11 located below both excitation coils 31a and 31b, as shown in FIG. 5a. On the other hand, during the period in which the polarities of both currents are reversed, the directions of the magnetic fields due to both currents on the surface of the steel pipe 11 are reversed.
従つて、この場合に両励磁コイル31a,31
b間には第5図bに示す如く鋼管11の表面に対
して垂直となる磁場(以下異方向磁場という)が
形成され、この異方向磁場より両励磁コイル31
a,31bの下方に位置する鋼管11の表面には
該磁場を中心とする渦電流が発生せしめられるこ
とになる。このような同方向磁場及び異方向磁場
は第4図に示す如く周期的に現れる。 Therefore, in this case, both excitation coils 31a, 31
As shown in FIG. 5b, a magnetic field perpendicular to the surface of the steel pipe 11 (hereinafter referred to as a different direction magnetic field) is formed between the two excitation coils 31 and 31.
An eddy current centered on the magnetic field is generated on the surface of the steel pipe 11 located below the magnetic field a and 31b. Such magnetic fields in the same direction and magnetic fields in different directions appear periodically as shown in FIG.
而して、同方向磁場形成時に鋼管11の表面に
割れ疵C〔第5図a参照〕が存在する場合は当該
割れ疵部にて同方向磁場から磁束が第5図aに示
す如く漏洩する。この漏洩磁束は鋼管11の表面
に垂直な方向の磁界を検出する磁場検出器32に
て検出されることになる。 Therefore, if a crack C [see Fig. 5a] exists on the surface of the steel pipe 11 when a codirectional magnetic field is formed, magnetic flux leaks from the codirectional magnetic field at the crack as shown in Fig. 5a. . This leakage magnetic flux is detected by a magnetic field detector 32 that detects a magnetic field in a direction perpendicular to the surface of the steel pipe 11.
一方、異方向磁場形成時に鋼管11の表面にピ
ツト疵P〔第5図b参照〕が存在する場合は当該
ピツト疵部にて渦電流の向きが乱れ、それに伴な
い渦電流による磁場が乱れ、これが磁場検出器3
2にて検出される。そして、これら磁場検出器3
2の同方向磁場形成時及び異方向磁場形成時の出
力は該磁場検出器32に接続された同期検波回路
43a及び43bにて夫々同期検波される。これ
により割れ疵C及びピツト疵Pの検出及び弁別が
可能となるのである。なお、両電流の位相差は
90゜に限るものではなく、同方向磁場及び異方向
磁場を効果的に形成できる位相差であればよい。 On the other hand, if a pit flaw P (see Fig. 5b) exists on the surface of the steel pipe 11 when a magnetic field is formed in a different direction, the direction of the eddy current is disturbed at the pit flaw, and the magnetic field due to the eddy current is accordingly disturbed. This is magnetic field detector 3
Detected at 2. And these magnetic field detectors 3
The outputs when the two magnetic fields are generated in the same direction and when the magnetic fields are generated in different directions are synchronously detected by synchronous detection circuits 43a and 43b connected to the magnetic field detector 32, respectively. This makes it possible to detect and differentiate cracks C and pit defects P. In addition, the phase difference between both currents is
The phase difference is not limited to 90 degrees, but may be any phase difference that can effectively form magnetic fields in the same direction and magnetic fields in different directions.
以下本発明をその実施例を示す図面に基づいて
詳述する。第6図は本発明に係る探傷方法の実施
に使用する装置の検出部周りの構造を示す模式的
正面図、第7図はその左側面図、第8図は検出部
の検出器ホルダ周りを拡大して示す正面断面図、
第9図はその左側半断面図である。
DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below based on drawings showing embodiments thereof. Fig. 6 is a schematic front view showing the structure around the detection part of the device used to implement the flaw detection method according to the present invention, Fig. 7 is a left side view thereof, and Fig. 8 is a schematic front view showing the structure around the detector holder of the detection part. An enlarged front sectional view,
FIG. 9 is a left half sectional view thereof.
図中11は鋼管であつて、図示しない搬送装置
により軸心回転されつつ軸長方向に移送される。
鋼管11の移送域の上方には鋼管11の移送方向
に適長離隔した1対のアーム12,12が図示し
ない駆動手段により鉛直面内での回動自在に枢支
されている。アーム12,12の先端部には本発
明装置の検出部Aが鉛直面内での回動自在に枢支
されている。検出部Aは鋼管11がその下方に移
送されて来て、その先端部が通過した時点でアー
ム12,12の下方への回動により下降せしめら
れ鋼管11の上側面に当接せしめられ本発明の探
傷が行われる。鋼管11が検出部Aの下方にない
場合はアーム12,12の上方への回動により所
定の退避位置迄上昇せしめられる。なお、アーム
12,12の鉛直方向への回動は鋼管11の移送
域に設置された図示しないフオトセンサの管端検
知信号により行われる。 In the figure, reference numeral 11 denotes a steel pipe, which is rotated about its axis and transported in the axial direction by a transport device (not shown).
Above the transfer area of the steel pipe 11, a pair of arms 12, 12 which are spaced apart by an appropriate length in the transfer direction of the steel pipe 11 are pivotally supported by a drive means (not shown) so as to be rotatable in a vertical plane. A detection unit A of the device of the present invention is pivotally supported at the tips of the arms 12, 12 so as to be rotatable in a vertical plane. The detection part A is moved downward when the steel pipe 11 is transferred, and when the tip thereof passes, the arms 12 and 12 are rotated downward to lower the detection part A and come into contact with the upper surface of the steel pipe 11. flaw detection is carried out. If the steel pipe 11 is not below the detection part A, the arms 12 and 12 are rotated upward to be raised to a predetermined retracted position. The vertical rotation of the arms 12, 12 is performed by a tube end detection signal from a photo sensor (not shown) installed in the transfer area of the steel tube 11.
次に検出部Aについて説明する。アーム12,
12の先端部には矩形状の検出部取付板13が水
平連結ピン14,14により左右方向への揺動可
能に枢支連結されている。取付板13の下面の左
側には円筒状の追従ローラ支持部材15,15が
垂設されており、その先端に側面視倒立U字状の
追従ローラ支承部材15a,15aを備えてい
る。取付板13下方の右側には該取付板13の下
面に垂設された支持部材13aを介して同様の追
従ローラ支持部材16(図面では手前側のみ現わ
れている)がその長手方向を水平方向として取付
けられている。その先端には追従ローラ支承部材
15aと同様の追従ローラ支承部材16aを左方
に向けて備えている。各支承部材15a,15
a,16aには追従ローラ17,17……を鋼管
11の軸心と平行な軸心回りの回転自在に軸支し
てあり、追従ローラ17,17……の鋼管11の
外周面転接位置は鋼管11の中心を通る鉛直面に
関して左右対称となつている。各追従ローラ1
7,17……は軸心回転する鋼管11の上側面上
に転接し、検出部Aの鋼管11に対する追随を可
能ならしめている。 Next, the detection section A will be explained. Arm 12,
A rectangular detection unit mounting plate 13 is pivotally connected to the distal end of the detection unit 12 by horizontal connecting pins 14, 14 so as to be swingable in the left-right direction. Cylindrical follow-up roller support members 15, 15 are vertically disposed on the left side of the lower surface of the mounting plate 13, and follow-up roller support members 15a, 15a each having an inverted U-shape in side view are provided at their tips. On the lower right side of the mounting plate 13, a similar follow-up roller support member 16 (only the front side is visible in the drawing) is connected via a support member 13a vertically provided on the lower surface of the mounting plate 13, with its longitudinal direction being the horizontal direction. installed. A follow-up roller support member 16a similar to the follow-up roller support member 15a is provided at its tip facing leftward. Each support member 15a, 15
Follower rollers 17, 17... are rotatably supported on a, 16a so as to be rotatable about an axis parallel to the axis of the steel pipe 11, and the positions where the follower rollers 17, 17... roll into contact with the outer circumferential surface of the steel pipe 11 are fixed. are symmetrical with respect to a vertical plane passing through the center of the steel pipe 11. Each follower roller 1
7, 17, . . . are in rolling contact with the upper surface of the steel pipe 11 rotating on its axis, allowing the detection section A to follow the steel pipe 11.
取付板13の下面中央には側面視U字状の支持
部材18が取付けられている。支持部材18の底
面中央には筒状のベアリングハウジング19がそ
の長手方向を上下方向として嵌着されており、該
ベアリングハウジング19にはスラストベアリン
グ20を同心的に嵌合してある。スラストベアリ
ング20には摺動軸21を内嵌してあり、その上
端には円板状のストツパ22を固着してあり、摺
動軸21のスラストベアリング20からの抜けを
防止している。摺動軸21の下端部は少し大径の
鍔部21aとしてあり、この鍔部21aとベアリ
ングハウジング19との間に摺動軸21を下方へ
付勢すべく摺動軸21に囲繞させてコイルバネ2
8を介装してある。該鍔部21aの下端には長方
形状のスプリング受板23が固着されており、該
スプリング受板23の下面には正面視門形のホル
ダ支承部材24が固着されている。支承部材24
の両側壁には夫々ベアリング25,25を軸心方
向を左右方向として嵌合してある。支承部材24
間には、支承部材24よりも左右方向長さが少し
短かく前後方向長さが長い。下面が開口した直方
体状のホルダカバー26が遊嵌されており、その
左右側壁中央部に設けた軸部26a,26aをベ
アリング25,25の内輪に嵌着してある。これ
によりホルダカバー26はベアリング25,25
の軸心回りの回動が自在となつている。スプリン
グ受板23〜ホルダカバー26間の所定の位置に
はスプリング27,27を係着して、ホルダカバ
ー26を下方に向けて付勢している。スプリング
27,27、コイルバネ28は鋼管11に曲り、
変形等が存在する場合の検出部Aのベアリング2
5,25の軸心回り及び上下方向への振動を吸収
するためのものであり、これにより検出部Aの鋼
管11に対する追随性の向上を図つている。 A support member 18 having a U-shape in side view is attached to the center of the lower surface of the mounting plate 13 . A cylindrical bearing housing 19 is fitted into the center of the bottom surface of the support member 18 with its longitudinal direction facing up and down, and a thrust bearing 20 is fitted concentrically into the bearing housing 19. A sliding shaft 21 is fitted inside the thrust bearing 20, and a disc-shaped stopper 22 is fixed to the upper end of the thrust bearing 20 to prevent the sliding shaft 21 from coming off from the thrust bearing 20. The lower end of the sliding shaft 21 has a flange 21a with a slightly larger diameter, and a coil spring is attached between the flange 21a and the bearing housing 19 and surrounded by the sliding shaft 21 in order to bias the sliding shaft 21 downward. 2
8 has been inserted. A rectangular spring receiving plate 23 is fixed to the lower end of the flange 21a, and a holder support member 24 having a gate shape in front view is fixed to the lower surface of the spring receiving plate 23. Support member 24
Bearings 25, 25 are fitted into both side walls, respectively, with the axial direction being the left and right direction. Support member 24
In between, the length in the left-right direction is slightly shorter and the length in the front-rear direction is longer than that of the support member 24. A holder cover 26 in the shape of a rectangular parallelepiped with an open bottom is loosely fitted, and shaft portions 26a, 26a provided at the center portions of the left and right side walls of the holder cover 26 are fitted into the inner rings of the bearings 25, 25. As a result, the holder cover 26 is attached to the bearings 25, 25.
It can freely rotate around its axis. Springs 27, 27 are engaged at predetermined positions between the spring receiving plate 23 and the holder cover 26 to urge the holder cover 26 downward. The springs 27, 27 and the coil spring 28 are bent into the steel pipe 11,
Bearing 2 of detection part A when there is deformation etc.
This is to absorb vibrations around the axes 5 and 25 and in the vertical direction, thereby improving the ability of the detection section A to follow the steel pipe 11.
ホルダカバー26の下縁には平面視寸法がホル
ダカバー26と同様の検出器ホルダ29が着脱自
在に取付けられている。検出器ホルダ29の左右
対称の位置には前後方向に長い側面視額縁状のコ
イルボビン30a,30aを配設してある。コイ
ルボビン30a,30aはその軸心方向が左右方
向となる様にしてあり、その周縁の溝に励磁コイ
ル31a,31bを巻回してある。励磁コイル3
1a,31bの前後方向長さは次に述べる磁場検
出器32,32……の個数又は鋼管11の送り速
度により定まる探傷域を考慮して適宜の長さに選
定されている。 A detector holder 29, which has the same dimensions as the holder cover 26 in plan view, is detachably attached to the lower edge of the holder cover 26. Coil bobbins 30a, 30a, which have a frame-like shape when viewed from the side and are long in the front-rear direction, are arranged at symmetrical positions on the detector holder 29. The coil bobbins 30a, 30a have their axes oriented in the left-right direction, and excitation coils 31a, 31b are wound in grooves on their peripheries. Excitation coil 3
The longitudinal lengths of 1a and 31b are selected to be appropriate lengths in consideration of the flaw detection area determined by the number of magnetic field detectors 32, 32... or the feed speed of the steel pipe 11, which will be described below.
励磁コイル31a,31b間中央には8個(図
面では4個のみ現われている)の磁場検出器3
2,32……をコイル31a,31bの前後方向
長さに応じて一連配置してあり、探傷域の拡大を
図つている。磁場検出器32,32……は検出素
子として感磁ダイオードを用いており、励磁コイ
ル31a,31bにより鋼管11の表面に周期的
に形成される既述した如き同方向磁場及び異方向
磁場の磁束変化を検出し、各磁場検出器32,3
2……に接続されたコネクタ33,33……を介
して所定の電気信号を後述する信号処理回路B
(第10図参照)に入力する。検出器ホルダ29
の下面には正面視で上部が開口されたコの字状の
ガイドシユー34が取付けられている。ガイドシ
ユー34は耐摩耗性に富む材料、例えばセラミツ
クスからなるものであつて検出器ホルダ29の摩
耗を防止するためのものである。 Eight (only four are shown in the drawing) magnetic field detectors 3 are located in the center between the excitation coils 31a and 31b.
2, 32, . . . are arranged in series according to the lengths of the coils 31a, 31b in the longitudinal direction, thereby expanding the flaw detection area. The magnetic field detectors 32, 32, . Each magnetic field detector 32, 3
Signal processing circuit B, which will be described later, outputs predetermined electrical signals via connectors 33, 33... connected to 2...
(See Figure 10). Detector holder 29
A U-shaped guide shoe 34 whose top is open when viewed from the front is attached to the lower surface of the guide shoe 34 . The guide shoe 34 is made of a highly wear-resistant material, such as ceramics, and is used to prevent the detector holder 29 from being worn.
次に信号処理回路Bについて第10図に基づき
説明する。第10図は信号処理回路Bのブロツク
図ある。コイル31aには第1発振器41aから
第11図aに示す如き周波数2.5kHzの高周波電流
が通電され、また、コイル31bには第2発振器
41bから第1発振器41a出力よりも90゜進ん
だ、第11図bに示す如き周波数2.5kHzの高周波
数電流が通電される。このような位相調節のため
に第1発振器41a出力が移相器42を介して第
2発振器41bに与えられるべくなしてある。 Next, the signal processing circuit B will be explained based on FIG. FIG. 10 is a block diagram of the signal processing circuit B. A high frequency current of 2.5 kHz as shown in FIG. 11a is applied to the coil 31a from the first oscillator 41a, and a high frequency current of 2.5 kHz as shown in FIG. A high frequency current with a frequency of 2.5 kHz as shown in FIG. 11b is applied. For such phase adjustment, the output of the first oscillator 41a is provided to the second oscillator 41b via the phase shifter 42.
磁場検出器32はこれらの磁場の磁束変化を検
出し、この磁束変化に応じた信号を同期検波回路
43a及び43b夫々に出力する。 The magnetic field detector 32 detects changes in the magnetic flux of these magnetic fields, and outputs signals corresponding to the changes in the magnetic flux to the synchronous detection circuits 43a and 43b, respectively.
第1発振器41a出力及び第2発振器41b出
力は移相器46a,46bを介して同期検波回路
43a,43bの夫々に与えられるようにしてあ
り、移相器46aは第11図cに示すように位相
45゜で同期検波を行わせるべく、また移相器46
bは第11図dに示すように移相135゜で同期検波
を行わせるべく調節される。同期検波回路43a
は磁場検出器32からの入力信号を同期検波し、
同方向磁場の磁束変化を検出する。この検波結果
は第12図aに示す様な極大値及び極小値を有す
る磁気探傷型の信号波形として得られる。この検
波結果はレコーダ44aにて記録され、また、比
較器45aに入力される。比較器45aには第1
2図aに二点鎖線で示す如く割れ疵Cの有害、無
害の判断基準となる閾値が設定されており、同期
検波回路43aからの入力信号の極大値が該閾値
よりも大なる場合は有害疵検出信号として図示し
ないマーキング装置に入力させる。これにより鋼
管11にはマーキングが施される。 The output of the first oscillator 41a and the output of the second oscillator 41b are provided to the synchronous detection circuits 43a and 43b via phase shifters 46a and 46b, respectively, and the phase shifter 46a is configured as shown in FIG. phase
In order to perform synchronous detection at 45°, a phase shifter 46 is also used.
b is adjusted to perform synchronous detection with a phase shift of 135° as shown in FIG. 11d. Synchronous detection circuit 43a
synchronously detects the input signal from the magnetic field detector 32,
Detects magnetic flux changes in the same direction magnetic field. The detection result is obtained as a magnetic flaw detection type signal waveform having maximum and minimum values as shown in FIG. 12a. This detection result is recorded by the recorder 44a and is also input to the comparator 45a. The comparator 45a has a first
As shown by the two-dot chain line in Figure 2a, a threshold value is set as a criterion for determining whether the crack C is harmful or harmless, and if the maximum value of the input signal from the synchronous detection circuit 43a is larger than the threshold value, it is harmful. The signal is input to a marking device (not shown) as a flaw detection signal. As a result, the steel pipe 11 is marked.
同期検波回路43bは磁場検出器32からの入
力信号を同期検波し、異方向磁場の磁束変化を検
出する。この検波結果は第12図bに示す様な極
小値のみを有する信号波形として得られる。この
検波結果はレコーダ44bにて記録され、また、
比較器45bに入力される。比較器45bには第
12図bに二点鎖線で示す如きピツト疵Pの有
害、無害の判断基準となる閾値が設定されてお
り、同期検波43bからの入力信号の極小値が該
閾値よりも小なる場合は有害疵検出信号をマーキ
ング装置に入力させる。これにより鋼管11には
マーキングが施される。 The synchronous detection circuit 43b synchronously detects the input signal from the magnetic field detector 32 and detects changes in magnetic flux of magnetic fields in different directions. The detection result is obtained as a signal waveform having only minimum values as shown in FIG. 12b. This detection result is recorded by the recorder 44b, and
The signal is input to the comparator 45b. A threshold value is set in the comparator 45b as a criterion for determining whether the pit flaw P is harmful or harmless, as shown by the two-dot chain line in FIG. If it is smaller, a harmful flaw detection signal is input to the marking device. As a result, the steel pipe 11 is marked.
なお、以上の如き信号処理回路Bのうち同期検
波回路43a,43bは各磁場検出器ごとに1組
設けるか又は多数の磁場検出器から1組の同期検
波回路43a,43bに順次切換えて与えるかの
構成をとるのがよい。 In addition, among the signal processing circuits B as described above, one set of synchronous detection circuits 43a and 43b may be provided for each magnetic field detector, or one set of synchronous detection circuits 43a and 43b may be sequentially switched from a large number of magnetic field detectors. It is better to have the following structure.
また上述の実施例では励磁コイル31a,31
bをその軸心が鋼管11の表面と平行になる様に
配したが、第13図に示す様に、軸心が鋼管11
の表面に直交する様に配することとしてもよい。 Furthermore, in the above embodiment, the excitation coils 31a, 31
b was arranged so that its axis was parallel to the surface of the steel pipe 11, but as shown in FIG.
It may be arranged perpendicularly to the surface of.
この場合も両励磁電流の波形の極性が一致する
期間では鋼管11の表面における両電流による磁
場の方向は同一になり、従つて鋼管11の表層部
には第13図aに示す如く同方向磁場が形成さ
れ、また、両電流の波形の極性が逆になる期間で
は鋼管11の表面における両電流による磁場の方
向は逆になり、従つて両コイル31a,31b間
には第13図bに示す如く異方向磁場が形成され
ることになる。従つてこの構成による場合も両コ
イル31a,31b間に配した磁場検出器32に
より同方向磁場及び異方向磁場の磁束変化を検出
することにより同様に割れ疵C、ピツト疵Pの検
出が可能になる。 In this case as well, during the period in which the polarities of the waveforms of both excitation currents match, the directions of the magnetic fields due to both currents on the surface of the steel pipe 11 are the same, and therefore the surface layer of the steel pipe 11 has magnetic fields in the same direction as shown in FIG. 13a. is formed and the polarities of the waveforms of both currents are reversed, the direction of the magnetic field due to both currents on the surface of the steel pipe 11 is reversed, and therefore there is a gap between both coils 31a and 31b as shown in FIG. 13b. As a result, magnetic fields in different directions are formed. Therefore, even with this configuration, cracks C and pit defects P can be similarly detected by detecting changes in the magnetic flux of the magnetic field in the same direction and the magnetic field in the different direction using the magnetic field detector 32 disposed between both coils 31a and 31b. Become.
次に本発明の効果を実施例に基づき明らかにす
る。第14図は割れ疵C、ピツト疵Pに相応する
人工欠陥を本発明により検出した場合の検出結果
を示すグラフである。第14図aは割れ疵Cに相
応する人工欠陥を検出した場合の磁場検出器の同
方向磁場、異方向磁場における磁束変化の検出に
係る出力レベルを縦軸に、また、割れ疵Cの深さ
を横軸にとつて示すグラフである。グラフから明
らかな様に割れ疵Cにあつては、磁場検出器の出
力レベルは同方向磁場の検出レベルが異方向磁場
のそれよりも十分大きく現れるので両者の弁別が
明瞭に行なえる。
Next, the effects of the present invention will be explained based on examples. FIG. 14 is a graph showing the detection results when artificial defects corresponding to cracks C and pit defects P are detected by the present invention. Figure 14a shows the output level of the magnetic field detector for detecting changes in magnetic flux in the same direction magnetic field and the different direction magnetic field when an artificial defect corresponding to crack C is detected, and the depth of crack C is plotted on the vertical axis. This is a graph showing the horizontal axis. As is clear from the graph, in the case of crack C, the output level of the magnetic field detector for the magnetic field in the same direction appears to be sufficiently higher than that for the magnetic field in the different direction, so that the two can be clearly distinguished.
第14図bはピツト疵Pに相応する人工欠陥を
検出した場合の磁場検出器の同方向磁場、異方向
磁場における磁束変化の検出に係る出力レベルを
縦軸に、また、ピツト疵Pの深さを横軸にとつて
示すグラフである。グラフから明らかなようにピ
ツト疵Pにあつては、異方向磁場の検出レベルが
同方向磁場のそれよりも十分大きく現れるので両
者の弁別が明瞭に行なえる。 Fig. 14b shows the output level of the magnetic field detector for detecting changes in magnetic flux in the same direction magnetic field and the different direction magnetic field when an artificial defect corresponding to the pit flaw P is detected, and the depth of the pit flaw P is plotted on the vertical axis. This is a graph showing the horizontal axis. As is clear from the graph, in the case of pit flaws P, the detection level of the magnetic field in the different direction appears sufficiently higher than that of the magnetic field in the same direction, so that the two can be clearly distinguished.
第15図は本発明により深さの異なる割れ疵、
ピツト疵を探傷した結果を示すチヤートである。
第15図aは同方向磁場、bは異方向磁場の磁束
変化を示すものであり、縦軸は夫々の検出レベル
を示している。グラフから明らかな様に両者の弁
別が可能である。また、疵深さと検出レベルが比
例関係にあるので疵深さが定量的に求まる。 FIG. 15 shows cracks with different depths according to the present invention.
This is a chart showing the results of pit flaw detection.
FIG. 15a shows the magnetic flux change of the same direction magnetic field, and b shows the magnetic flux change of the different direction magnetic field, and the vertical axis shows the detection level of each. As is clear from the graph, it is possible to distinguish between the two. Furthermore, since the flaw depth and the detection level are in a proportional relationship, the flaw depth can be determined quantitatively.
なお、上述の実施例では本発明を鋼管に適用す
る場合について述べたが、スラブ等の鋼材につい
ても適用でき、更には鋼材以外の他の金属材につ
いても適用できることは勿論である。 In addition, although the above-mentioned embodiment described the case where the present invention is applied to a steel pipe, it goes without saying that it can also be applied to steel materials such as slabs, and furthermore, it can be applied to other metal materials other than steel materials.
以上詳述した如く本発明による場合は、被検査
材の表面に同方向磁場及び異方向磁場を周期的に
形成せしめ、疵が存する場合の同方向磁場及び異
方向磁場の磁束の変化を磁場検出器にて検出する
ものであるので、疵の性状に関係なく、即ち割れ
疵、ピツト疵等の疵の種類に関係なく正確な検出
が行え、従来方法の如く疵の種類に応じて複数の
探傷法を適用する必要がなく、設備コスト、検査
コストの低減が図れる。更には検出部を小型軽量
化できるので被検査材表面への追随性の向上が図
れ、精度の良い検出が可能となる等、本発明は優
れた効果を奏する。 As detailed above, according to the present invention, a magnetic field in the same direction and a magnetic field in different directions are periodically formed on the surface of the material to be inspected, and changes in the magnetic flux of the magnetic fields in the same direction and the different direction when a flaw exists are detected by magnetic field detection. Since the method uses a device to detect flaws, accurate detection can be performed regardless of the nature of the flaw, i.e. regardless of the type of flaw, such as cracks or pit flaws. There is no need to apply the law, and equipment costs and inspection costs can be reduced. Furthermore, since the detection unit can be made smaller and lighter, the ability to follow the surface of the material to be inspected can be improved, and highly accurate detection becomes possible, and the present invention has excellent effects.
第1,2図は従来方法の実施状態を示す模式
図、第3〜5図は本発明の原理説明図、第6図は
本発明装置の検出部周りの構造を示す模式的正面
図、第7図はその左側面図、第8図は検出器ホル
ダ周りを拡大して示す正面断面図、第9図はその
左側半断面図、第10図は信号処理回路のブロツ
ク図、第11図はその動作説明のための信号波形
図、第12図は同期検波回路の検出結果を示すグ
ラフ、第13図は本発明の他の実施例を示す模式
図、第14図は本発明により割れ疵、ピツト疵に
相応する人工欠陥を検出した場合の結果を示すグ
ラフ、第15図は本発明により深さの異なる割れ
疵、ピツト疵を探傷した結果を示すチヤートであ
る。
11……鋼管、31a,31b……励磁コイ
ル、32,32……磁場検出器、41a……第1
発振器、41b……第2発振器、42,46a,
46b……移相器、43a,43b……同期検波
回路、A……検出部、B……信号処理回路。
Figures 1 and 2 are schematic diagrams showing the implementation state of the conventional method, Figures 3 to 5 are explanatory diagrams of the principle of the present invention, Figure 6 is a schematic front view showing the structure around the detection section of the device of the present invention, Fig. 7 is a left side view, Fig. 8 is a front sectional view showing an enlarged view of the detector holder, Fig. 9 is a left half sectional view thereof, Fig. 10 is a block diagram of the signal processing circuit, and Fig. 11 is a front sectional view showing the area around the detector holder. FIG. 12 is a graph showing the detection results of the synchronous detection circuit, FIG. 13 is a schematic diagram showing another embodiment of the present invention, and FIG. 14 is a signal waveform diagram for explaining the operation. FIG. 15 is a graph showing the results of detecting artificial defects corresponding to pit flaws, and FIG. 15 is a chart showing the results of detecting cracks and pit flaws of different depths according to the present invention. 11... Steel pipe, 31a, 31b... Excitation coil, 32, 32... Magnetic field detector, 41a... First
Oscillator, 41b...Second oscillator, 42, 46a,
46b...phase shifter, 43a, 43b...synchronous detection circuit, A...detection section, B...signal processing circuit.
Claims (1)
にあるように並設した2つのコイルに同周波数の
位相の異なる励磁電流を通電し、前記被検査材の
表面の両コイルと対向する部分に、これに沿う向
きとなる磁場及びこれに直交する向きとなる磁場
を夫々周期的に形成せしめ、この部分に臨ませた
磁場検出器にて各磁場形成時の磁束変化を検出す
ることを特徴とする探傷方法。 2 夫々の軸心が被検査材の表面に直交するよう
に並設した2つのコイルに同周波数の位相の異な
る励磁電流を通電し、前記被検査材の表面の両コ
イルと対向する部分に、これに沿う向きとなる磁
場及びこれに直交する向きとなる磁場を夫々周期
的に形成せしめ、この部分に臨ませた磁場検出器
にて各磁場形成時の磁束変化を検出することを特
徴とする探傷方法。[Scope of Claims] 1. Exciting currents of the same frequency and different phases are applied to two coils arranged in parallel so that their respective axes are on the same line along the surface of the material to be inspected, and the surface of the material to be inspected is A magnetic field oriented along the coils and a magnetic field perpendicular to the coils are periodically formed in the part facing both coils, and a magnetic field detector placed facing this part detects the magnetic flux when each magnetic field is formed. A flaw detection method characterized by detecting changes. 2. Applying excitation currents of the same frequency and different phases to two coils arranged in parallel so that their respective axes are perpendicular to the surface of the material to be inspected, and applying current to a portion of the surface of the material to be inspected that faces both coils, A magnetic field oriented along this direction and a magnetic field oriented perpendicular to this are formed periodically, and a magnetic field detector placed facing this part detects changes in magnetic flux when each magnetic field is formed. Flaw detection method.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP4891884A JPH0249661B2 (en) | 1984-03-13 | 1984-03-13 | TANSHOHOHO |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP4891884A JPH0249661B2 (en) | 1984-03-13 | 1984-03-13 | TANSHOHOHO |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| JPS60192252A JPS60192252A (en) | 1985-09-30 |
| JPH0249661B2 true JPH0249661B2 (en) | 1990-10-30 |
Family
ID=12816625
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| JP4891884A Expired - Lifetime JPH0249661B2 (en) | 1984-03-13 | 1984-03-13 | TANSHOHOHO |
Country Status (1)
| Country | Link |
|---|---|
| JP (1) | JPH0249661B2 (en) |
Families Citing this family (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP2666301B2 (en) * | 1987-11-04 | 1997-10-22 | 日本鋼管株式会社 | Magnetic flaw detection |
-
1984
- 1984-03-13 JP JP4891884A patent/JPH0249661B2/en not_active Expired - Lifetime
Also Published As
| Publication number | Publication date |
|---|---|
| JPS60192252A (en) | 1985-09-30 |
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