JPH08145965A - Ultrasonic cured layer measuring apparatus by electronic scanning - Google Patents
Ultrasonic cured layer measuring apparatus by electronic scanningInfo
- Publication number
- JPH08145965A JPH08145965A JP6289452A JP28945294A JPH08145965A JP H08145965 A JPH08145965 A JP H08145965A JP 6289452 A JP6289452 A JP 6289452A JP 28945294 A JP28945294 A JP 28945294A JP H08145965 A JPH08145965 A JP H08145965A
- Authority
- JP
- Japan
- Prior art keywords
- layer
- ultrasonic
- receiver
- transmitter
- wave
- 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.)
- Pending
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Landscapes
- Investigating Or Analyzing Materials By The Use Of Ultrasonic Waves (AREA)
Abstract
Description
【0001】[0001]
【産業上の利用分野】本発明は、被検体の硬さとその内
質的分布状況を超音波により測定する超音波硬化層測定
方法及びその装置に係る。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultrasonic hardening layer measuring method and apparatus for ultrasonically measuring the hardness of a sample and its internal distribution.
【0002】特に超音波の送波子と受波子に関する。In particular, it relates to an ultrasonic wave transmitter and receiver.
【0003】[0003]
【従来の技術】圧延用鍛鋼ロール等においては、表層部
における焼入れ硬化層の状態がロールの寿命を左右する
重要な条件となっており、この硬化層を非破壊的に測定
することがロールの品質保証上重要である。2. Description of the Related Art In forged steel rolls for rolling, the state of the quench-hardened layer in the surface layer is an important condition that influences the life of the roll, and it is important to measure this hardened layer nondestructively. It is important for quality assurance.
【0004】従来の硬化層測定装置は、いずれも被検体
の表面のみまたは表層部の比較的浅い位置(表面から1
0〜20mm程度)の硬化層しか測定できない。In all of the conventional hardened layer measuring devices, only the surface of the subject or a relatively shallow position of the surface layer portion (1 from the surface) is used.
Only a hardened layer of 0 to 20 mm) can be measured.
【0005】特許No.特公昭63−26340 号「非破壊式硬
化層測定方法及び装置」によれば、精度よく硬化層分布
を測定できるが測定精度は、送波子及び受波子の設置精
度に大きく影響されており、精度良く設置するのに時間
を要した。また、送波子と受波子の円柱被検体の円周上
での位置を半機械的に移動させるため、測定間隔をあま
り小さくできない。さらに精度よく測定するためには、
送波子と受波子の位置決め精度を高める必要がある。硬
化層分布の測定精度は、被検体への送波子及び受波子の
設置精度に大きく左右され、送波子及び受波子を精度良
く設置するために時間がかかっていた。また、送波子及
び受波子の被検体の円周上での設置位置を機械的に移動
させるため、移動距離に関して最小限度があった。さら
に測定精度を向上させるためには、移動距離、すなわち
測定間隔を小さくする事が望まれていた。According to the patent No. JP-B-63-26340 "Non-destructive method and apparatus for measuring hardened layer", the hardened layer distribution can be accurately measured, but the measurement accuracy is largely dependent on the installation accuracy of the wave transmitter and the wave receiver. It was affected, and it took time to install it accurately. Further, the positions of the transmitter and the receiver on the circumference of the cylindrical object are moved semi-mechanically, so the measurement interval cannot be made very small. To measure more accurately,
It is necessary to improve the positioning accuracy of the transmitter and receiver. The measurement accuracy of the distribution of the hardened layer largely depends on the installation accuracy of the wave transmitter and the wave receiver on the subject, and it took time to accurately install the wave transmitter and the wave receiver. Further, since the installation positions of the wave transmitter and the wave receiver on the circumference of the subject are mechanically moved, there is a minimum limit on the moving distance. In order to further improve the measurement accuracy, it has been desired to reduce the moving distance, that is, the measurement interval.
【0006】[0006]
【発明が解決しようとする課題】本発明の目的は、上記
の欠点を除去し、被検体の表面から内に至る比較的深い
範囲の硬化層を超音波を利用して非破壊的に精度良く短
時間で測定する方法及び装置を提供することにある。SUMMARY OF THE INVENTION The object of the present invention is to eliminate the above-mentioned drawbacks and to accurately and nondestructively cure a hardened layer in a relatively deep range from the surface of a subject to the inside thereof by using ultrasonic waves. It is to provide a method and an apparatus for measuring in a short time.
【0007】[0007]
【課題を解決するための手段】被検体内に透入可能な超
音波を用いて、硬さの異なる各種の鍛鋼ロール片を試験
片として超音波特性を調べた結果、硬さHs(ショア硬
さ)と超音波の伝播速度との間には図1に示すように良
好な対応関係があることが認められた。[Means for Solving the Problems] As a result of investigating ultrasonic characteristics using various forged steel roll pieces having different hardness as test pieces by using ultrasonic waves penetrating into a subject, hardness Hs (Shore hardness It has been confirmed that there is a good correspondence between the ultrasonic wave velocity and the ultrasonic wave propagation velocity as shown in FIG.
【0008】上述の関係に着目し、被検体中の超音波伝
播速度を求め、その速度の大きさから被検体の硬さを測
定する。Focusing on the above relationship, the ultrasonic wave propagation velocity in the subject is determined, and the hardness of the subject is measured from the magnitude of the velocity.
【0009】ところで実体ロールのように円柱面を有す
る被検体においては、図2に示すように硬化層(斜線部
分)は被検体1の軸心Oに対してほぼ対称に分布してお
り、表面近傍では最も硬く内層になるにしたがって硬さ
が低くくなっている。By the way, in a subject having a cylindrical surface such as a body roll, the hardened layer (hatched portion) is distributed substantially symmetrically with respect to the axis O of the subject 1 as shown in FIG. In the vicinity, the hardness is the highest and the hardness decreases as the inner layer is formed.
【0010】一方、ロールは軸方向にかなりの長さを有
する他、胴中央部と胴端面での硬化層深さは異なってい
ることが多く、軸方向における両端面間から被検体内部
の伝播速度を求めることは困難である。したがって、こ
のような円柱形状の多層被検体の場合には、軸心に対称
な任意間隔の多重層を仮想して送波子から送出される超
音波ビームが被検体の所望する深さの位置を経て受波子
に受波されるようにするため、送波子及び受波子の間隔
を電子走査により可変可能にして、被検体円周上の2点
間に配置し、所望の深さでの弦方向の超音波伝播速度を
求める。On the other hand, the roll has a considerable length in the axial direction, and the depth of the hardened layer is often different between the center part of the body and the end face of the body. It is difficult to find the speed. Therefore, in the case of such a cylindrical multi-layered object, the ultrasonic beam emitted from the transmitter hypothesizes multiple layers that are symmetrical with respect to the axis and that are spaced at arbitrary intervals, so that the position of the desired depth of the object is detected. In order to allow the wave to be received by the wave receiver, the distance between the wave transmitter and the wave receiver can be changed by electronic scanning, and the wave is placed between two points on the circumference of the object to be measured in the chord direction at the desired depth. Determine the ultrasonic wave propagation velocity of.
【0011】すなわち、上記目的を達成するために、送
波子及び受波子の少なくとも一方に電子走査アレイ型探
触子を用い、第1層から第n層までの測定に関して、そ
の都度送波子と受波子を配置せずにすむ様にする。That is, in order to achieve the above-mentioned object, an electronic scanning array type probe is used for at least one of the transmitter and the receiver, and the transmitter and the receiver are used for each measurement from the first layer to the n-th layer. Try not to place Hamiko.
【0012】[0012]
【作用】実体ロールの硬化層測定において、表面の最も
浅い位置にある第1層から順次第2層,第3層,…第n
層に相当する深さの弦方向の径路長を伝播する超音波伝
播速度は、径路長の最大深さが、それぞれ伝播速度を求
める層にあるように、送波子と受波子の位置を設定し
て、この時の伝播時間を幾何学的に求められる各層での
径路長、並びに既に求めた第1層から前層までの伝播速
度により求めることができる。In the measurement of the hardened layer of the body roll, the first layer at the shallowest position on the surface, the second layer, the third layer, ...
The ultrasonic wave propagation velocity that propagates along the chordal path length of the depth corresponding to the layer is set by setting the positions of the transmitter and the receiver so that the maximum depth of the path length is in the layer where the propagation velocity is obtained. Then, the propagation time at this time can be obtained by the geometrically obtained path length in each layer and the already-obtained propagation velocity from the first layer to the previous layer.
【0013】この際、送波子と受波子は、(1)送波
子:電子走査アレイ型探触子,受波子:一点入射型探触
子、(2)送波子:一点入射型探触子,受波子:電子走
査アレイ型探触子、(3)送波子,受波子共に電子走査
アレイ型探触子の3通りの組み合わせがあり、このいず
れかを使用する。At this time, the transmitter and the receiver are (1) a transmitter: an electronic scanning array type probe, a receiver: a single point incident type probe, (2) a transmitter: a single point incident type probe, Receiving device: There are three combinations of electronic scanning array type probe, (3) electronic scanning array type probe for both transmitter and receiving device, and any one of them is used.
【0014】このため、送波子と受波子の位置設定を1
回行うだけで前記第1層から順次第2層,第3層,…第
n層に相当する深さの弦方向の径路長を伝播する超音波
伝播速度を求めることができ、設置時間短縮が可能とな
る。また、前記送波子及び受波子の組み合わせにより、
測定間隔を小さくでき、測定精度向上が可能となる。Therefore, the positions of the transmitter and the receiver are set to 1
The ultrasonic wave propagation velocity for propagating along the chordal path length of the depth corresponding to the second layer, the third layer, ... It will be possible. Also, by the combination of the transmitter and the receiver,
The measurement interval can be reduced, and the measurement accuracy can be improved.
【0015】[0015]
(実施例1)本発明の実施例について説明する。図3は
被検体1の一方の表面に超音波ビームの集束点を有する
凹面振動子が組込まれた集束型受波子3と、他方には電
子走査アレイ型送波子2を用いている点を特徴としてい
る。Example 1 An example of the present invention will be described. FIG. 3 is characterized in that a focusing type transducer 3 in which a concave transducer having a focusing point of an ultrasonic beam is incorporated on one surface of a subject 1 and an electronic scanning array type transmitting element 2 is used on the other side. I am trying.
【0016】本方法によれば、送波子を電子走査式送波
子にすることにより、集束型の送波子と同等に超音波を
電子的に集束することが可能であり、かつ、電子走査式
送波子を被検体1の受波子から順に円周上へ複数個使用
することで電子的に入射点を直線的に移動させることが
可能となった。また、測定間隔を1mm、すなわち弦長測
定ピッチを1mmとし、精度の良い硬化層測定結果が得ら
れる。このことにより、送波子と受波子を測定毎に設置
することなく、1回の位置設定で表層部から内部に至る
硬化層分布測定を短時間かつ、精度よく測定することが
可能となった。 (実施例2)また、上述の実施例1の逆に、送波子を集
束型,受波子を電子アレイ走査型に切り換えることによ
り超音波の入射方向を変化させても同様の効果が得られ
る。さらに、送波子及び受波子とも電子アレイ走査型に
することにより両方向からの硬化層測定が可能である。According to the present method, the ultrasonic wave can be electronically focused in the same manner as the focusing type transducer by using the electronic scanning type transducer as the transmitting element, and the electronic scanning type transmitting element can be used. By using a plurality of wave elements sequentially from the wave receiver of the subject 1 on the circumference, it becomes possible to electronically move the incident point linearly. In addition, the measurement interval is set to 1 mm, that is, the chord length measurement pitch is set to 1 mm, and an accurate hardened layer measurement result is obtained. As a result, the hardened layer distribution measurement from the surface layer portion to the inside can be accurately measured in a short time by setting the position once, without installing a wave transmitter and a wave receiver for each measurement. (Embodiment 2) On the contrary to Embodiment 1 described above, the same effect can be obtained by changing the incident direction of ultrasonic waves by switching the wave transmitter to the focusing type and the wave receiver to the electronic array scanning type. Furthermore, by making both the wave transmitter and the wave receiver an electronic array scanning type, it is possible to measure the hardened layer from both directions.
【0017】電子アレイ走査型探触子を送波子及び受波
子のいずれか一方、または、両方に用いることと電子ア
レイ走査型探触子を電子セクタ走査及び電子リニア走査
を併用することにより、1回の送波子及び受波子の設置
で被検体の表層部から内部に至る硬化層測定を短時間か
つ、精度よく測定することを可能にした。By using the electronic array scanning probe for either one or both of the transmitter and the receiver, and by using the electronic array scanning probe in combination with the electronic sector scanning and the electronic linear scanning, By installing the wave transmitter and wave receiver once, it is possible to measure the hardened layer from the surface layer to the inside of the object in a short time and with high accuracy.
【0018】[0018]
【発明の効果】本発明による送波子及び受波子を用いた
超音波硬化層測定方法及び装置は、被検体を全く損傷す
ることなく、被検体表層部から内部に至る広い範囲で硬
化層の深さを短時間かつ、精度よく測定することができ
る。The ultrasonic hardening layer measuring method and apparatus using the wave transmitter and the wave receiver according to the present invention has a large depth of the hardening layer from the surface layer to the inside of the object without damaging the object at all. Can be measured accurately in a short time.
【図1】ロール試験材の硬さ分布(Hs:ショア硬さ)
と超音波伝播速度の関係を実験的に求めた関係線図であ
る。FIG. 1 Hardness distribution of roll test material (Hs: Shore hardness)
It is a relationship diagram which experimentally calculated | required the relationship between and ultrasonic wave propagation velocity.
【図2】円柱面を有する被検体の硬化層の分布状況を示
す参考図である。FIG. 2 is a reference diagram showing a distribution state of a hardened layer of a subject having a cylindrical surface.
【図3】本発明による超音波硬化層測定方法を実施する
場合の参考図である。FIG. 3 is a reference diagram for carrying out the method for measuring an ultrasonically cured layer according to the present invention.
1…被検体、2…電子走査アレイ型送波子、3…集束型
受波子。DESCRIPTION OF SYMBOLS 1 ... Subject, 2 ... Electronic scanning array type | formula transmitter, 3 ... Focusing type | formula receiver.
フロントページの続き (72)発明者 木野 裕敏 東京都千代田区大手町二丁目6番2号 日 立建機株式会社内Front Page Continuation (72) Inventor Hirotoshi Kino 2-6-2 Otemachi, Chiyoda-ku, Tokyo Inside Nitto Construction Machinery Co., Ltd.
Claims (2)
柱状被検体の前記硬化層を軸心に対称な任意の間隔の多
重層と仮定して、まず前記被検体の最表層部にある第1
層のみを通過する超音波ビームの伝播時間と径路長から
第1層での超音波ビームの伝播速度を求め、次に、第1
層と第2層のみを通過する超音波ビームの伝播時間と第
1層及び第2層での径路長及び既に求めた第1層の伝播
速度とから第2層での伝播速度を求め、以下、同様な方
法で第n層に至るまでの伝播速度を求めて、最終的に
は、各層の伝播速度を基に予め求められている伝播速度
と硬度との相関性から各層における硬さを求める超音波
硬化層測定装置において、 円柱状被検体の外殻部の弦方向に通過する超音波ビーム
の伝播時間を求めるための送波子と受波子の組み合わせ
で、送波子に電子走査アレイ型探触子を用い、受波子
に一点入射型探触子を用いる場合、送波子に一点入射
型探触子を用い、受波子に電子走査アレイ型探触子を用
いる場合、送波子,受波子共に電子走査アレイ型探触
子を用いる場合のいずれかの組み合わせにより硬化層分
布を測定することを特徴とする電子走査による超音波硬
化層測定装置。1. A first outermost layer of the subject, assuming that the hardened layer of a cylindrical subject having a hardened layer formed on an outer shell portion having a circular cross section is a multilayer having an arbitrary interval symmetrical about an axis. Part 1
The propagation velocity of the ultrasonic beam in the first layer is obtained from the propagation time and the path length of the ultrasonic beam passing through only the layer, and then the first
The propagation velocity in the second layer is calculated from the propagation time of the ultrasonic beam passing through only the first layer and the second layer, the path lengths in the first layer and the second layer, and the propagation velocity of the first layer which has already been obtained. , The propagation velocity up to the n-th layer is obtained by the same method, and finally the hardness of each layer is obtained from the correlation between the propagation velocity and the hardness which is previously obtained based on the propagation velocity of each layer. In the ultrasonic hardening layer measuring device, an electronic scanning array type probe is used for the transmitter by combining the transmitter and receiver to determine the propagation time of the ultrasonic beam passing through the outer shell of the cylindrical object in the chord direction. When a single-incidence probe is used for the receiver and a single-incidence probe is used for the transmitter and an electronic scanning array type probe is used for the receiver, both the transmitter and the receiver are Hardened layer by any combination when using a scanning array type probe A device for measuring an ultrasonically cured layer by electronic scanning, which is characterized by measuring a cloth.
前記超音波送受信部からの送信パルスにより被検体内に
超音波ビームを送出する送波子と,前記被検体内を通過
してきた超音波ビームを受波子と,超音波ビームが前記
被検体内の所望の深さの層を通って受波されるように前
記送波子及び受波子の設定保持を行う設定保持具と,超
音波ビームが前記被検体内に送出されてから前記受波子
に受波される迄の伝播時間を測定する伝播時間測定部
と,前記送波子及び前記受波子の相対的な位置関係を基
にして被検体内に入射した超音波ビームが前記受波子に
到達するまでの径路長を演算する径路長演算部と,前記
伝播時間測定部の出力と前記径路長演算部の出力並びに
既に求めた各層の伝播速度を基にして測定中の層におけ
る伝播速度を演算する伝播速度演算部と,前記伝播速度
演算された各層の伝播速度を記憶し、かつ必要に応じて
読み出すことのできるメモリ部と,伝播速度を硬さに換
算して出力表示を行う硬さ演算部を具備した超音波硬化
層測定装置において、第1項記載の送波子及び受波子を
用いることを特徴とした電子走査による超音波硬化層測
定装置。2. An ultrasonic wave transmitting / receiving unit for transmitting / receiving ultrasonic waves,
A transmitter for transmitting an ultrasonic beam into the subject by a transmission pulse from the ultrasonic transmitter / receiver, a receiver for receiving the ultrasonic beam that has passed through the subject, and a desired ultrasonic beam in the subject. And a setting holder for setting and holding the wave transmitter and the wave receiver so that the wave is received through a layer having a depth of, and an ultrasonic beam is sent to the inside of the subject and then received by the wave receiver. The propagation time measuring unit for measuring the propagation time until the end of the ultrasonic wave, and the path through which the ultrasonic beam entering the subject reaches the receiver based on the relative positional relationship between the transmitter and the receiver. A path length calculation unit for calculating the length, a propagation velocity calculation for calculating the propagation velocity in the layer under measurement based on the output of the propagation time measurement unit and the output of the path length calculation unit, and the propagation velocity of each layer already obtained. And the transmission of each layer for which the propagation velocity is calculated. Item 1. In an ultrasonic hardening layer measuring device, comprising: a memory unit capable of storing a velocity and reading it out as necessary, and a hardness calculation unit for converting a propagation velocity into hardness and displaying an output, An ultrasonic hardening layer measuring device by electronic scanning characterized by using the above-mentioned wave transmitter and wave receiver.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP6289452A JPH08145965A (en) | 1994-11-24 | 1994-11-24 | Ultrasonic cured layer measuring apparatus by electronic scanning |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP6289452A JPH08145965A (en) | 1994-11-24 | 1994-11-24 | Ultrasonic cured layer measuring apparatus by electronic scanning |
Publications (1)
Publication Number | Publication Date |
---|---|
JPH08145965A true JPH08145965A (en) | 1996-06-07 |
Family
ID=17743453
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP6289452A Pending JPH08145965A (en) | 1994-11-24 | 1994-11-24 | Ultrasonic cured layer measuring apparatus by electronic scanning |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPH08145965A (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6031173A (en) * | 1997-09-30 | 2000-02-29 | Kawai Musical Inst. Mfg. Co., Ltd. | Apparatus for generating musical tones using impulse response signals |
CN113390970A (en) * | 2021-06-07 | 2021-09-14 | 中南大学 | Ultrasonic sound velocity detection method and system for detecting concrete performance |
-
1994
- 1994-11-24 JP JP6289452A patent/JPH08145965A/en active Pending
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6031173A (en) * | 1997-09-30 | 2000-02-29 | Kawai Musical Inst. Mfg. Co., Ltd. | Apparatus for generating musical tones using impulse response signals |
CN113390970A (en) * | 2021-06-07 | 2021-09-14 | 中南大学 | Ultrasonic sound velocity detection method and system for detecting concrete performance |
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