JP5178594B2 - Acoustic sensor device - Google Patents

Acoustic sensor device Download PDF

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JP5178594B2
JP5178594B2 JP2009063546A JP2009063546A JP5178594B2 JP 5178594 B2 JP5178594 B2 JP 5178594B2 JP 2009063546 A JP2009063546 A JP 2009063546A JP 2009063546 A JP2009063546 A JP 2009063546A JP 5178594 B2 JP5178594 B2 JP 5178594B2
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acoustic sensor
sensor device
connector
elastic member
side cap
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JP2010216966A (en
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恒実 村山
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Nippon Steel Corp
Posco Co Ltd
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Posco Co Ltd
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本発明は、回転数が10rpm以下の極低速回転機械の軸受の音響診断に使用する音響センサに関する。   The present invention relates to an acoustic sensor used for acoustic diagnosis of a bearing of a very low speed rotating machine having a rotation speed of 10 rpm or less.

従来、回転機械の軸受の異常診断には軸受の振動を検出して得られる信号により判定する振動診断が用いられている。振動診断は、回転数に比例して発生する衝撃振動を測定するものである。しかし、100rpm以下の低速回転機械を診断する場合、軸受の異常に伴って発生する振動は小さく、衝撃振動の発生間隔も長くなるので、異常の診断は難しい。特に連続鋳造機のロールのように数rpmの極低速回転機械に振動診断を行うと、軸受の異常に伴う信号とノイズの識別が難しく精度の高い診断は困難であった。   Conventionally, vibration diagnosis that is determined by a signal obtained by detecting vibration of a bearing is used for abnormality diagnosis of a bearing of a rotary machine. The vibration diagnosis is to measure impact vibration generated in proportion to the rotation speed. However, when diagnosing a low-speed rotating machine of 100 rpm or less, the vibration generated due to the abnormality of the bearing is small, and the occurrence interval of the impact vibration becomes long, so it is difficult to diagnose the abnormality. In particular, when vibration diagnosis is performed on an extremely low speed rotating machine of several rpm such as a roll of a continuous casting machine, it is difficult to distinguish a signal and noise associated with a bearing abnormality and to make a highly accurate diagnosis.

最近、下記特許文献1に記載のように、軸受の転走面にクラックが発生しているものの、転動体は健全に回転している状態の極低速回転軸受の異常検知のために、衝撃振動を用いる診断に代えて音響信号を用いる異常診断である音響診断が提案されている。   Recently, as described in the following Patent Document 1, although a crack has occurred on the rolling surface of the bearing, the impact vibration is detected for detecting an abnormality in the extremely low speed rotating bearing in a state where the rolling element is rotating smoothly. An acoustic diagnosis, which is an abnormality diagnosis using an acoustic signal instead of a diagnosis using an acoustic signal, has been proposed.

図5は、特許文献1の図5として開示されている図である。図5は、マイクロホンと振動センサをマグネットで加振機に取り付けて、加振機をランダムノイズ加振させたときの応答を計測した周波数特性を示している。このグラフによれば、振動センサが約8kHz以上の高周波振動に対して相対的に感度が高いのに対して、マイクロホンは5kHz以下の周波数帯の振動に対して相対的に感度が高いことを示している。したがって、特許文献1に記載のように、極低速回転機械に多い大径の軸受では固有振動数から5kHzの周波数音が大きくなるためマイクロホンを用いた音響診断が望ましいといえる。すなわち、回転数が10rpm以下の極低速回転機械の異常診断には音響センサを用いるのが望ましいことが示されている。しかしながら、特許文献1では、音響診断に用いて感度が良好となる具体的な音響センサの構造は提案されていない。   FIG. 5 is a diagram disclosed as FIG. FIG. 5 shows frequency characteristics obtained by measuring a response when a microphone and a vibration sensor are attached to a shaker with a magnet and the shaker is subjected to random noise excitation. According to this graph, the vibration sensor is relatively sensitive to high frequency vibrations of about 8 kHz or more, whereas the microphone is relatively sensitive to vibrations in the frequency band of 5 kHz or less. ing. Therefore, as described in Patent Document 1, in a large-diameter bearing that is often used in a very low-speed rotating machine, a frequency sound of 5 kHz is increased from the natural frequency, so that it can be said that acoustic diagnosis using a microphone is desirable. That is, it is shown that it is desirable to use an acoustic sensor for abnormality diagnosis of a very low speed rotating machine having a rotation speed of 10 rpm or less. However, Patent Document 1 does not propose a specific structure of an acoustic sensor that provides good sensitivity for use in acoustic diagnosis.

なお、下記特許文献2には、人の発話音声の体内伝播音を集音する接触型マイクロホンに関し、エレクトレット膜が樹脂材料の中に埋め込まれた形状の接触型マイクを人体に押しつけると、人体からの反力を受けて樹脂部材が変形するが、接触圧力の違いなどがあればマイクの特性が変化するという問題に鑑みてなされた接触型マイクロホンに関する発明が記載されている。この接触型マイクロホンは、人体に接触させて用いられ、人の発話音声の体内伝播音を集音して電気信号に変換するマイク部と、前記マイク部を人体に接触させたときに前記マイク部に加わる圧力を調整する圧力調整部とを備えることを特徴とする。圧力調整部は、マイク部を形成する樹脂が変形することによる特性変化を防ぐために設けられている。また、明細書中には、この接触型マイクロホンは、特に1kHz以下の周波数領域におけるS/N特性が一般的な非接触型マイクより優れていることが記載されている。しかしながら、1kHz以下の周波数領域は、極低速回転機械の軸受の診断領域から外れている。   Note that the following Patent Document 2 relates to a contact microphone that collects body-borne sound of human speech, and when a contact microphone with an electret film embedded in a resin material is pressed against the human body, The invention relates to a contact-type microphone that has been made in view of the problem that the characteristics of the microphone change if there is a difference in contact pressure or the like, although the resin member is deformed in response to the reaction force. This contact type microphone is used in contact with the human body, and collects the sound transmitted through the body of a person's speech and converts it into an electrical signal, and the microphone unit when the microphone unit is brought into contact with the human body. And a pressure adjusting unit for adjusting the pressure applied to the head. The pressure adjusting unit is provided to prevent a change in characteristics due to deformation of the resin forming the microphone unit. Further, it is described in the specification that this contact type microphone is superior to a general non-contact type microphone in S / N characteristics particularly in a frequency region of 1 kHz or less. However, the frequency region of 1 kHz or less is out of the diagnostic region of the bearing of the extremely low speed rotating machine.

さらに、下記特許文献3には、耐湿性および指向性に優れ、小型化等を図ることのできる異常感知センサユニットであって、機械装置から発生する超音波を検出して、該機械装置の異常を感知するものが記載されている。この異常感知センサユニットは、空中超音波センサと、集音ホーンとして機能する筒状ケースと、前記超音波センサを取り付けるセンサ取付部と、筐体と、を備え、前記機械装置に前記筒状ケースの開口部を対向させ、該機械装置から発生する超音波を収録することを特徴とする。筒状ケースは、周辺の音を遮って指向性を高める目的ももつ。しかし、筒状ケース内の空中超音波センサは、診断対象の機械装置とは離れて配置されており、極低速回転機械の軸受から発生する信号は小さいので、この異常感知センサユニットでは極低速回転機械の軸受の異常の検出は困難である。   Further, Patent Document 3 below is an abnormality detection sensor unit that is excellent in moisture resistance and directivity, and that can be downsized and the like. What senses is described. The abnormality detection sensor unit includes an aerial ultrasonic sensor, a cylindrical case that functions as a sound collection horn, a sensor mounting portion to which the ultrasonic sensor is attached, and a housing. The cylindrical case is provided in the mechanical device. The ultrasonic waves generated from the mechanical device are recorded. The cylindrical case also has the purpose of increasing directivity by blocking surrounding sounds. However, the aerial ultrasonic sensor in the cylindrical case is arranged away from the machine device to be diagnosed, and the signal generated from the bearing of the extremely low speed rotating machine is small. It is difficult to detect abnormalities in mechanical bearings.

特開2008−268187号公報JP 2008-268187 A 特開2006−287810号公報JP 2006-287810 A 特開2006−105727号公報JP 2006-105727 A

本発明は、回転数が10rpm以下の極低速回転機械の軸受の異常診断に使用して有効な音響センサ装置を提供することを目的とする。   An object of the present invention is to provide an acoustic sensor device that is effective for use in diagnosis of a bearing abnormality in a very low speed rotating machine having a rotation speed of 10 rpm or less.

本発明の音響センサ装置は、回転数が10rpm以下の回転機械に接触させて、前記回転機械の軸受からの伝播音を検出することにより異常診断を行う音響センサ装置であって、音響センサと、前記音響センサを収容する中空部材と、前記中空部材の一端に配置された集音側キャップと、前記音響センサの集音面と集音側キャップとに狭持された弾性部材と、前記音響センサの前記集音面を前記弾性部材に押し付けるとともに、押付力を調整して前記弾性部材の接触共振周波数を1kHz〜5kHzの範囲に保持する前記中空部材の他端に配置されたコネクタ側キャップと、を備える。 The acoustic sensor device of the present invention is an acoustic sensor device that makes an abnormality diagnosis by contacting a rotating machine having a rotational speed of 10 rpm or less and detecting a propagation sound from a bearing of the rotating machine, and the acoustic sensor; A hollow member for housing the acoustic sensor; a sound collecting side cap disposed at one end of the hollow member; an elastic member sandwiched between the sound collecting surface and the sound collecting side cap of the acoustic sensor; and the acoustic sensor A connector-side cap disposed at the other end of the hollow member that presses the sound collection surface of the elastic member against the elastic member and adjusts the pressing force to maintain the contact resonance frequency of the elastic member in a range of 1 kHz to 5 kHz; Is provided.

前記弾性部材の縦弾性係数は、1MPa以上、10GPa以下とすることができる。
前記弾性部材は、ニトリルゴムとすることができる。
前記弾性部材は、フッ素樹脂とすることができる。
前記弾性部材の厚みは、1mm以上、4mm以下とすることができる。
The elastic modulus of the elastic member can be 1 MPa or more and 10 GPa or less.
The elastic member may be nitrile rubber.
The elastic member may be a fluororesin.
The thickness of the elastic member can be 1 mm or more and 4 mm or less.

記コネクタ側キャップはねじ込み式キャップであり、前記コネクタ側キャップのねじ込み量に応じて押付力を調整することができる。 Before Symbol connector side caps are screw-caps, it is possible to adjust the pressing force in accordance with the screwing amount of the connector-side cap.

回転数が10rpm以下の極低速回転機械の軸受の音響診断を確実に実行することができる。   The acoustic diagnosis of the bearing of the extremely low speed rotating machine having a rotation speed of 10 rpm or less can be reliably executed.

本実施形態の音響センサユニットを示す図である。It is a figure which shows the acoustic sensor unit of this embodiment. 緩衝部材の材料により異なる周波数応答を示す図である。It is a figure which shows a different frequency response with the material of a buffer member. 図2に従って作成された表を示す図である。It is a figure which shows the table | surface produced according to FIG. 本実施形態の音響センサユニットの使用例を示す図である。It is a figure which shows the usage example of the acoustic sensor unit of this embodiment. 音響センサと振動センサの周波数応答を示すグラフである。It is a graph which shows the frequency response of an acoustic sensor and a vibration sensor.

図1は、本発明の一実施形態である音響センサユニットの長手方向断面の概略形状を示す図である。音響センサユニット10は、音響センサ1と、音響センサ1を収納する円筒形状の金属製のケース20を有する。音響センサ1は、暗騒音を遮断するために、ケース20により密閉されている。さらに、使用環境により防水性が必要な場合は、防水剤で金属ケースの接合部をコーティングすることができる。   FIG. 1 is a diagram showing a schematic shape of a longitudinal section of an acoustic sensor unit according to an embodiment of the present invention. The acoustic sensor unit 10 includes an acoustic sensor 1 and a cylindrical metal case 20 that houses the acoustic sensor 1. The acoustic sensor 1 is sealed with a case 20 in order to block background noise. Furthermore, when waterproofness is required depending on the use environment, the joint portion of the metal case can be coated with a waterproofing agent.

音響センサユニット10は、10rpm以下の極低速回転機械の異常を検知するために、診断対象の極低速回転機械に接触させ、回転機械から伝播する1kHz〜5kHzの周波数音を集音する。音響センサ1は、本実施形態では、10kHzまでほぼフラットな周波数特性をもつ市販のマイクロホンを使用する。音響センサ1は、音響信号を入力する集音部11と、音響信号を変換した電気信号を信号処理部(図示せず)に導くケーブル(図示せず)を接続するためのコネクタ7を有する。なお、音響センサとしては、図1に示すようなマイクロホンに限らず、各種の音響センサを使用することができる。音響センサの形状も図1に示す形状に限定されない。   The acoustic sensor unit 10 collects a frequency sound of 1 kHz to 5 kHz transmitted from the rotating machine in contact with the extremely low speed rotating machine to be diagnosed in order to detect an abnormality of the extremely low speed rotating machine of 10 rpm or less. In the present embodiment, the acoustic sensor 1 uses a commercially available microphone having a substantially flat frequency characteristic up to 10 kHz. The acoustic sensor 1 includes a sound collecting unit 11 for inputting an acoustic signal and a connector 7 for connecting a cable (not shown) for guiding an electric signal obtained by converting the acoustic signal to a signal processing unit (not shown). In addition, as an acoustic sensor, not only a microphone as shown in FIG. 1 but various acoustic sensors can be used. The shape of the acoustic sensor is not limited to the shape shown in FIG.

ケース20は、長手方向に伸びる中空円筒部材3と、中空円筒部材3の一端に配置された金属製の集音側キャップ4と、中空円筒部材3の他端に配置された金属製のコネクタ側キャップ2とを有する。中空円筒部材3は、中空円筒部材3の内壁が音響センサ1およびコネクタ7と接触しないような大きさの内径を有する。音響センサ1およびコネクタ7と中空円筒部材3との間に空間が介在するので、中空円筒部材3から音響センサ1に伝わる暗騒音を遮断することができる。   The case 20 includes a hollow cylindrical member 3 extending in the longitudinal direction, a metal sound collecting side cap 4 disposed at one end of the hollow cylindrical member 3, and a metal connector side disposed at the other end of the hollow cylindrical member 3. And a cap 2. The hollow cylindrical member 3 has an inner diameter such that the inner wall of the hollow cylindrical member 3 does not contact the acoustic sensor 1 and the connector 7. Since a space is interposed between the acoustic sensor 1 and the connector 7 and the hollow cylindrical member 3, background noise transmitted from the hollow cylindrical member 3 to the acoustic sensor 1 can be blocked.

集音側キャップ4の内面には、音響センサ1の集音部11を載置する凹部41が形成される。凹部41には、緩衝部材9を介して集音部11が押し付けられる。緩衝部材9は、弾性材料で形成され、本実施形態では、集音部11に対応する中実の円板である。   On the inner surface of the sound collecting side cap 4, a concave portion 41 for placing the sound collecting portion 11 of the acoustic sensor 1 is formed. The sound collection unit 11 is pressed against the recess 41 via the buffer member 9. The buffer member 9 is formed of an elastic material, and is a solid disk corresponding to the sound collection unit 11 in the present embodiment.

集音側キャップ4の外側端面の中央部には、外周にねじが切られた凸部42を有する。凸部42は、内周にねじが切られたマグネット6の凹部61にねじ込まれ、集音側キャップ4はマグネット6と一体化される。音響センサユニット10が、診断対象の回転機械の適当な外面にマグネット6の底面62を密着させて取り付けられると、音響センサ1は、マグネット6、集音側キャップ4、緩衝部材9を伝播する回転機械の音を検出することができる。   A central portion of the outer end face of the sound collecting side cap 4 has a convex portion 42 that is threaded on the outer periphery. The convex portion 42 is screwed into the concave portion 61 of the magnet 6 threaded on the inner periphery, and the sound collecting side cap 4 is integrated with the magnet 6. When the acoustic sensor unit 10 is attached with the bottom surface 62 of the magnet 6 in close contact with an appropriate outer surface of the rotating machine to be diagnosed, the acoustic sensor 1 rotates to propagate through the magnet 6, the sound collecting side cap 4, and the buffer member 9. The sound of the machine can be detected.

診断対象の回転機械が、集音側キャップ4の凸部42に対応する、内周部にねじが切られた凹部を有するものであると、音響センサユニット10は、マグネット6を取り外して、集音側キャップ4の凸部42を診断対象の回転機械の凹部にねじ込むことにより、回転機械に密着して取り付けることができる。   If the rotating machine to be diagnosed has a concave portion that is threaded on the inner periphery corresponding to the convex portion 42 of the sound collecting side cap 4, the acoustic sensor unit 10 removes the magnet 6 and By screwing the convex portion 42 of the sound side cap 4 into the concave portion of the rotating machine to be diagnosed, it can be attached in close contact with the rotating machine.

作業者が音響センサユニット10を保持して、診断対象の機械に押し付けることにより音響診断を行うこともできる。この場合には、マグネット6に代えて金属の探触棒を用いる。探触棒の先端は、比較的細くなっており、探触棒の後端には、集音側キャップ4の凸部42に対応して内面にねじが切られた凹部が設けられている。マグネット6に代えて集音側キャップ4に取り付けて使用する。   An operator can hold the acoustic sensor unit 10 and perform acoustic diagnosis by pressing the acoustic sensor unit 10 against a machine to be diagnosed. In this case, a metal probe rod is used instead of the magnet 6. The tip of the probe rod is relatively thin, and a concave portion whose inner surface is threaded corresponding to the convex portion 42 of the sound collecting side cap 4 is provided at the rear end of the probe rod. Instead of the magnet 6, it is used by being attached to the sound collecting side cap 4.

音響センサ1のコネクタ7は、音響センサ1側の大径部71と、音響センサユニット10から突出する小径部72を有する。中空円筒部材3を密閉するコネクタ側キャップ2は、コネクタ7の小径部72が挿通する中心孔22を有し、コネクタ側キャップ2の側面内周にはねじ21が切られている。中空円筒部材3のコネクタ側の端部の外周には、コネクタ側キャップ2のねじ21に対応するねじ31が切られている。コネクタ側キャップ2は、その中心孔22の側面と、コネクタ7の大径部71の肩部に当接する面には、カラー5を有している。   The connector 7 of the acoustic sensor 1 has a large-diameter portion 71 on the acoustic sensor 1 side and a small-diameter portion 72 that protrudes from the acoustic sensor unit 10. The connector-side cap 2 that seals the hollow cylindrical member 3 has a center hole 22 through which the small-diameter portion 72 of the connector 7 is inserted, and a screw 21 is cut on the inner periphery of the side surface of the connector-side cap 2. A screw 31 corresponding to the screw 21 of the connector-side cap 2 is cut on the outer periphery of the end of the hollow cylindrical member 3 on the connector side. The connector-side cap 2 has a collar 5 on the side surface of the center hole 22 and the surface that contacts the shoulder of the large-diameter portion 71 of the connector 7.

コネクタ7の小径部72をコネクタ側キャップ2の中心孔22に挿通して、コネクタ側キャップ2を回転させ、コネクタ側キャップ2のねじ21を中空円筒部材3外周のねじ31にねじ込むことにより、コネクタ側キャップ2が中空円筒部材3を密閉する。このとき、コネクタ7の大径部71の肩部に当接するコネクタ側キャップ2は、コネクタ側キャップ2の前進により、音響センサ1を緩衝部材9に押し付けることになる。したがって、コネクタ側キャップ2のねじ込み量を調整することにより、緩衝部材9に所望の押付力、言い換えれば所望の押込量を与えることができる。これにより、緩衝部材9の接触共振周波数を制御することができ、回転数が10rpm以下の回転機械の異常診断に最適な接触共振周波数を得ることができる。   The small diameter portion 72 of the connector 7 is inserted into the center hole 22 of the connector side cap 2, the connector side cap 2 is rotated, and the screw 21 of the connector side cap 2 is screwed into the screw 31 on the outer periphery of the hollow cylindrical member 3. The side cap 2 seals the hollow cylindrical member 3. At this time, the connector-side cap 2 that comes into contact with the shoulder of the large-diameter portion 71 of the connector 7 presses the acoustic sensor 1 against the buffer member 9 by the advancement of the connector-side cap 2. Therefore, by adjusting the screwing amount of the connector-side cap 2, it is possible to give the buffer member 9 a desired pressing force, in other words, a desired pressing amount. Thereby, the contact resonance frequency of the buffer member 9 can be controlled, and the contact resonance frequency optimal for abnormality diagnosis of a rotating machine having a rotation speed of 10 rpm or less can be obtained.

なお、本実施形態では、コネクタ側キャップ2のねじ込み量を調整することにより、緩衝部材9に一定の押付力を与えているが、緩衝部材9に押付力を与える方法は、これに限らない。例えば、コネクタ側キャップ2は一定のねじ込み量でねじ込み、コネクタ側キャップ2とコネクタ7の間にばね部材を介在させて、押付力を調整することもできる。この場合、コネクタ側キャップ2はねじ込み式のものではなくてもよく、コネクタ側キャップ2とコネクタ7の間にばね部材を保持できるものであればよい。緩衝部材9の押し付けに関しては、その他適宜の方法あるいは構造を採用することができる。   In the present embodiment, a constant pressing force is applied to the buffer member 9 by adjusting the screwing amount of the connector-side cap 2, but the method of applying the pressing force to the buffer member 9 is not limited thereto. For example, the connector-side cap 2 can be screwed with a constant screw-in amount, and the pressing force can be adjusted by interposing a spring member between the connector-side cap 2 and the connector 7. In this case, the connector-side cap 2 does not have to be a screw-in type, and any connector that can hold the spring member between the connector-side cap 2 and the connector 7 may be used. Regarding the pressing of the buffer member 9, other appropriate methods or structures can be adopted.

本実施形態の音響センサユニット10では、緩衝部材9の材料を選択し、音響センサ1を緩衝部材9に押し付ける押付力を調整する。選択された材料を使用した緩衝部材9に対する押付力を調整することにより、音響センサ1と緩衝部材9の接触共振周波数を所望の値に制御することができる。本実施形態では、診断対象が回転数が10rpm以下の回転機械であることを考慮して、緩衝部材9が1kHz〜5kHzの周波数帯に共振周波数をもつように、押付力あるいは押込量が調整される。これにより、10rpm以下の転がり軸受の音響診断に最適な音響センサユニット10を実現することができる。   In the acoustic sensor unit 10 of this embodiment, the material of the buffer member 9 is selected, and the pressing force for pressing the acoustic sensor 1 against the buffer member 9 is adjusted. The contact resonance frequency between the acoustic sensor 1 and the buffer member 9 can be controlled to a desired value by adjusting the pressing force against the buffer member 9 using the selected material. In this embodiment, considering that the diagnosis target is a rotating machine having a rotation speed of 10 rpm or less, the pressing force or the pressing amount is adjusted so that the buffer member 9 has a resonance frequency in a frequency band of 1 kHz to 5 kHz. The Thereby, the acoustic sensor unit 10 optimal for acoustic diagnosis of a rolling bearing of 10 rpm or less can be realized.

図2は、緩衝部材の材質の相違による周波数特性を示すグラフであり、図3は、図2のグラフの1kHzごとのゲインの値を表にしたものである。
緩衝部材9の材料として、4種類の材料を試みた。すなわち、ニトリルゴム(縦弾性係数E=4MPa)、フッ素樹脂(縦弾性係数E=4.1GPa)、MCナイロン(登録商標)(縦弾性係数E=32GPa)、ポリアセタール(縦弾性係数E=26GPa)を用いて緩衝部材を作成した。緩衝部材9の形状は、音響センサ1の集音部の形状に合わせて中実の円板状であり、外径は7mm、厚さは2mmとした。上述の4種類の材料で形成した緩衝部材9を用いて音響センサユニット10の周波数特性を測定した結果が図2のグラフである。
FIG. 2 is a graph showing frequency characteristics depending on the material of the buffer member, and FIG. 3 is a table showing gain values for 1 kHz in the graph of FIG.
Four types of materials were tried as the material of the buffer member 9. Nitrile rubber (longitudinal elastic modulus E = 4 MPa), fluororesin (longitudinal elastic modulus E = 4.1 GPa), MC nylon (registered trademark) (longitudinal elastic modulus E = 32 GPa), polyacetal (longitudinal elastic modulus E = 26 GPa) A cushioning member was prepared using The shape of the buffer member 9 is a solid disk shape in accordance with the shape of the sound collecting portion of the acoustic sensor 1, the outer diameter is 7 mm, and the thickness is 2 mm. The result of measuring the frequency characteristics of the acoustic sensor unit 10 using the buffer member 9 formed of the above-described four types of materials is the graph of FIG.

図2、3から分かるように、フッ素樹脂の周波数応答は、5kHzまでの範囲で、MCナイロン(登録商標)およびポリアセタールと比較して約10dB高い。さらにニトリルゴムの周波数応答は、4.5kHzまでフッ素樹脂に比べて約10dB高く、比較的平坦な特性を示している。したがって、MCナイロン(登録商標)およびポリアセタールと比較すると、フッ素樹脂とニトリルゴムとは、本実施形態の緩衝部材9として適しているということができる。   As can be seen from FIGS. 2 and 3, the frequency response of the fluororesin is about 10 dB higher than that of MC nylon (registered trademark) and polyacetal in the range up to 5 kHz. Furthermore, the frequency response of nitrile rubber is about 10 dB higher than that of fluororesin up to 4.5 kHz, indicating a relatively flat characteristic. Therefore, compared with MC nylon (registered trademark) and polyacetal, it can be said that fluororesin and nitrile rubber are suitable as the buffer member 9 of this embodiment.

MCナイロン(登録商標)の縦弾性係数が32GPaで、ポリアセタールの縦弾性係数が26GPaであるのに対して、フッ素樹脂の縦弾性係数は4.1GPaであって、一桁小さい。さらにニトリルゴムの縦弾性係数は、4MPaであり、フッ素樹脂の縦弾性係数と比較して三桁小さい。したがって、比較的柔軟性のある弾性材料が緩衝部材9の材料に適しているということができる。   MC nylon (registered trademark) has a longitudinal elastic modulus of 32 GPa and polyacetal has a longitudinal elastic modulus of 26 GPa, whereas that of fluororesin is 4.1 GPa, which is an order of magnitude smaller. Furthermore, the longitudinal elastic modulus of nitrile rubber is 4 MPa, which is three orders of magnitude smaller than that of fluororesin. Therefore, it can be said that a relatively flexible elastic material is suitable for the material of the buffer member 9.

押し付けることによる塑性変形の可能性などを考慮すると、音響センサユニット10の緩衝部材としては、縦弾性係数が1MPa以上の材料を採用するのがよい。また、フッ素樹脂は、ニトリルゴムより硬く塑性変形の可能性も比較的低いので、例えば長期間の使用に有利である。以上のことから、本実施形態の音響センサユニット10の緩衝部材としては、縦弾性係数が1MPa〜10Gpaの範囲の材料が好適である。   In consideration of the possibility of plastic deformation caused by pressing, a material having a longitudinal elastic modulus of 1 MPa or more is preferably used as the buffer member of the acoustic sensor unit 10. Further, since the fluororesin is harder than nitrile rubber and has a relatively low possibility of plastic deformation, it is advantageous for long-term use, for example. From the above, as the buffer member of the acoustic sensor unit 10 of the present embodiment, a material having a longitudinal elastic modulus in the range of 1 MPa to 10 Gpa is suitable.

柔軟性のある弾性部材で形成された緩衝部材9について、緩衝部材9の厚みを厚くしすぎると、緩衝部材9に曲げの圧力がかかり周波数特性が急変する周波数帯が現れる、換言すれば周波数特性曲線に折れが発生する場合がある。また、緩衝部材9の厚みが薄すぎると、緩衝部材9が固くなるので周波数特性が低くなる。したがって、本実施形態の緩衝部材9の厚みは、1mm〜4mmの範囲とするのが望ましい。   If the buffer member 9 is made of a flexible elastic member, if the buffer member 9 is too thick, a frequency band in which the frequency characteristic changes suddenly due to bending pressure applied to the buffer member 9 appears, in other words, the frequency characteristic. The curve may be broken. On the other hand, if the thickness of the buffer member 9 is too thin, the buffer member 9 becomes hard and the frequency characteristics are lowered. Therefore, the thickness of the buffer member 9 of the present embodiment is desirably in the range of 1 mm to 4 mm.

なお、音響センサユニット10では、診断対象の回転機械に接触した部材を伝播する音を集めるので、緩衝部材9に使用する円板には貫通孔の必要はない。しかしながら、例えばリング状の緩衝部材で、円板の中央部に貫通孔があるような場合でも、リング部分を通って伝わる固体伝播音に加え、中央貫通孔を通過する空中伝播音も集音することができれば、使用可能である。   The acoustic sensor unit 10 collects sound that propagates through a member that has contacted the rotating machine to be diagnosed, and therefore there is no need for a through hole in the disk used for the buffer member 9. However, for example, in the case of a ring-shaped cushioning member, even if there is a through hole in the center part of the disk, in addition to the solid propagation sound transmitted through the ring part, the airborne sound passing through the center through hole is also collected. If you can, you can use it.

ニトリルゴムは、上述のように緩衝部材9の材料として効果の高いものであるが、大きな押付力で押し付けると塑性変形を起こすおそれがある。さらには、押付力あるいは押込量が変化すると、接触共振点が変化してしまう。したがって、緩衝部材9には所定の押付力を付与する必要がある。本実施形態で、緩衝部材9をニトリルゴムで製造する場合、厚み2mmであれば、押込み量は0.2〜0.3mmであり、厚みの10〜15%の押込み量としている。この押し込み量は、前述のように上キャップ2のねじ込み量で調整され、厚みの10〜15%の押込み量を実現している。   Nitrile rubber is highly effective as a material of the buffer member 9 as described above, but if it is pressed with a large pressing force, plastic deformation may occur. Furthermore, when the pressing force or the pressing amount changes, the contact resonance point changes. Therefore, it is necessary to apply a predetermined pressing force to the buffer member 9. In this embodiment, when the buffer member 9 is made of nitrile rubber, if the thickness is 2 mm, the pushing amount is 0.2 to 0.3 mm, and the pushing amount is 10 to 15% of the thickness. This pushing amount is adjusted by the screwing amount of the upper cap 2 as described above, and a pushing amount of 10 to 15% of the thickness is realized.

図4は、本実施形態の音響センサユニット10の使用例を説明する図である。数rpmで回転する連続鋳造設備用軸受に多用される自動調心ころがり軸受箱100に、マグネット6を用いて音響センサユニット10を取り付ける。これにより、ころがり軸受の回転による音響を固体伝播により検出することができ、ころがり軸受の回転の異常を診断することができる。   FIG. 4 is a diagram illustrating an example of use of the acoustic sensor unit 10 of the present embodiment. The acoustic sensor unit 10 is attached using a magnet 6 to a self-aligning rolling bearing box 100 that is frequently used in a bearing for continuous casting equipment that rotates at several rpm. Thereby, the sound by rotation of a rolling bearing can be detected by solid propagation, and abnormality of rotation of a rolling bearing can be diagnosed.

以上説明したように、本実施形態では、緩衝部材9の縦弾性係数や厚さを選定して、接触共振周波数を1kHz〜5kHzに合わせることにより、周波数特性の急激なピークや低下がなく、1kHz〜5kHzの全域で大きなゲインを確保することができる。したがって、回転数が10rpm以下の極低速回転機械の音響診断に有効な音響センサを実現することができる。   As described above, in the present embodiment, by selecting the longitudinal elastic modulus and thickness of the buffer member 9 and adjusting the contact resonance frequency to 1 kHz to 5 kHz, there is no sharp peak or decrease in frequency characteristics. A large gain can be secured in the entire range of ˜5 kHz. Therefore, it is possible to realize an acoustic sensor effective for acoustic diagnosis of an extremely low speed rotating machine having a rotation speed of 10 rpm or less.

10 音響センサユニット
1 音響センサ
11 集音面
20 ケース
2 コネクタ側キャップ
21 ねじ
22 中心孔
3 中空円筒部材
31 ねじ
4 集音側キャップ
41 凹部
42 凸部
5 カラー
6 マグネット
61 凹部
62 底面
7 コネクタ
71 大径部
72 小径部
9 緩衝部材
100 軸受箱
DESCRIPTION OF SYMBOLS 10 Acoustic sensor unit 1 Acoustic sensor 11 Sound collecting surface 20 Case 2 Connector side cap 21 Screw 22 Center hole 3 Hollow cylindrical member 31 Screw 4 Sound collecting side cap 41 Concave part 42 Convex part 5 Color 6 Magnet 61 Concave part 62 Bottom face 7 Connector 71 Large Diameter portion 72 Small diameter portion 9 Buffer member 100 Bearing box

Claims (6)

回転数が10rpm以下の回転機械に接触させて、前記回転機械の軸受からの伝播音を検出することにより異常診断を行う音響センサ装置であって、
音響センサと、
前記音響センサを収容する中空部材と、
前記中空部材の一端に配置された集音側キャップと、
前記音響センサの集音面と集音側キャップとに狭持された弾性部材と、
前記音響センサの前記集音面を前記弾性部材に押し付けるとともに、押付力を調整して前記弾性部材の接触共振周波数を1kHz〜5kHzの範囲に保持する前記中空部材の他端に配置されたコネクタ側キャップと、
を備える音響センサ装置。
An acoustic sensor device that makes an abnormality diagnosis by contacting a rotating machine having a rotation speed of 10 rpm or less and detecting a propagation sound from a bearing of the rotating machine,
An acoustic sensor;
A hollow member that houses the acoustic sensor;
A sound collecting side cap disposed at one end of the hollow member;
An elastic member sandwiched between the sound collecting surface and the sound collecting side cap of the acoustic sensor;
The connector side disposed at the other end of the hollow member that presses the sound collection surface of the acoustic sensor against the elastic member and adjusts the pressing force to maintain the contact resonance frequency of the elastic member in the range of 1 kHz to 5 kHz. A cap ,
An acoustic sensor device comprising:
前記弾性部材の縦弾性係数は、1MPa以上、10GPa以下である請求項1に記載の音響センサ装置。   The acoustic sensor device according to claim 1, wherein the elastic member has a longitudinal elastic modulus of 1 MPa or more and 10 GPa or less. 前記弾性部材は、ニトリルゴムである請求項2に記載の音響センサ装置。   The acoustic sensor device according to claim 2, wherein the elastic member is nitrile rubber. 前記弾性部材は、フッ素樹脂である請求項2に記載の音響センサ装置。   The acoustic sensor device according to claim 2, wherein the elastic member is a fluororesin. 前記弾性部材の厚みは、1mm以上、4mm以下である請求項1〜4のいずれか1項に記載の音響センサ装置。   The acoustic sensor device according to claim 1, wherein the elastic member has a thickness of 1 mm or more and 4 mm or less. 記コネクタ側キャップはねじ込み式キャップであり、前記コネクタ側キャップのねじ込み量に応じて押付力を調整する請求項に記載の音響センサ装置。 Before Symbol connector side caps are screw-caps, the acoustic sensor device according to claim 1 to adjust the pressing force in accordance with the screwing amount of the connector-side cap.
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US20160039434A1 (en) * 2013-03-27 2016-02-11 Aktiebolaget Skf Hub unit

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