JP3639391B2 - Dielectric polarization velocimeter - Google Patents

Description

【０００９】
数１の右辺第一項は、電場の変化に瞬間的に追従する光学分極や赤外分極の成分を、右辺第二項が、配向分極などの緩和型の分極の成分を表す。ここで、χ_e1は瞬間的な分極に対応した電気感受率である。ａ（ｔ）は余効関数で、電場がインパルス状に変化したときの、緩和型分極のインパルス応答に相当し、次のような関数である。
【００１０】
【数２】

【００１１】
χ_e2は、緩和型分極に対応した電気感受率、τは緩和時間である。電極１の電位差Ｖを矩形波状に変化させた場合、電場Ｅ＝Ｖ／ｄは図２（上）に示すような波形に、誘電分極Ｐは図２（中）に示すような波形になる。また、電極１により形成されるコンデンサーに流れる電流はｄＤ／ｄｔに比例するから、電流検出器３の出力は図２（下）のような波形となる。コンデンサーに流れる電流の内、パルス状に流れる電流を瞬間電流、パルス状の電流に続いて指数関数的に流れる電流を吸収電流と呼ぶ。
【００１２】
次に、物体６が速度Ｕで移動している場合を考える。今、電極１にはさまれた領域における電場をＥ、緩和型分極の大きさをＰ₂ として、物体の誘電分極がＰ＝４πχ_e1Ｅ＋Ｐ₂ であるとする。微小な時間間隔Δｔの間に、電場の存在する領域から電場がゼロの領域へ出ていく誘電体の体積はｗｄＵΔｔである。一方、同じ体積ｗｄＵΔｔの誘電体が、電場がゼロの領域から電場の存在する領域に入ってくる。新たに入ってきた微小体積内の誘電分極は、Δｔが緩和時間τに比べて十分小さいならば、Δｔの間に誘起される緩和型分極の成分はほとんどゼロなので、瞬間的に形成される分極成分４πχ_e1Ｅにほぼ等しい。結局、電極１にはさまれた領域全体では、誘電体中の誘電分極は、ｗｄＵΔｔ・Ｐ₂ だけ減少することになる。本来の緩和現象によるＰ₂ の変化も考慮すれば、電極１にはさまれた領域で平均したＰ₂ について
【００１３】
【数３】

【００１４】
という微分方程式が成り立つ。数３から、物体６の移動によって、緩和型分極の緩和時間τが等価的にγ倍なり、また電気感受率χ_e2も等価的にγ倍になることがわかる。ただし
【００１５】
【数４】

【００１６】
である。このように、物体が移動することによって、固定した電極から観測した物体の誘電体としての性質が見かけ上変化する。その変化の度合いは、物体中の誘電分極の移動の度合いの、従って物体の移動速度Ｕの関数である。誘電体の性質が等価的に変化するから、みかけの余効関数も変化し、電流検出器３の出力波形の吸収電流の波形が変化する。信号処理装置４は、吸収電流の波形から緩和時間を求め、その変化から物体６の移動速度Ｕを計算している。
【００１７】
上に説明したように、物体の移動によって、見かけの緩和時間だけでなく、見かけの電気感受率もまた変化する。従って、本実施例のように緩和時間の変化から移動速度を計算するのではなく、電気感受率の変化から移動速度Ｕを計算しても構わない。また、電極１と物体６とで形成されるコンデンサーのインピーダンスには、電極にはさまれた物体の誘電的性質が反映しているから、コンデンサーのインピーダンスを測定して移動速度Ｕを求めてもよい。この場合、コンデンサーのインピーダンス測定は、通常のインピーダンス測定法のいずれの方法を用いても構わない。
【００１８】
本実施例では、物体の厚みや誘電率は一定であるとして、緩和時間のみを計算して移動速度を測定している。もし、物体の誘電率や物体の厚みなどが変化すると、物体の移動速度が同一でも、観測される緩和時間が変化するので、速度測定の誤差を生じる。このような事が想定される場合には、電極１の形成するコンデンサーの静電容量をも併せて測定し、この値によって、補正を加える方法を採ることができる。
【００１９】
（第二実施例）図３は、管内の流れの流速測定に適用した、本発明の第二実施例を示している。図３において、７は流体の流れている管、１は管７の中の流体に電場を印可する電極、８および９は、それぞれ電極１の上流と下流に設置された検出用電極である。本実施例においては、電極１を中心にして、電極８と電極９とは対称な形状に作られている。２は発振器で、電極１に正弦波電圧を印可している。１０および１１は、検出用電極８および９の電位差を検出して増幅する電圧増幅器、１２は電圧増幅器１０と１１の出力の差を増幅する差動増幅器である。１３は信号処理装置で、差動増幅器１２の出力を、発振器２の信号を同期信号として同期検波し、管７中の流体の流速を計算して、指示計器５に出力している。
【００２０】
電極１に正弦的な電圧を加えると、電極８および電極９には、静電誘導により正弦波電圧が誘起される。流れが無い場合は、電極８と９とが対称に作成されているので、それぞれの電極の誘起電圧は等しく、差動増幅器１２の出力はゼロである。これに対して、管７中の流体が流れていると、上流側電極８にはさまれた領域には、誘電分極の誘起されていない流体が流れ込むのに対して、下流側電極９にはさまれた領域には、電極１の電場によって分極された流体が流れ込む。このため、電極８に誘起される電圧と電極９に誘起される電圧に差が生じ、差動増幅器１２の出力信号はゼロではなくなる。差動増幅器１２の出力信号の振幅は、流体の流速が大きくなる程大きくなるから、信号処理装置１３で同期検波して、その結果から流速を知ることができる。なお、この実施例では管１を流れるのは液体であるが、測定原理から明らかなように、粉体が気体によって搬送される固気二相流のような流れにも適用することができる。
【００２１】
（第三実施例）図４は、櫛歯型電極を用いた本発明の第三実施例である。図４において、６は速度Ｕで移動している帯状の物体である。１４および１４’は、等しい間隔２ｐで平行に並んだ多数の細長い導体から成る櫛歯型電極で、１４と１４’とは、それぞれの櫛歯状の電極が交互に並ぶように設置されている。２は周波数可変の発振器で、電極１４と１４’の間に周波数ｆの正弦的な電位差を加えている。３は櫛歯型電極１４、１４’によって形成されているコンデンサーに流れる電流を検出する電流検出器である。１５は信号処理装置で、発振器２の発振周波数ｆを変えながら、電極１４と１４’で形成されるコンデンサーのインピーダンスを測定して、物体６の移動速度Ｕを計算し、結果を指示計器５に出力している。
【００２２】
櫛歯型電極１４および１４’に電圧を加えると、物体６の表面には、図５（ａ）に示したような分極が誘起される。時間ｐ／Ｕだけ後には、物体６は、電極のピッチの半分ｐだけ移動する。もし、分極の緩和時間τがｐ／Ｕと同程度以上のオーダーであれば、移動後の物体表面上には、移動前の分極状態の影響が残っている。この残留分極の影響により、櫛歯型電極１４、１４’から観察した物体の誘電体としての性質は、物体が移動している時と静止している時とで変化する。しかも、その変化は、残留分極と、電極間の電場の相対的な位相関係によって異なってくる。このため、物体の移動による誘電的性質の等価的な変化は、電極に加えられる電圧の周波数の関数となる。特に、周波数がｆ₀ ＝Ｕ／２ｐの場合には、図５（ｂ）に示すように、物体が櫛歯型電極の半ピッチｐだけ移動する間に電場が半周期変化するため、一種の共鳴状態となる。従って、信号処理装置４５によって、周波数ｆを変えながらコンデンサーのインピーダンスを測定してｆ₀ を求めれば、物体６の移動速度Ｕを知ることができる。なお、発振器としてＶＣＯを用い、コンデンサーのインピーダンスの位相角の特定の値でロックされるようにフェーズロックトループを形成して、ＶＣＯの発振周波数からＵを求める構成をとることも可能である。
【００２３】
以上の実施例の説明において、測定対象である移動物体を、単一緩和時間の緩和型分極を持つ常誘電体としてきたが、二つ以上の緩和時間を持つ誘電体や強誘電体であっても、物体の運動によって見かけの誘電的性質が変化することは同じであるから、信号処理装置における計算式を変えれば、これらの誘電体にも本発明の原理を適用することが可能である。
【００２４】
【発明の効果】
誘電分極の移動の度合いから速度を検出するという新しい原理に基づく本発明によって、次のような特徴を有する速度計を実現することができる。すなわち、本発明の速度計は、非接触で速度を測定することができる。また、測定対象物体は緩和時間を持つ誘電体であればよく、幅広い対象に適用できる。更に、構造的にも、測定対象近くに電極を設置するだけで速度計が構成できるので、単純で堅牢であり、幅広い使用条件に耐えうる。この他、構造とともに構成要素も単純で一般的な安価なものであるため、低コストに作製することが可能である。
【図面の簡単な説明】
【図１】本発明の第一実施例である。
【図２】電場、誘電分極およびコンデンサー電流の波形図である。
【図３】流体の流速測定に適用した、本発明の第二実施例である。
【図４】櫛歯型電極を使用した、本発明の第三実施例である。
【図５】物体表面の分極状態を示す概念図である。
【符号の説明】
１ 電極
２ 発振器
３ 電流検出器
４ 信号処理装置
５ 指示計器
６ 物体
７ 管
８、９ 検出用電極
１０、１１ 電圧増幅器
１２ 差動増幅器
１３ 信号処理装置
１４、１４’ 櫛歯型電極
１５ 信号処理装置[0001]
[Industrial application fields]
The present invention is an apparatus for measuring the moving speed of an object, in particular, an electric field applied to an object that is a dielectric material to induce dielectric polarization, and the dielectric properties of the object as the dielectric polarization in the object moves together with the object. The present invention relates to a speedometer that detects a change and measures a moving speed of an object.
[0002]
[Prior art]
A conventional speedometer for measuring the moving speed of an object has the following principle. Speedometer using velocity electromotive force generated in conductor moving in magnetic field, speedometer using eddy current generated in conductor moving in magnetic field changing depending on place, equidistant grid attached to measurement object A speedometer that counts the number of passes in a unit time, a speedometer that uses the principle of a spatial filter, a speedometer that uses the Doppler effect of ultrasonic waves and lasers, and the like.
[0003]
[Problems to be solved by the invention]
Conventional speedometers each have high noise, short component life, residual output when the moving speed is zero, narrow speed measurement range, and applicable measurement objects are limited depending on the measurement principle There are problems such as limited installation conditions and environment, and high cost. An object of the present invention is to realize a low-cost speedometer that can measure the moving speed of an object in a non-contact manner, has a simple structure and is robust, based on a new principle.
[0004]
[Means for Solving the Problems]
In order to solve the above problems, in the present invention, an electric field is applied to an object to induce dielectric polarization, and the degree of movement of the dielectric polarization that tries to move while maintaining the shape of the object is determined. The movement speed of the object is measured.
[0005]
[Action]
When an electric field is applied to an object that is a dielectric, dielectric polarization is induced in the object. As the object moves, the external electric field felt by the object changes, but since dielectric polarization has a finite relaxation time, the dielectric polarization in the object cannot instantaneously follow the external electric field and is very small. If you look at the time interval, it moves while maintaining the previous time. An electric field is applied to an object to induce dielectric polarization, and the degree of movement of the dielectric polarization that tries to move while maintaining the shape with the movement of the object is observed as a change in the dielectric properties of the object. By doing so, the moving speed of the object can be measured.
[0006]
【Example】
Hereinafter, details of the present invention will be described based on examples. FIG. 1 shows a first embodiment of the present invention. In FIG. 1, 6 is a belt-like object moving at a speed U in a direction parallel to itself. Reference numeral 1 denotes an electrode formed of a rectangular parallel plate, the interval between the electrode plates is d, the length of the side parallel to the moving direction of the object 6 is l, and the length of the side perpendicular to the moving direction is w. The object 6 is sandwiched between the electrodes 1 and moves in the electric field formed by the electrodes 1. Reference numeral 2 denotes an oscillator which applies a rectangular wave-like alternating potential to the electrode 1. Reference numeral 3 denotes a current detector, which detects a current flowing through a capacitor constituted by the electrode 1 and the object 6. A signal processing device 4 calculates the moving speed of the object 6 from the output signal of the current detector 3 and outputs it to the indicating instrument 5.
[0007]
First, a case where the object 6 is stationary will be described. It is assumed that the electric field is uniform in the region sandwiched between the electrodes 1 and zero elsewhere, but this assumption is for simplifying the explanation and making it easy to understand, and is based on the principle of the present invention. It is not a prerequisite for The potential difference between both ends of the electrode 1 is V, the electric field is E, the electric displacement is D, and the dielectric polarization in the object is P. At this time, D = E + 4πP holds. If the object 6 is a linear paraelectric dielectric having a relaxation polarization with a single relaxation time, the following relationship exists between the electric field E (t) and the dielectric polarization P (t).
[0008]
[Expression 1]

[0009]
Number 1 of the right side first term is a component of the optical polarization and infrared polarization instantaneously follow a change of the electric field, the right side second term is representative of a component of the polarization of relaxor such as orientation polarization. Here, χ _e1 is an electrical susceptibility corresponding to instantaneous polarization. a (t) is an aftereffect function, which corresponds to the impulse response of relaxation-type polarization when the electric field changes in an impulse shape, and has the following function.
[0010]
[Expression 2]

[0011]
χ _e2 is the electrical susceptibility corresponding to relaxation polarization, and τ is the relaxation time. When the potential difference V of the electrode 1 is changed to a rectangular wave shape, the electric field E = V / d has a waveform as shown in FIG. 2 (upper), and the dielectric polarization P has a waveform as shown in FIG. 2 (middle). Further, since the current flowing through the capacitor formed by the electrode 1 is proportional to dD / dt, the output of the current detector 3 has a waveform as shown in FIG. Of the current flowing through the capacitor, the current that flows in a pulsed manner is called the instantaneous current, and the current that flows exponentially following the pulsed current is called the absorbed current.
[0012]
Next, consider a case where the object 6 is moving at a speed U. Now, suppose that the electric field in the region sandwiched between the electrodes 1 is E, the magnitude of the relaxation polarization is P ₂ , and the dielectric polarization of the object is P = 4πχ _e1 E + P ₂ . During the minute time interval Δt, the volume of the dielectric that exits from the region where the electric field exists to the region where the electric field is zero is wdUΔt. On the other hand, the dielectric having the same volume wdUΔt enters the region where the electric field exists from the region where the electric field is zero. If the dielectric polarization in the newly entered microvolume is sufficiently small compared to the relaxation time τ, the component of the relaxation-type polarization induced during Δt is almost zero, so that the polarization formed instantaneously It is approximately equal to the component 4πχ _e1 E. Eventually, in the entire region sandwiched between the electrodes 1, the dielectric polarization in the dielectric is reduced by wdUΔt · P ₂ . Considering the change in P ₂ due to the inherent relaxation phenomenon, the average P ₂ in the region sandwiched between the electrodes 1
[Equation 3]

[0014]
The following differential equation holds. From Equation 3, it can be seen that the relaxation time τ of relaxation-type polarization is equivalently γ times and the electrical susceptibility χ _e2 is equivalently γ-times as the object 6 moves. However, [0015]
[Expression 4]

[0016]
It is. As described above, when the object moves, the property of the object observed from the fixed electrode apparently changes. The degree of change is a function of the degree of movement of the dielectric polarization in the object and hence the moving speed U of the object. Since the properties of the dielectric change equivalently, the apparent aftereffect function also changes, and the absorption current waveform of the output waveform of the current detector 3 changes. The signal processing device 4 calculates the relaxation time from the waveform of the absorption current, and calculates the moving speed U of the object 6 from the change.
[0017]
As explained above, the movement of the object changes not only the apparent relaxation time but also the apparent electrical susceptibility. Therefore, instead of calculating the moving speed from the change in relaxation time as in the present embodiment, the moving speed U may be calculated from the change in electrical susceptibility. Further, the impedance of the capacitor formed by the electrode 1 and the object 6 reflects the dielectric properties of the object sandwiched between the electrodes, so that the moving speed U can be obtained by measuring the impedance of the capacitor. Good. In this case, the impedance measurement of the capacitor may use any of ordinary impedance measurement methods.
[0018]
In this embodiment, assuming that the thickness and dielectric constant of the object are constant, only the relaxation time is calculated and the moving speed is measured. If the dielectric constant of the object, the thickness of the object, etc. change, the observed relaxation time changes even if the moving speed of the object is the same, resulting in a speed measurement error. When such a situation is assumed, it is possible to measure the capacitance of the capacitor formed by the electrode 1 and correct the value based on this value.
[0019]
(Second Embodiment) FIG. 3 shows a second embodiment of the present invention applied to the flow velocity measurement of the flow in the pipe. In FIG. 3, 7 is a pipe through which fluid flows, 1 is an electrode for applying an electric field to the fluid in the pipe 7, and 8 and 9 are detection electrodes installed upstream and downstream of the electrode 1, respectively. In this embodiment, the electrode 8 and the electrode 9 are made symmetrical with the electrode 1 as the center. An oscillator 2 applies a sine wave voltage to the electrode 1. Reference numerals 10 and 11 denote voltage amplifiers that detect and amplify the potential difference between the detection electrodes 8 and 9, and reference numeral 12 denotes a differential amplifier that amplifies the difference between the outputs of the voltage amplifiers 10 and 11. A signal processing device 13 detects the output of the differential amplifier 12 synchronously with the signal of the oscillator 2 as a synchronization signal, calculates the flow velocity of the fluid in the tube 7, and outputs it to the indicating instrument 5.
[0020]
When a sinusoidal voltage is applied to the electrode 1, a sinusoidal voltage is induced in the electrode 8 and the electrode 9 by electrostatic induction. When there is no flow, since the electrodes 8 and 9 are formed symmetrically, the induced voltage of each electrode is equal and the output of the differential amplifier 12 is zero. On the other hand, when the fluid in the pipe 7 is flowing, the fluid without induction of dielectric polarization flows into the region sandwiched by the upstream electrode 8 whereas the downstream electrode 9 A fluid polarized by the electric field of the electrode 1 flows into the sandwiched region. For this reason, a difference is generated between the voltage induced at the electrode 8 and the voltage induced at the electrode 9, and the output signal of the differential amplifier 12 is not zero. Since the amplitude of the output signal of the differential amplifier 12 increases as the fluid flow velocity increases, the signal processor 13 performs synchronous detection, and the flow velocity can be known from the result. In this embodiment, the liquid flowing through the tube 1 is liquid, but as is apparent from the measurement principle, the present invention can also be applied to a flow such as a solid-gas two-phase flow in which powder is conveyed by gas.
[0021]
(Third Embodiment) FIG. 4 shows a third embodiment of the present invention using a comb-shaped electrode. In FIG. 4, reference numeral 6 denotes a belt-like object moving at a speed U. 14 and 14 'are comb-shaped electrodes made up of a large number of elongated conductors arranged in parallel at equal intervals 2p, and 14 and 14' are arranged so that the respective comb-shaped electrodes are alternately arranged. . Reference numeral 2 denotes a variable frequency oscillator, which adds a sinusoidal potential difference of frequency f between the electrodes 14 and 14 '. Reference numeral 3 denotes a current detector that detects a current flowing through a capacitor formed by comb-shaped electrodes 14 and 14 '. Reference numeral 15 denotes a signal processing device, which measures the impedance of the capacitor formed by the electrodes 14 and 14 ′ while changing the oscillation frequency f of the oscillator 2, calculates the moving speed U of the object 6, and sends the result to the indicating instrument 5. Output.
[0022]
When a voltage is applied to the comb-shaped electrodes 14 and 14 ′, polarization as shown in FIG. 5A is induced on the surface of the object 6. After time p / U, the object 6 moves by half p of the electrode pitch. If the polarization relaxation time τ is on the order of p / U or more, the influence of the polarization state before the movement remains on the surface of the object after the movement. Due to the influence of the remanent polarization, the property of the object observed from the comb-shaped electrodes 14 and 14 'varies between when the object is moving and when it is stationary. Moreover, the change varies depending on the remanent polarization and the relative phase relationship of the electric field between the electrodes. Thus, the equivalent change in dielectric properties due to the movement of the object is a function of the frequency of the voltage applied to the electrode. In particular, when the frequency is f ₀ = U / 2p, as shown in FIG. 5 (b), the electric field changes half a period while the object moves by the half pitch p of the comb-shaped electrode. It becomes a resonance state. Therefore, the moving speed U of the object 6 can be known by measuring the impedance of the capacitor while changing the frequency f by the signal processing device 45 to obtain f ₀ . Note that it is also possible to employ a configuration in which a VCO is used as an oscillator and a phase-locked loop is formed so as to be locked at a specific value of the phase angle of the capacitor impedance, and U is obtained from the oscillation frequency of the VCO.
[0023]
In the description of the above embodiments, the moving object to be measured has been a paraelectric material having a relaxation polarization with a single relaxation time. However, it is a dielectric or a ferroelectric material having two or more relaxation times. However, since the apparent dielectric properties change depending on the motion of the object, the principle of the present invention can be applied to these dielectrics by changing the calculation formula in the signal processing device.
[0024]
【The invention's effect】
A speedometer having the following characteristics can be realized by the present invention based on the new principle of detecting speed from the degree of movement of dielectric polarization. That is, the speedometer of the present invention can measure speed without contact. Further, the object to be measured may be a dielectric having a relaxation time, and can be applied to a wide range of objects. Furthermore, structurally, since a speedometer can be configured simply by installing an electrode near the measurement object, it is simple and robust, and can withstand a wide range of use conditions. In addition, the structural elements as well as the structure are simple and generally inexpensive, and thus can be manufactured at low cost.
[Brief description of the drawings]
FIG. 1 is a first embodiment of the present invention.
FIG. 2 is a waveform diagram of electric field, dielectric polarization, and capacitor current.
FIG. 3 is a second embodiment of the present invention applied to fluid flow velocity measurement.
FIG. 4 is a third embodiment of the present invention using a comb-shaped electrode.
FIG. 5 is a conceptual diagram showing a polarization state of an object surface.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Electrode 2 Oscillator 3 Current detector 4 Signal processing device 5 Indicator meter 6 Object 7 Tubes 8 and 9 Detection electrodes 10 and 11 Voltage amplifier 12 Differential amplifier 13 Signal processing devices 14 and 14 'Comb electrode 15 Signal processing device

Claims (1)

In a velocimeter for measuring the moving speed of an object, it has means for inducing dielectric polarization in the object and means for detecting the dielectric polarization state in the object, and the degree to which the dielectric polarization state moves as the object moves , A dielectric polarization velocimeter characterized by detecting the moving speed of the object by detecting it as a change in dielectric properties of the object.

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