JPH0686410A - Magnetic levitation train equipment - Google Patents
Magnetic levitation train equipmentInfo
- Publication number
- JPH0686410A JPH0686410A JP23369492A JP23369492A JPH0686410A JP H0686410 A JPH0686410 A JP H0686410A JP 23369492 A JP23369492 A JP 23369492A JP 23369492 A JP23369492 A JP 23369492A JP H0686410 A JPH0686410 A JP H0686410A
- Authority
- JP
- Japan
- Prior art keywords
- magnetic flux
- coil
- vehicle
- levitation train
- magnetic
- 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
Links
Landscapes
- Control Of Vehicles With Linear Motors And Vehicles That Are Magnetically Levitated (AREA)
Abstract
Description
【0001】[0001]
【産業上の利用分野】本発明は、車上に超電導磁石を搭
載した磁気浮上式鉄道の地上コイルの異常を検出システ
ムを備えた磁気浮上列車装置に関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic levitation train device equipped with a system for detecting an abnormality in a ground coil of a magnetic levitation railway in which a superconducting magnet is mounted on a vehicle.
【0002】[0002]
【従来の技術】図10は磁気浮上鉄道の軌道路の構成を
示すものである。上コイル5a1と下コイル5b1を、
また上コイル5i1と下コイル5j1をそれぞれ互いに
逆向きに接続した8の字型の地上コイルである浮上案内
コイル5,5を軌道の左右両側に配置し、左右の両浮上
案内コイル5,5を接続線である案内ケーブル6a1,
6b1で繋ぎ車両の浮上と案内を兼用させている。図1
1は車両の両側面に所定間隔へだてて配置された超電導
磁石4aと浮上案内コイル5との浮上走行中の位置関係
を示し、超電導磁石4aの上下中心線3は浮上案内コイ
ル5の上下中心線2からΔZだけ沈んでいる。従って超
電導磁石4aの移動に伴い、浮上案内コイル5にはその
各部分コイル5a1,5b1に鎖交する磁束の時間変化
の差に比例した電圧が誘起され、電流が流れる。列車の
浮上、案内力はその電流によって生成される磁束と車上
の超電導磁石の相互作用によって得られる。2. Description of the Related Art FIG. 10 shows the structure of a track of a magnetic levitation railway. The upper coil 5a1 and the lower coil 5b1,
In addition, levitation guide coils 5 and 5 which are eight-shaped ground coils in which the upper coil 5i1 and the lower coil 5j1 are respectively connected in opposite directions are arranged on both left and right sides of the track, and the left and right levitation guide coils 5 and 5 are connected to each other. Guide cable 6a1, which is a connection line
6b1 is used to connect the levitation and guidance of the vehicle. Figure 1
Reference numeral 1 denotes the positional relationship between the superconducting magnets 4a and the levitation guide coil 5 which are arranged at predetermined intervals on both sides of the vehicle during levitation traveling. The vertical center line 3 of the superconducting magnet 4a is the vertical center line of the levitation guide coil 5. It is sinking from 2 by ΔZ. Therefore, along with the movement of the superconducting magnet 4a, a voltage proportional to the time change of the magnetic flux interlinking the respective partial coils 5a1 and 5b1 is induced in the levitation guide coil 5, and a current flows. The levitation and guiding force of a train are obtained by the interaction between the magnetic flux generated by the current and the superconducting magnet on the train.
【0003】このような磁気浮上鉄道において、浮上案
内コイル5及び案内ケーブル6a1,6b1が断線、短
絡すると、浮上力、案内力が不足する。この結果、脈動
成分の著しい増大を生じ、乗心地上好ましくない上、台
車がガイドウェイに衝突するなどの危険も生じる。そこ
で、浮上案内コイル5及び案内ケーブル6a1,6b1
の異常検出は常時行なう必要がある。In such a magnetic levitation railway, if the levitation guide coil 5 and the guide cables 6a1 and 6b1 are broken or short-circuited, the levitation force and the guide force become insufficient. As a result, the pulsation component is significantly increased, which is not preferable in terms of riding comfort, and there is a risk that the carriage collides with the guideway. Therefore, the levitation guide coil 5 and the guide cables 6a1 and 6b1
It is necessary to always detect the abnormality of.
【0004】従来は浮上案内コイルの異常を検出するた
めに、個々の浮上案内コイルに電流を流してリアクタン
スの測定を行なっていた。Conventionally, in order to detect an abnormality of the levitation guide coil, a reactance is measured by passing a current through each levitation guide coil.
【0005】また、特開昭54−118020号公報に
はオンラインで地上コイルの異常を検出する方法が記述
されている。これによると、地上コイルに対向して、複
数のサーチコイルを、地上コイルピッチの整数倍だけ離
して車上に設置し、それらのサーチコイルの出力を比較
器に入れ、その出力の有無により異常を検出する方法、
また、一つのサーチコイルにより検出された直接の信号
と、一周期遅らせる遅延回路を介した信号とを比較器に
入れ、その出力の有無により異常を検出する方法が提案
されている。同様な公知例として特開昭54−9519
6号公報も挙げられる。Further, Japanese Laid-Open Patent Publication No. 54-11820 describes a method for detecting an abnormality in the ground coil online. According to this, a plurality of search coils facing the ground coil are placed on the vehicle at an integer multiple of the ground coil pitch, and the outputs of those search coils are put into a comparator. How to detect,
Further, a method has been proposed in which a direct signal detected by one search coil and a signal via a delay circuit that delays by one cycle are put in a comparator and an abnormality is detected by the presence or absence of the output. As a similar known example, JP-A-54-9519
No. 6 publication is also cited.
【0006】[0006]
【発明が解決しようとする課題】従来行なわれていた個
々の浮上案内コイル及び案内ケーブルに電流を流してリ
アクタンスを測定する方法は、多大の労力と時間を要
し、経済性の点で大きな欠点を有していた。また、オン
ラインで異常検出できないので運転時間外に検査しなけ
ればならなかった。The conventional method for measuring reactance by passing a current through each of the floating guide coil and the guide cable requires a great deal of labor and time, and is a major drawback in terms of economy. Had. In addition, the abnormality cannot be detected online, so the inspection had to be done outside the operating hours.
【0007】また、後者の公知例に関しては、車輪走行
の場合に超電導磁石の上下中心と浮上案内コイルの上下
中心が一致し、浮上電流が誘導されないので浮上案内コ
イルの異常を検出できないという欠点があった。また、
案内ケーブルについては、左右の平衡位置で浮上走行す
る場合、左右の浮上案内コイルの誘起電圧がバランスす
るため、電流が流れないので異常を検知できなかった。Further, the latter known example has a drawback that the upper and lower centers of the superconducting magnet and the upper and lower centers of the levitation guide coil are aligned when the wheel is traveling, and the levitation current is not induced, so that the abnormality of the levitation guide coil cannot be detected. there were. Also,
With regard to the guide cable, when the vehicle is levitated at the left and right equilibrium positions, the induced voltages of the left and right levitation guide coils are balanced, and no current flows, so an abnormality cannot be detected.
【0008】また、サーチコイルを進行方向に添って地
上コイルピッチの整数倍だけ離して設置し、その出力を
比較する場合、列車のヨーイング方向の変位に対して誤
差が生じやすいなどの問題点もあった。In addition, when the search coils are installed along the traveling direction and separated from each other by an integral multiple of the ground coil pitch and the outputs are compared, there is a problem that an error easily occurs with respect to the displacement of the train in the yawing direction. there were.
【0009】本発明は上記の点に鑑みなされたものであ
り、本発明の目的は、浮上案内コイル及び案内ケーブル
の異常を常時オンラインで検出するシステムを提供する
ことにある。また本発明の他の目的は、車輪走行中にも
浮上案内コイル及び案内ケーブルの異常を検出できるシ
ステムを提供することにある。また本発明の他の目的
は、左右の平衡位置で浮上走行している場合でも常時案
内ケーブルの異常を検出できるシステムを提供すること
にある。また本発明の他の目的は、浮上走行時における
車体のヨーイング方向の変位に対して誤差の少ない浮上
案内コイル及び案内ケーブルの異常検出システムを提供
することにある。The present invention has been made in view of the above points, and an object of the present invention is to provide a system for constantly detecting an abnormality in a levitation guide coil and a guide cable online. Another object of the present invention is to provide a system capable of detecting an abnormality in the levitation guide coil and the guide cable even while the wheels are traveling. Another object of the present invention is to provide a system capable of constantly detecting an abnormality in the guide cable even when the vehicle is levitating at the left and right equilibrium positions. Another object of the present invention is to provide an abnormality detection system for a levitation guide coil and a guide cable that has less error with respect to displacement of the vehicle body in the yawing direction during levitation.
【0010】[0010]
【課題を解決するための手段】上記目的を達成するため
に本発明は、車両の両側面に所定間隔へだてて配置され
た超電導磁石と、上下2つを互いに逆向きに接続した8
の字型コイルより成ると共に地上の軌道路の両側面に車
両進行方向に沿って所定間隔へだてて複数配置された地
上コイルと、この両側の地上コイルを互いに接続する接
続線と、車両上に設けられて該車両の左右両側で前記地
上コイルに鎖交する磁束を左右非対称にする磁束非対称
化手段と、車両上の軌道側側面に設けられ前記地上コイ
ルの作り出す磁束を検出する磁束検出手段とを備えた磁
気浮上列車装置である。In order to achieve the above object, the present invention provides a superconducting magnet arranged on both side surfaces of a vehicle with a predetermined interval, and two upper and lower parts connected in opposite directions.
A ground coil consisting of square-shaped coils and arranged on both sides of the trackway on the ground at a predetermined interval along the vehicle traveling direction, and a connecting wire connecting the ground coils on both sides to each other, and provided on the vehicle. And a magnetic flux asymmetry means for making the magnetic flux interlinking with the ground coil on both the left and right sides of the vehicle asymmetric, and a magnetic flux detection means for detecting the magnetic flux generated by the ground coil provided on the side surface on the track side of the vehicle. It is a magnetic levitation train device equipped.
【0011】前記磁気浮上列車装置おいて、磁束非対称
化手段は、前記超電導磁石とは別に車上に設けられた電
磁石、磁束非対称化用超電導磁石又は永久磁石であるも
のがよい。ここで、磁束非対称化手段としての磁石は車
両の片側に設けられ、磁束検出手段からの直接の出力と
一周期前の出力とを受けて比較する比較手段が設けられ
たものでもよい。また、磁束非対称化手段は、前記超電
導磁石を車両両側で非対称に励磁する手段であるがよ
い。また、磁束非対称化手段は、ある左右一組の超電導
磁石を非対称に励磁すると共に、他の左右一組の超電導
磁石を前記一組の励磁と左右反転非対称に励磁する手段
であるのがよい。In the magnetic levitation train device, the magnetic flux asymmetry means is preferably an electromagnet, a superconducting magnet for magnetic flux asymmetry, or a permanent magnet provided on the vehicle separately from the superconducting magnet. Here, the magnet as the magnetic flux asymmetry means may be provided on one side of the vehicle, and the comparison means for receiving and comparing the direct output from the magnetic flux detecting means and the output one cycle before may be provided. The magnetic flux asymmetry means may be a means for asymmetrically exciting the superconducting magnet on both sides of the vehicle. Further, it is preferable that the magnetic flux asymmetry means is a means for asymmetrically exciting a certain set of left and right superconducting magnets, and exciting another set of left and right superconducting magnets in asymmetrical left-right reversal with the one set of excitation.
【0012】また前記磁気浮上列車装置おいて、前記磁
束検出手段は、上下に8の字型の前記地上コイルの上下
各コイルに対向して同じく上下に個々に配置されると共
に、地上コイルの上下各コイルの発生する磁束を別々に
検出するように形成されたものがよい。ここで、前記磁
束検出手段は、サーチコイルより成るものが挙げられ
る。Further, in the magnetic levitation train device, the magnetic flux detecting means are individually arranged in the upper and lower sides of the upper and lower sides of the ground coil in the shape of a figure 8 respectively so as to face each other. It is preferable that the magnetic flux generated by each coil be separately detected. Here, the magnetic flux detecting means may include a search coil.
【0013】[0013]
【作用】磁石を車上に左右非対称に配置する等によっ
て、磁石が作る磁束が車両の左右で非対称になり、常に
地上コイル及び接続線(案内ケーブル)に電流が流れる
ので、常にオンラインで異常検出が可能である。車上の
磁束検出手段を8の字型地上コイルの上コイルと下コイ
ルにそれぞれ対向するように上下に別々に配置し、上コ
イルと下コイルの作り出す磁束をそれぞれ別々に検出し
て比較するようにしたので、磁束検出に対する車体のヨ
ーイングの影響が小さくなる。浮上推進案内用等の超電
導磁石を左右非対称に励磁し、異常を検出するので新た
に磁石を設置する必要がなくなり、車両の構造が簡単に
なる。浮上推進案内用等の超電導磁石の或左右一組の磁
石を異なる起磁力に励磁し、他の一組をその左右反転対
称に励磁したので、左右に働く電磁力が等しくなり、車
両を安定に走行させることができる。車両の両側の磁束
を左右非対称にするために新たに超電導磁石を設置すれ
ば、左右の磁束の差が大きくなり、磁束検出の信号が大
きくなる。車両の両側の磁束を左右非対称にするために
新たに永久磁石を設置すれば、異常検出システムの磁石
のメインテナンスの必要がない。磁束検出器としてサー
チコイルを用いれば、取付け、構造が簡単になり製作が
容易になる。[Function] By arranging the magnets asymmetrically on the vehicle, the magnetic flux created by the magnets becomes asymmetrical on the vehicle's left and right, and current always flows through the ground coil and the connecting wire (guide cable). Is possible. The magnetic flux detecting means on the vehicle is separately arranged vertically so as to face the upper coil and the lower coil of the figure 8 ground coil, respectively, and the magnetic fluxes produced by the upper coil and the lower coil are separately detected and compared. Therefore, the influence of yawing of the vehicle body on the magnetic flux detection is reduced. Superconducting magnets for levitation propulsion guidance are excited asymmetrically to detect anomalies, eliminating the need to install new magnets and simplifying the vehicle structure. One of the superconducting magnets for levitation propulsion magnets or one set of left and right magnets was excited with different magnetomotive forces, and the other set was excited with left-right inversion symmetry, so the electromagnetic force acting on the left and right became equal and the vehicle was stabilized. Can be run. If a new superconducting magnet is installed to make the magnetic fluxes on both sides of the vehicle asymmetrical, the difference between the magnetic fluxes on the left and right becomes large and the signal for magnetic flux detection becomes large. If a new permanent magnet is installed in order to make the magnetic flux on both sides of the vehicle asymmetrical, there is no need to maintain the magnet of the abnormality detection system. If a search coil is used as the magnetic flux detector, the mounting and structure will be simple and the manufacture will be easy.
【0014】[0014]
【実施例】以下、図に示した実施例に基づいて本発明を
詳細に説明する。図1に本発明の実施例である地上コイ
ル異常検出システムを備えた磁気浮上列車装置の断面図
を示す。軌道路の左右両側に浮上推進案内用の地上コイ
ル5,5が設置されている。地上コイル5は、上コイル
5a1と下コイル5b1及び上コイル5i1と下コイル
5j1とから成る8の字型コイルであり、案内用ケーブ
ル6a1,6b1によりヌルフラックス接続されてい
る。この全体の接続構造は図10に示したものと同様で
ある。なお他の接続構造として図9に示したものもあ
る。車両1には浮上推進案内用の超電導磁石(図示せ
ず)とは別に電磁石10を車両1の一側に設置し、また
車両1の地上コイル5側の車両側面に上下磁束検出器8
a1,8b1、その車両1の左右対称位置に上下磁束検
出器8i1,8j1を設置し、上コイル5a1,5i1
と下コイル5b1,5j1が作る磁束をそれぞれ検出す
るようになっている。The present invention will be described in detail below with reference to the embodiments shown in the drawings. FIG. 1 shows a cross-sectional view of a magnetic levitation train device equipped with a ground coil abnormality detection system according to an embodiment of the present invention. Ground coils 5 and 5 for levitation propulsion guidance are installed on both left and right sides of the trackway. The ground coil 5 is an 8-shaped coil including an upper coil 5a1 and a lower coil 5b1, and an upper coil 5i1 and a lower coil 5j1 and is null-flux connected by the guide cables 6a1 and 6b1. The entire connection structure is similar to that shown in FIG. There is also another connection structure shown in FIG. In addition to a superconducting magnet (not shown) for levitation propulsion guidance, an electromagnet 10 is installed on the vehicle 1 on one side of the vehicle 1, and a vertical magnetic flux detector 8 is provided on the vehicle side of the vehicle 1 on the ground coil 5 side.
a1 and 8b1, upper and lower magnetic flux detectors 8i1 and 8j1 are installed at symmetrical positions of the vehicle 1, and upper coils 5a1 and 5i1 are provided.
And the magnetic fluxes generated by the lower coils 5b1 and 5j1 are respectively detected.
【0015】このような車両が走行すると、電磁石10
が生成する磁束により、浮上案内コイルの下コイル5b
1に電圧が誘起される。従って車輪走行、浮上走行にか
かわらず、電気的に接続されているコイル5a1,5i
1,5j1と案内ケーブル6a1,6b1にも常に電流
が流れる。車上に設置した磁束検出器8a1,8b1は
浮上案内コイル5a1,5b1の生成する磁束を検知
し、浮上案内コイルピッチ毎に周期的な信号が検出され
る。When such a vehicle runs, the electromagnet 10
The lower coil 5b of the levitation guide coil is generated by the magnetic flux generated by
A voltage is induced at 1. Therefore, the coils 5a1 and 5i that are electrically connected to each other are electrically connected regardless of whether the vehicle is wheeled or levitated.
Current always flows through 1, 5j1 and the guide cables 6a1, 6b1. The magnetic flux detectors 8a1 and 8b1 installed on the vehicle detect the magnetic flux generated by the levitation guide coils 5a1 and 5b1, and a periodic signal is detected for each levitation guide coil pitch.
【0016】図2は浮上案内コイル5の上コイル5a3
が断線している場合の磁束検出器8a1,8b1の出力
を示す。(a)は磁束検出器8a1の出力、(b)は磁
束検出器8b1の出力を示す。コイルが断線していると
車上の磁束検出器8a1には周期的な信号が検出されな
いので、これを利用してコイルの断線検出を行なうこと
ができる。また磁束検出器8b1に検出される信号も異
常がある周期では高さが少し小さくなっている。FIG. 2 shows the upper coil 5a3 of the levitation guide coil 5.
Shows the outputs of the magnetic flux detectors 8a1 and 8b1 when there is a disconnection. (A) shows the output of the magnetic flux detector 8a1, and (b) shows the output of the magnetic flux detector 8b1. If the coil is broken, a periodic signal is not detected by the magnetic flux detector 8a1 on the vehicle, so that the coil can be detected by utilizing this. The height of the signal detected by the magnetic flux detector 8b1 is slightly smaller in the abnormal cycle.
【0017】図3は、コイル5a3,5b3,5i3,
5j3の案内ケーブル6b3が断線した場合を示し、
(a)は磁束検出器8a1の出力、(b)は磁束検出器
8b1の出力、(c)は磁束検出器8a1の出力と磁束
検出器8b1の出力の和、すなわち(a)と(b)の出
力の和を示すものである。浮上案内コイル5及び案内ケ
ーブルが共に正常の場合は、(a)と(b)の和は出力
が一定した周期的な信号になり、図3(c)の始め二周
期の様な波形になる。しかし、案内ケーブル6b3が断
線した場合は、磁束検出器8a1と8b1は逆符号で同
じ波形になり、その和は、図3(c)の3番目周期のよ
うに信号が検出されない。この零の信号から案内ケーブ
ルの異常の有無を知ることができる。FIG. 3 shows the coils 5a3, 5b3, 5i3.
The case where the guide cable 6b3 of 5j3 is broken,
(A) is the output of the magnetic flux detector 8a1, (b) is the output of the magnetic flux detector 8b1, (c) is the sum of the output of the magnetic flux detector 8a1 and the output of the magnetic flux detector 8b1, that is, (a) and (b) It shows the sum of the outputs of. When both the levitation guide coil 5 and the guide cable are normal, the sum of (a) and (b) becomes a periodic signal with a constant output, and has a waveform like the first two cycles in FIG. 3 (c). . However, when the guide cable 6b3 is broken, the magnetic flux detectors 8a1 and 8b1 have the same waveform with opposite signs, and the sum thereof is not detected as in the third cycle of FIG. 3C. Whether or not the guide cable is abnormal can be known from this zero signal.
【0018】また、磁束検出器8a1と8b1を進行方
向に対して垂直に取り付けたので、車体がヨーイング方
向に傾いても磁束検出器8a1と8b1の信号は相似的
に変化する。このため、2つの信号の和が零になる場合
は変わらないので、異常検出の誤差の心配が少ない。Further, since the magnetic flux detectors 8a1 and 8b1 are mounted perpendicularly to the traveling direction, the signals of the magnetic flux detectors 8a1 and 8b1 change similarly even if the vehicle body is tilted in the yawing direction. Therefore, when the sum of the two signals becomes zero, there is no change, and there is little concern about error in abnormality detection.
【0019】図4は本発明の他の実施例で、磁気浮上列
車の浮上推進案内用の超電導磁石4aと4iを、左右異
なる起磁力に励磁し、そのクライオスタットである外槽
7a,7iの地上コイル5側に磁束検出器8a1,8b
1,8i1,8j1を設置したものである。この場合、
車両に新たに磁石を設置する必要がないので、車両構造
が簡単になり、前述と同様に地上コイルの異常検出がで
きる。FIG. 4 shows another embodiment of the present invention, in which superconducting magnets 4a and 4i for levitation propulsion guidance of a magnetic levitation train are excited by different magnetomotive forces on the left and right, and their cryostats of outer tanks 7a and 7i are grounded. Magnetic flux detectors 8a1 and 8b on the coil 5 side
1,8i1 and 8j1 are installed. in this case,
Since it is not necessary to newly install a magnet on the vehicle, the vehicle structure is simplified and the abnormality of the ground coil can be detected as described above.
【0020】図5は本発明の他の実施例であり、超電導
磁石4a,4c,4d,4i,4j,4lを同じ起磁力
に励磁し、超電導磁石4bと4kはやや低く且つ同じ起
磁力に励磁したものである。磁束検出器は図4と同じよ
うに設置する。このような構成にすることにより、左右
の磁束が非対称になって前述と同様の効果が得られと共
に、且つ台車に働く左右力の和が同じになるので、列車
を安定に走行させることができる。FIG. 5 shows another embodiment of the present invention, in which superconducting magnets 4a, 4c, 4d, 4i, 4j, and 4l are excited to the same magnetomotive force, and superconducting magnets 4b and 4k are slightly lower and have the same magnetomotive force. It was excited. The magnetic flux detector is installed as in FIG. With such a configuration, the left and right magnetic fluxes are asymmetrical, the same effect as described above is obtained, and the sum of the left and right forces acting on the dolly is the same, so that the train can be stably run. .
【0021】また、図6は本発明の他の実施例であり、
図5と同じ構造をしたシステムに更に、全く同じ構造の
磁束検出器8a2,8b2,8i2,8j2を超電導磁
石4c,4kの外側にも配置したものである。地上コイ
ル正常時には磁束検出器8a1,8i2の信号波形は全
く同じになる。しかし、各時間においてはそれぞれのコ
イルは別の地上コイルの磁束を拾っている。このため、
地上コイルの異常の場合は異常が起こった方を検出する
検出器の信号と正常な地上コイルの信号に差ができる。
この2つの信号を比較することによっても異常検出がで
きる。従って本実施例では2重に異常検出できるので、
より信頼性の高い浮上案内コイル異常検出システムにす
ることができる。尚、磁束検出器8a1,8a2の進行
方向に沿う間隔は地上コイルピッチの整数倍である。FIG. 6 shows another embodiment of the present invention,
In addition to the system having the same structure as in FIG. 5, magnetic flux detectors 8a2, 8b2, 8i2, 8j2 having exactly the same structure are arranged outside the superconducting magnets 4c, 4k. When the ground coil is normal, the signal waveforms of the magnetic flux detectors 8a1 and 8i2 are exactly the same. However, at each time, each coil picks up the magnetic flux of another ground coil. For this reason,
In the case of an abnormality of the ground coil, there is a difference between the signal of the detector that detects the abnormal one and the signal of the normal ground coil.
Abnormality can also be detected by comparing these two signals. Therefore, in this embodiment, since the abnormality can be detected twice,
A more reliable levitation guide coil abnormality detection system can be provided. The distance along the traveling direction of the magnetic flux detectors 8a1 and 8a2 is an integral multiple of the ground coil pitch.
【0022】図7は本発明の他の実施例で、車両1の片
側だけに永久磁石11を配置し、車上には磁束検出器8
i1を一箇所だけ取り付ける。磁束検出器8i1のその
ままの出力と、遅延回路12を通した一周期すなわち1
浮上案内コイルピッチだけ前の時間の出力とを比較器1
3にいれる。浮上案内コイル5が正常な場合は、比較器
13の出力はほぼ零になるが、浮上案内コイル又は案内
ケーブルに異常が生じた場合には比較器13の出力が増
大するので、これを検出することにより浮上案内コイル
及び案内ケーブルの異常を検出できる。FIG. 7 shows another embodiment of the present invention in which a permanent magnet 11 is arranged only on one side of a vehicle 1 and a magnetic flux detector 8 is provided on the vehicle.
Attach i1 only in one place. The output of the magnetic flux detector 8i1 as it is and one cycle through the delay circuit 12, that is, 1
Comparator 1 compares the output of the levitation guide coil with the previous time.
Put in 3. When the levitation guide coil 5 is normal, the output of the comparator 13 becomes substantially zero, but when an abnormality occurs in the levitation guide coil or the guide cable, the output of the comparator 13 increases, so this is detected. Therefore, the abnormality of the levitation guide coil and the guide cable can be detected.
【0023】また、本発明のほかの実施例として、図7
において、永久磁石11の替わりに超電導石を用いた場
合も同じ効果が得られる。さらにこの場合の利点とし
て、起磁力が大きいので浮上案内コイルに流れる電流が
大きくなり、磁束検出器の出力が大きくなる。As another embodiment of the present invention, FIG.
In the above, the same effect can be obtained when a superconducting stone is used instead of the permanent magnet 11. Further, as an advantage in this case, since the magnetomotive force is large, the current flowing through the levitation guide coil is large, and the output of the magnetic flux detector is large.
【0024】図8は磁束検出器としてサーチコイル8a
1と8b1を使用した例で、サーチコイルの形状を上下
対称にし、定常浮上走行時での浮上つり合い位置でサー
チコイルの上下対称軸線と浮上案内コイル5の各上下コ
イルの中心線9a,9bとが一致する様に設置する。す
ると、浮上つり合い位置が上下しても、上コイル5a2
と磁束検出器8a1、下コイル5b2と磁束検出器8b
1は同じ位置関係にあるので、磁束検出器8a1と8b
1の信号は同じ比率で変化する。このため図3で説明し
たように、案内ケーブルが断線した場合に磁束検出器8
a1と8b1の信号の和が零になる。これは浮上つり合
い位置に依存しないので、常に異常を検出することがで
きる。FIG. 8 shows a search coil 8a as a magnetic flux detector.
In the example using 1 and 8b1, the shape of the search coil is vertically symmetrical, and the vertical symmetry axis of the search coil and the center lines 9a and 9b of the upper and lower coils of the levitation guide coil 5 at the levitation balance position during steady levitation traveling. Install so that they match. Then, even if the floating balance position moves up and down, the upper coil 5a2
And magnetic flux detector 8a1, lower coil 5b2 and magnetic flux detector 8b
Since 1 has the same positional relationship, magnetic flux detectors 8a1 and 8b
Signals of 1 change at the same rate. Therefore, as described in FIG. 3, when the guide cable is broken, the magnetic flux detector 8
The sum of the signals of a1 and 8b1 becomes zero. Since this does not depend on the floating balance position, an abnormality can always be detected.
【0025】[0025]
【発明の効果】本発明によれば、磁束非対称化手段によ
り車両の左右両側で前記地上コイルに鎖交する磁束を左
右非対称にし、常に地上コイル及び接続線(案内ケーブ
ル)に電流が流れるようにしたので、磁束検出手段によ
り前記地上コイルの作り出す磁束を検出することにより
常にオンラインで異常検出が可能である。また以下の効
果を期待することができる。 (1)車輪走行中にも浮上案内コイルの断線を確認でき
る。 (2)車輪走行中、浮上走行中を問わず案内ケーブルの
断線確認ができる。 (3)車両に新たな磁石を設置する必要がないので、車
両構造が簡単になる。 (4)車両の左右に働く力を同じにし、安定に浮上走行
できる。 (5)複数組の検出器を設けることにより、より信頼性
の高い検出システムができる。 (6)磁束検出の際、車両のヨーイングの影響を小さく
することができる。 (7)永久磁石を利用するので磁石のメインテナンスが
不要のシステムができる。 (8)超電導磁石を設置することにより、磁束検出器の
信号が大きくなる。 (9)車両の浮上つり合い位置に依存せずに異常を検出
できる。 (10)磁束検出器としてサーチコイルを用いると、取
付け、構造が簡単になり、製作が容易になる。According to the present invention, the magnetic flux asymmetry means makes the magnetic flux interlinking with the ground coil on the left and right sides of the vehicle bilaterally asymmetric, so that the current always flows through the ground coil and the connecting wire (guide cable). Therefore, by detecting the magnetic flux generated by the ground coil by the magnetic flux detecting means, it is possible to always detect the abnormality online. In addition, the following effects can be expected. (1) The disconnection of the levitation guide coil can be confirmed even while the wheels are traveling. (2) It is possible to check the disconnection of the guide cable regardless of whether the vehicle is traveling on the wheels or traveling on the surface. (3) Since it is not necessary to install a new magnet on the vehicle, the vehicle structure is simplified. (4) The forces acting on the left and right sides of the vehicle are the same, which enables stable levitation. (5) By providing a plurality of sets of detectors, a more reliable detection system can be obtained. (6) The influence of yawing of the vehicle can be reduced when the magnetic flux is detected. (7) Since a permanent magnet is used, a system that does not require magnet maintenance can be created. (8) By installing the superconducting magnet, the signal of the magnetic flux detector becomes large. (9) The abnormality can be detected without depending on the floating balance position of the vehicle. (10) When a search coil is used as the magnetic flux detector, the mounting and the structure are simple, and the manufacturing is easy.
【図1】本発明による浮上案内コイルの異常検出システ
ムを備えた磁気浮上列車装置の断面図である。FIG. 1 is a cross-sectional view of a magnetic levitation train device including a levitation guide coil abnormality detection system according to the present invention.
【図2】浮上案内コイルが断線した場合の磁束検出器の
出力を示す図である。FIG. 2 is a diagram showing an output of a magnetic flux detector when a flying guide coil is broken.
【図3】案内ケーブルが断線した場合の磁束検出器の出
力と、その和を示す図である。FIG. 3 is a diagram showing the output of the magnetic flux detector when the guide cable is broken and the sum thereof.
【図4】本発明の他の実施例を示す磁石の励磁方法とサ
ーチコイルの配置例を示す断面図である。FIG. 4 is a cross-sectional view showing a magnet exciting method and a search coil arrangement example according to another embodiment of the present invention.
【図5】本発明の他の実施例を示す磁石の励磁方法とサ
ーチコイルの配置例を示す断面図である。FIG. 5 is a sectional view showing a magnet exciting method and a search coil arrangement example according to another embodiment of the present invention.
【図6】本発明の他の実施例を示す磁石の励磁方法とサ
ーチコイルの配置例を示す見取り図である。FIG. 6 is a sketch drawing showing an example of magnet excitation method and search coil arrangement according to another embodiment of the present invention.
【図7】本発明の他の実施例を示す永久磁石の配置と異
常検出システムの概略構成を示す断面図である。FIG. 7 is a cross-sectional view showing an arrangement of permanent magnets and a schematic configuration of an abnormality detection system according to another embodiment of the present invention.
【図8】本発明の一実施例のサーチコイルの形状と配置
を示し、(a)は片側正面図、(b)は側面図である。8A and 8B show the shape and arrangement of a search coil according to an embodiment of the present invention, FIG. 8A being a front view on one side and FIG. 8B being a side view.
【図9】磁気浮上鉄道の浮上案内コイルの接続法の一例
を示した図である。FIG. 9 is a diagram showing an example of a method for connecting a levitation guide coil of a magnetic levitation railway.
【図10】磁気浮上鉄道の浮上案内コイルの接続法の一
例を示した図である。FIG. 10 is a diagram showing an example of a method for connecting a levitation guide coil of a magnetic levitation railway.
【図11】従来の磁気浮上鉄道の浮上原理を説明した図
であり、(a)は片側正面図、(b)は側面図である。11A and 11B are diagrams illustrating the levitation principle of a conventional magnetic levitation railway, in which FIG. 11A is a front view on one side and FIG. 11B is a side view.
1 車体 2 地上コイルの上下中心線 3 超電導磁石の上下中心線 4a〜4l 浮上推進案内用の超電導磁石 5 地上コイル(浮上案内コイル) 5a1,5i1 上コイル 5b1,5j1 下コイル 6a1〜6a4,6b1〜6b4 接続線(案内ケーブ
ル) 7a,7i 超電導磁石外槽 8a1,8b1,8i1,8j1 磁束検出器(サーチ
コイル) 9a,9b 上下の浮上案内コイルそれぞれの中心線 10 電磁石 11 永久磁石 12 遅延回路 13 比較器1 Body 2 Vertical centerline of ground coil 3 Vertical centerline of superconducting magnet 4a-4l Superconducting magnet for levitation propulsion guide 5 Ground coil (levitation guide coil) 5a1, 5i1 Upper coil 5b1, 5j1 Lower coil 6a1-6a4, 6b1 6b4 Connection line (guide cable) 7a, 7i Superconducting magnet outer tank 8a1, 8b1, 8i1, 8j1 Magnetic flux detector (search coil) 9a, 9b Center line of each of the upper and lower floating guide coils 10 Electromagnet 11 Permanent magnet 12 Delay circuit 13 Comparison vessel
───────────────────────────────────────────────────── フロントページの続き (72)発明者 斎藤 敏雄 茨城県日立市久慈町4026番地 株式会社日 立製作所日立研究所内 (72)発明者 小林 孝司 茨城県日立市久慈町4026番地 株式会社日 立製作所日立研究所内 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Toshio Saito 4026 Kuji Town, Hitachi City, Hitachi, Ibaraki Prefecture, Hitachi Research Institute, Ltd. Hitachi Research Laboratory
Claims (9)
れた超電導磁石と、上下2つを互いに逆向きに接続した
8の字型コイルより成ると共に地上の軌道路の両側面に
車両進行方向に沿って所定間隔へだてて複数配置された
地上コイルと、この両側の地上コイルを互いに接続する
接続線と、車両上に設けられて該車両の左右両側で前記
地上コイルに鎖交する磁束を左右非対称にする磁束非対
称化手段と、車両上の軌道側側面に設けられ前記地上コ
イルの作り出す磁束を検出する磁束検出手段とを備えた
磁気浮上列車装置。1. A superconducting magnet arranged on both sides of a vehicle at a predetermined interval, and an eight-shaped coil in which two upper and lower parts are connected in opposite directions to each other, and a vehicle traveling direction is provided on both sides of a ground track. A plurality of ground coils arranged along a predetermined interval along the ground coil, a connecting wire for connecting the ground coils on both sides to each other, and a magnetic flux interlinking with the ground coil on the left and right sides of the vehicle. A magnetic levitation train device comprising magnetic flux asymmetry means for making asymmetry and magnetic flux detection means provided on a side surface of a vehicle on a track side for detecting magnetic flux generated by the ground coil.
て、磁束非対称化手段は、前記超電導磁石とは別に車上
に設けられた電磁石であることを特徴とする磁気浮上列
車装置。2. The magnetic levitation train device according to claim 1, wherein the magnetic flux asymmetry means is an electromagnet provided on the vehicle separately from the superconducting magnet.
て、磁束非対称化手段は、前記超電導磁石とは別に車上
に設けられた磁束非対称化用超電導磁石であることを特
徴とする磁気浮上列車装置。3. The magnetic levitation train device according to claim 1, wherein the magnetic flux asymmetry means is a magnetic flux asymmetry superconducting magnet provided on the vehicle separately from the superconducting magnet. Levitating train device.
て、磁束非対称化手段は、前記超電導磁石とは別に車上
に設けられた永久磁石であることを特徴とする磁気浮上
列車装置。4. The magnetic levitation train device according to claim 1, wherein the magnetic flux asymmetry means is a permanent magnet provided on the vehicle separately from the superconducting magnet.
上列車装置おいて、磁束非対称化手段としての磁石は車
両の片側に設けられ、磁束検出手段からの直接の出力と
一周期前の出力とを受けて比較する比較手段が設けられ
たことを特徴とする磁気浮上列車装置。5. The magnetic levitation train device according to any one of claims 2 to 4, wherein the magnet as the magnetic flux asymmetry means is provided on one side of the vehicle, and one cycle before the direct output from the magnetic flux detection means. The magnetic levitation train device is characterized in that a comparison means for receiving and comparing the output of the magnetic levitation train is provided.
て、磁束非対称化手段は、前記超電導磁石を車両両側で
非対称に励磁する手段であることを特徴とする磁気浮上
列車装置。6. The magnetic levitation train device according to claim 1, wherein the magnetic flux asymmetry means is means for asymmetrically exciting the superconducting magnet on both sides of the vehicle.
て、磁束非対称化手段は、ある左右一組の超電導磁石を
非対称に励磁すると共に、他の左右一組の超電導磁石を
前記一組の励磁と左右反転非対称に励磁する手段である
ことを特徴とする磁気浮上列車装置。7. The magnetic levitation train device according to claim 1, wherein the magnetic flux asymmetry means asymmetrically excites a pair of left and right superconducting magnets and a pair of other left and right superconducting magnets. Magnetic levitation train device, characterized in that it is a means for asymmetrically exciting the left and right.
上列車装置おいて、前記磁束検出手段は、上下に8の字
型の前記地上コイルの上下各コイルに対向して同じく上
下に個々に配置されると共に、地上コイルの上下各コイ
ルの発生する磁束を別々に検出するように形成されたこ
とを特徴とする磁気浮上列車装置。8. The magnetic levitation train device according to any one of claims 1 to 7, wherein the magnetic flux detecting means is arranged above and below the ground coil in a figure 8 shape so as to face each other. A magnetic levitation train device, wherein the magnetic levitation train device is arranged individually and is formed so as to separately detect the magnetic flux generated by each coil above and below the ground coil.
て、前記磁束検出手段は、サーチコイルより成ることを
特徴とする磁気浮上列車装置。9. The magnetic levitation train device according to claim 8, wherein the magnetic flux detecting means comprises a search coil.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP23369492A JPH0686410A (en) | 1992-09-01 | 1992-09-01 | Magnetic levitation train equipment |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP23369492A JPH0686410A (en) | 1992-09-01 | 1992-09-01 | Magnetic levitation train equipment |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| JPH0686410A true JPH0686410A (en) | 1994-03-25 |
Family
ID=16959087
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| JP23369492A Pending JPH0686410A (en) | 1992-09-01 | 1992-09-01 | Magnetic levitation train equipment |
Country Status (1)
| Country | Link |
|---|---|
| JP (1) | JPH0686410A (en) |
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP2015186385A (en) * | 2014-03-25 | 2015-10-22 | 公益財団法人鉄道総合技術研究所 | System and method for measuring ground coil position of magnetic levitation type railway |
| JP2019144018A (en) * | 2018-02-16 | 2019-08-29 | 公益財団法人鉄道総合技術研究所 | Temperature estimation method |
-
1992
- 1992-09-01 JP JP23369492A patent/JPH0686410A/en active Pending
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP2015186385A (en) * | 2014-03-25 | 2015-10-22 | 公益財団法人鉄道総合技術研究所 | System and method for measuring ground coil position of magnetic levitation type railway |
| JP2019144018A (en) * | 2018-02-16 | 2019-08-29 | 公益財団法人鉄道総合技術研究所 | Temperature estimation method |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN106012716B (en) | Symmetrical permanent magnet suspension system and permanent magnetic levitation train rail system | |
| US6101952A (en) | Vehicle guidance and switching via magnetic forces | |
| CA1136721A (en) | Levitation and guide mechanism for curved track in inductive repulsion type vehicle magnetic levitation and guide system | |
| US4711182A (en) | Magnetic suspension for a vehicle | |
| CN110808678A (en) | Superconducting linear motor applied to maglev train | |
| US5652472A (en) | Magnetodynamic levitation and stabilizing selfregulating system | |
| WO2019143469A1 (en) | Permanent magnet magnet maglev using passive, lo-frequency electromagnetic stabilization | |
| JPH0686410A (en) | Magnetic levitation train equipment | |
| US3951075A (en) | Electro dynamic suspension and guidance system for a moving vehicle | |
| CN103963787B (en) | One magnetic suspension grade separation transportation system | |
| US3952668A (en) | Electrodynamic suspension guidance system | |
| JPH09261804A (en) | Magnetic levitation system | |
| JP3310124B2 (en) | Abnormal ground coil detector for magnetic levitation train equipment | |
| JPH05281281A (en) | Device for detecting abnormality of ground coil of superconductive magnetic levitation type railroad | |
| JPH0669245B2 (en) | Combined levitation and propulsion system for magnetic levitation | |
| KR930005823A (en) | Linear motor-borne field magnets bogie | |
| JPH10125526A (en) | Maglev train with torsional oscillation detecting coil for superconducting magnet | |
| JPH11215615A (en) | Superconducting magnetically levitated running car | |
| Murai et al. | Test run of combined propulsion, levitation and guidance system at Miyazaki test track | |
| CN109631816B (en) | Medium-low speed magnetic levitation F-shaped rail displacement detection device | |
| SU1119902A1 (en) | Arrangement for detecting an object moving along rails | |
| JPH07249515A (en) | Instrument for detecting and measuring magnetic neutral conductor of floating coil | |
| JPH02146908A (en) | Connection of guide/magnetic levitation coil | |
| JPH06327103A (en) | Magnetic levitation railroad | |
| JPH07298417A (en) | Magnetic levitation vehicle |