• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:

    公开号:SU841610A3
    申请号:SU762409192
    申请日:1976-10-07
    公开日:1981-06-23
    发明作者:Бувро Рене;Раймон Нарбэ-Жореги Жан
    申请人:Томсон-Цсф (Фирма);
    IPC主号:
    专利说明:

    1 The invention relates to electrical measuring technology and can be used to obtain information about the location, direction and speed of vehicles on highways. Magnetic sensors are known. Acquisition of information about the coordinates of a moving vehicle They contain at least one radiating winding, upon excitation of which a magnetic field is formed around the sensor, perceived by one or several receiving windings located on the sensor. A metallic mass or a vehicle penetrates this field and perturbs it, and this disturbance is detected by the sensor receiving windings. However, the known sensors have a number of disadvantages due to the fact that the receiving coils are collinear and weakly interconnected, which requires a relatively large physical dimensions of the sensor. In addition, in the absence of perturbing conductive masses, it is necessary to make an exact mechanical adjustment of the relative position of the three coils, but such pre-adjustment may be disturbed due to the surrounding circumference on the road. The purpose of the invention is the yMeHsiiieirtie dimensions and increase the sensitivity of the sensor. This goal is achieved by the fact that in an electromagnetic sensor sensitive to changes in the magnetic field that it creates, containing at least one radiating winding, two receiving windings and a data processing unit, receiving windings, the coupling coefficient between which,. at least an order of magnitude higher than their ratio to the radiating winding, they are located on both sides of the axis of the radiating winding, with their common axis perpendicular to the axis of the radiating winding. Radiating and receiving windings in the sensor are located on a ferromagnetic plate, and an electrostatic screen is located around the receiving windings. In addition, each receiving winding is connected to the first input of the corresponding amplifier, the second input of which is connected respectively to the first and second outputs of the phase comparator, one input of which is connected through the first converter to the radiating winding, another input through the second converter to the outputs of amplifiers, and the third and the fourth outputs are connected to the processing unit via logical units.
    FIG. 1 shows the structure of the proposed device; in fig. 2 - functional sensor circuit.
    The sensor contains the radiating winding 1 (Fig. 1), the receiving windings 2 and 3, located at a distance of several decimeters from the winding 1. The windings 1-3 are connected to the processing unit 4 with the output 5 and mounted on the ferromagnetic plate 6, and the BOKpyi windings 2 and 3, an electrostatic shield 7 is located. Sensor axis 8 is located along the road in its middle. The common axis 9 of the windings 2 and 3 is perpendicular to the axis 8, which coincides with the axis of the winding 1.
    The windings 2 and 3 are connected respectively to the inputs of the receiving amplifiers 10 and 11 (Fig. 2), the outputs of which are combined and connected to a conversion circuit 12 that converts a sinusoidal voltage to a rectangular one. The radiating winding 1 is connected to a conversion circuit 13 which converts the -sinusoidal voltage to a rectangular, which is a reference voltage, as a result of which they become almost completely insensitive to g (5 additional interference that may be superimposed on the sinusoidal signal.
    Conversion circuits 12 and 13 are connected to phase comparator 14, having two outputs 15 and 16, connected respectively to amplifiers 11, and two other outputs 17 and 18, from which information about the object detected by the sensor is taken, depending on its position but the sensor axis is fed to logic circuits 19 and 20.
    Through amplifier 21, circuit 22 supplies power to the radiating winding 1 at a frequency of 50 kHz, KS chain 23 and 24 extinguishes rapid signal changes.
    The device works as follows.
    As a result of the winding 1 being fed, a sinusoidal voltage across the circuit 22 through the amplifier 21, a current flows in it, creating a magnetic field around the winding that induces currents in the receiving windings 2 and 3 located on both sides of the radiating winding axis and associated with it. In the absence of a metallic mass perturbing the magnetic field, there is a resulting signal on the receiving windings 2 and 3, the phase of which coincides with the phase of the reference signal, which forms
    circuit 13. Under these conditions, it is necessary that at the output of the receiving windings there is a nonzero resultant, the value of which could be processed in the trimming circuit.
    The adjustment is carried out automatically and makes it possible to compensate for the adverse effects on the system from the environment, as well as the changes associated with the slow drift characteristics of the components of the system. To make this adjustment, the signals of the receive windings 2 and 3 are separately amplified respectively in amplifiers 10 and 11, which have separate gain control, and then are combined in a string 23 at the output of these amplifiers. In the chain 23, a vector signal is obtained, which is the result of the addition of amplified ALAB, the phase of which varies, therefore, depending on the imbalance of the gain factors of the amplifiers with respect to the reference phase.
    A phase comparator 14, to which, on the one hand, the resulting signal and, on the other hand, the reference signal, after converting them to square signals, respectively, in conversion circuits 12 and 13, determines the phase difference of the two signals and outputs a voltage from outputs 15 and 16 to one or the other of the amplifiers 10 and 11, depending on the sign of this difference, to change their gain factors so that the resulting signal is in phase with the reference signal. In this case, the phase comparison of the signals is carried out in digital form, and the phase matching operation is carried out relatively slowly due to the fact that the automatic gain control of the amplifiers 11 and 12 has a long response time.
    Thus, the system cannot immediately respond to the occurrence of rapid phase mismatches caused by the appearance of a metallic mass or vehicle in the magnetic field of the radiating winding, resulting in a voltage at one of the outlets 17 or 18 of the phase comparator 14, indicating the presence of stopped vehicle in the immediate vicinity of the sensor, if this voltage is constant, or for the presence of a moving vehicle, if this voltage is in the form of a pulse . The output at which the voltage appears indicates the position of the vehicle relative to the axis of the sensor or the direction of its movement.
    Typically, the sensor is placed under the roadway along the axis of the controlled road, and its relatively
    The small dimensions that make up
    lina about 1 m make
    its application is quite simple.
    n can also be installed on
    the edge of the roadway without distortion, nor the information issued to them, the claims
    1. Electromagnetic sensor, sensitive to changes in the magnetic field that it creates, containing,. at least one radiating winding, two receiving windings and a data processing unit, distinguished by the fact that, in order to reduce its dimensions and increase its sensitivity, the receiving windings, the coupling coefficient between which, at least, order of magnitude higher than the ratio of their relationship with the radiating winding, are located on both sides of the axis of the radiating winding, with their total 20 axis perpendicular to the axis of the radiating winding.
    2, Electromagnetic sensor by
    Claim 1, characterized in that the radiating and receiving windings are placed on a ferromagnetic plate, and an electrostatic screen is located around the receiving windings.
    3. Electromagnetic sensor in PP. 1 and 2, characterized in that each receiving winding is connected to the first input of the corresponding amplifier, the second inputs of which are connected respectively to the first and second outputs of the phase comparator. One INPUT of which is connected via the first converter
    with the emitter coil, the other input through the second transducer with the outputs of the amplifiers, and the third and fourth outputs through the logical blocks are connected to the processing unit.
    Sources of information taken into account in the examination
    1. US patent No. 3,911,389, cl. 340/38 L, 1975.
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    2
    权利要求:
    Claims (3)
    [1]
    Claim
    1. An electromagnetic sensor sensitive to a change in the magnetic field that it creates, containing * at least one radiating winding, two receiving windings and a data processing unit, characterized in that, in order to reduce its size and increase sensitivity, receiving windings, the coupling coefficient between which is at least an order of magnitude higher than the coefficient of their coupling with the radiating winding, are located on both sides of the axis of the radiating winding, their common 20 axis being perpendicular to the axis of the radiating winding.
    [2]
    2. The electromagnetic sensor according to
    π. 1, characterized in that the emitting and receiving windings are located on the ferromagnetic plate, and around the receiving windings there is an electrostatic screen.
    [3]
    3. The electromagnetic sensor according to paragraphs. 1 and 2, characterized in that each receiving winding is connected to the first input of the corresponding amplifier, the second inputs of which are connected respectively to the first and second outputs of the phase comparator, one input of which is connected through the first converter to the radiating winding, and the other input through the second converter to the outputs of the amplifiers , and the third and fourth outputs through logical blocks are connected to the data processing unit.
    类似技术:
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    GB1300219A|1972-12-20|Electromagnetic transducer
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    SU656012A1|1979-04-05|Electromagnetic metal locator
    US2983865A|1961-05-09|Mine detector
    ES428162A1|1976-07-16|Vehicle-actuated device
    SU1048412A2|1983-10-15|Solenoid touch-free pickup for checking position and displacement of lengthy body having magnetic irregularities
    US2665499A|1954-01-12|Pendulum and acceleration compensation apparatus
    SU666597A1|1979-06-05|Magnetic aerial-induction-type cable detector
    RU1803350C|1993-03-23|Micrometeoroid detector
    SU590621A1|1978-01-30|Pressure transmitter
    同族专利:
    公开号 | 公开日
    DE2644928A1|1977-04-14|
    BE846942A|1977-04-05|
    JPS5246834A|1977-04-14|
    IT1074710B|1985-04-20|
    JPS5836753B2|1983-08-11|
    ATA742176A|1980-07-15|
    BR7606685A|1977-11-16|
    US4075553A|1978-02-21|
    AT361338B|1981-03-10|
    SE7611003L|1977-04-08|
    NL7611018A|1977-04-13|
    AU1842876A|1978-04-13|
    DE2644928B2|1978-11-30|
    DE2644928C3|1979-08-09|
    AU501542B2|1979-06-21|
    NO141488B|1979-12-10|
    SE412478B|1980-03-03|
    ES452183A1|1977-10-16|
    FR2327556A1|1977-05-06|
    NO141488C|1980-03-19|
    GB1551998A|1979-09-05|
    NO763417L|1977-04-13|
    FR2327556B1|1981-01-23|
    CH613518A5|1979-09-28|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE6963C|A. BANNASCH, Färbereibesitzer, in Brieg bei Breslau|Washing machine|
    US661520A|1897-08-02|1900-11-13|Caryl D Haskins|Automatic steering device for torpedoes.|
    US2160356A|1937-09-28|1939-05-30|Harry A Fore|Geophysical instrument|
    US2807777A|1945-05-24|1957-09-24|Doll Henri-Georges|Coil assembly for geophysical prospecting|
    US3509469A|1967-05-17|1970-04-28|Nasa|Position sensing device employing misaligned magnetic field generating and detecting apparatus|
    US3996510A|1975-03-12|1976-12-07|General Electric Company|Shielding arrangement for sensing the proximity of a metallic object|FR2371675B1|1976-11-19|1982-12-31|Thomson Csf|
    FR2498347B2|1981-01-16|1984-01-13|Thomson Csf|
    GB2102127B|1981-05-07|1985-03-20|Mccormick Lab Inc|Determining the position of a device inside biological tissue|
    US4455529A|1981-06-08|1984-06-19|Schlumberger Technology Corporation|Digital induction logging tool including means for measuring phase quadrature components in a phase sensitive detector|
    GB2158240B|1984-04-26|1988-01-27|Standard Telephones Cables Ltd|A null-balanced proximity sensor|
    US4818936A|1985-02-15|1989-04-04|The Broken Hill Proprietary Company Limited|Method and apparatus for identifying and classifying steels|
    US4968979A|1985-04-19|1990-11-06|Omron Tateisi Electronics Co.|Vehicle detecting system|
    JPS61245299A|1985-04-22|1986-10-31|Omron Tateisi Electronics Co|Vehicle sensor with function of communication between vehicles on road|
    EP0222028B1|1985-11-02|1988-12-28|Vallon GmbH|Metal detector for detecting metal objects|
    JPS63150686A|1986-12-15|1988-06-23|Nippon Signal Co Ltd:The|Metal detector|
    IT1260208B|1992-11-19|1996-04-02|Giovanni Manneschi|PERFECTED METAL DETECTOR|
    ES2070702B1|1992-12-31|1997-03-01|Alcatel Standard Electrica|MAGNETIC FIELD SENSOR DEVICE.|
    FR2828286B1|2001-08-02|2003-11-21|Siemens Automotive Sa|DIAGNOSTIC DEVICE FOR AN ANTENNA|
    US8314608B2|2010-06-30|2012-11-20|Hall David R|Method of determining distance to a ferrous material|
    WO2019186671A1|2018-03-27|2019-10-03|株式会社京三製作所|Detection system|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    FR7530695A|FR2327556B1|1975-10-07|1975-10-07|
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