Elektromagnetische Betaetigungsvorrichtung mit Rueckkopplung

Elektromagnetische Betaetigungsvorrichtung mit Rueckkopplung

841,199. Magnetic amplifiers. SPERRY RAND CORPORATION. Sept. 10, 1956 [Sept. 26, 1955], No. 27633/56. Class 40 (9). [Also in Group XL (c)] In a circuit for operating an electromechanical device such as a relay 10, a signal 14 is applied to an amplifier 13 energized from a source of variable potentia...

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1. Verfasser: BONN THEODORE HERTZ
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Sprache:ger
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BASIC ELECTRIC ELEMENTS
ELECTRIC SWITCHES
ELECTRICITY
EMERGENCY PROTECTIVE DEVICES
RELAYS
SELECTORS
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description 841,199. Magnetic amplifiers. SPERRY RAND CORPORATION. Sept. 10, 1956 [Sept. 26, 1955], No. 27633/56. Class 40 (9). [Also in Group XL (c)] In a circuit for operating an electromechanical device such as a relay 10, a signal 14 is applied to an amplifier 13 energized from a source of variable potential V, to produce a flux in the magnetic core 10, a coupling circuit 12 being provided to apply feed-back to the amplifier. The amplifier 13 may include thermionic discharge tubes of the high vacuum or gas type, transistors (see Group XL (c)), or a magnetic amplifier and a further feed-back may be effected over resistor R 1 . While the flux is building up in core 10 a voltage is generated in coil 12 and is effective to increase the drive applied to the amplifier 13. As soon as a steady state has been reached the feed-back decreases so that the holding current of the relay is less than the initial actuating current. The relay may be held operated over an auxiliary contact. To prevent a negative-going signal being fed back to the amplifier 13 due to the fall in flux from the actuating to holding valve, a diode may be included in the feed-back path, Fig. 2 (not shown). When the circuit is operated without a diode in the feed-back path the decrease in flux may be such as to generate a sufficiently large voltage in coil 12 for the amplifier to provide insufficient current to keep the relay 10 operated so that it releases and the cycle subsequently commences again. In a modification, Fig. 4, the input signal is applied at terminal 50 to windings 44, 45 on magnetic cores 40, 41, energized from an A.C. supply over diodes D 3 , D 4 . The output from windings 42, 43 is applied to a winding 48 on a device such as a relay having a magnetic core 49. A feed-back voltage is generated across coil 51 and applied over a diode to the input circuit. As an alternative arrangement a further winding may be added to each of the cores 40, 41 to which the voltage from the feed-back winding 51 is applied.
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[Also in Group XL (c)] In a circuit for operating an electromechanical device such as a relay 10, a signal 14 is applied to an amplifier 13 energized from a source of variable potential V, to produce a flux in the magnetic core 10, a coupling circuit 12 being provided to apply feed-back to the amplifier. The amplifier 13 may include thermionic discharge tubes of the high vacuum or gas type, transistors (see Group XL (c)), or a magnetic amplifier and a further feed-back may be effected over resistor R 1 . While the flux is building up in core 10 a voltage is generated in coil 12 and is effective to increase the drive applied to the amplifier 13. As soon as a steady state has been reached the feed-back decreases so that the holding current of the relay is less than the initial actuating current. The relay may be held operated over an auxiliary contact. To prevent a negative-going signal being fed back to the amplifier 13 due to the fall in flux from the actuating to holding valve, a diode may be included in the feed-back path, Fig. 2 (not shown). When the circuit is operated without a diode in the feed-back path the decrease in flux may be such as to generate a sufficiently large voltage in coil 12 for the amplifier to provide insufficient current to keep the relay 10 operated so that it releases and the cycle subsequently commences again. In a modification, Fig. 4, the input signal is applied at terminal 50 to windings 44, 45 on magnetic cores 40, 41, energized from an A.C. supply over diodes D 3 , D 4 . The output from windings 42, 43 is applied to a winding 48 on a device such as a relay having a magnetic core 49. A feed-back voltage is generated across coil 51 and applied over a diode to the input circuit. 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Magnetic amplifiers. SPERRY RAND CORPORATION. Sept. 10, 1956 [Sept. 26, 1955], No. 27633/56. Class 40 (9). [Also in Group XL (c)] In a circuit for operating an electromechanical device such as a relay 10, a signal 14 is applied to an amplifier 13 energized from a source of variable potential V, to produce a flux in the magnetic core 10, a coupling circuit 12 being provided to apply feed-back to the amplifier. The amplifier 13 may include thermionic discharge tubes of the high vacuum or gas type, transistors (see Group XL (c)), or a magnetic amplifier and a further feed-back may be effected over resistor R 1 . While the flux is building up in core 10 a voltage is generated in coil 12 and is effective to increase the drive applied to the amplifier 13. As soon as a steady state has been reached the feed-back decreases so that the holding current of the relay is less than the initial actuating current. The relay may be held operated over an auxiliary contact. To prevent a negative-going signal being fed back to the amplifier 13 due to the fall in flux from the actuating to holding valve, a diode may be included in the feed-back path, Fig. 2 (not shown). When the circuit is operated without a diode in the feed-back path the decrease in flux may be such as to generate a sufficiently large voltage in coil 12 for the amplifier to provide insufficient current to keep the relay 10 operated so that it releases and the cycle subsequently commences again. In a modification, Fig. 4, the input signal is applied at terminal 50 to windings 44, 45 on magnetic cores 40, 41, energized from an A.C. supply over diodes D 3 , D 4 . The output from windings 42, 43 is applied to a winding 48 on a device such as a relay having a magnetic core 49. A feed-back voltage is generated across coil 51 and applied over a diode to the input circuit. As an alternative arrangement a further winding may be added to each of the cores 40, 41 to which the voltage from the feed-back winding 51 is applied.</description><subject>BASIC ELECTRIC ELEMENTS</subject><subject>ELECTRIC SWITCHES</subject><subject>ELECTRICITY</subject><subject>EMERGENCY PROTECTIVE DEVICES</subject><subject>RELAYS</subject><subject>SELECTORS</subject><fulltext>true</fulltext><rsrctype>patent</rsrctype><creationdate>1960</creationdate><recordtype>patent</recordtype><sourceid>EVB</sourceid><recordid>eNrjZLBxzUnNLinKz01Mz0stySxOzkhVcEotSQSy00vz0ovL8ouKMpMzSoBshdzMEoWg0tTk7Oz8goIcoAgPA2taYk5xKi-U5maQd3MNcfbQTS3Ij08tLkhMTgUaGu_iamhgYWxibOpkTFgFAM14MFA</recordid><startdate>19600615</startdate><enddate>19600615</enddate><creator>BONN THEODORE HERTZ</creator><scope>EVB</scope></search><sort><creationdate>19600615</creationdate><title>Elektromagnetische Betaetigungsvorrichtung mit Rueckkopplung</title><author>BONN THEODORE HERTZ</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-epo_espacenet_DE1083435B3</frbrgroupid><rsrctype>patents</rsrctype><prefilter>patents</prefilter><language>ger</language><creationdate>1960</creationdate><topic>BASIC ELECTRIC ELEMENTS</topic><topic>ELECTRIC SWITCHES</topic><topic>ELECTRICITY</topic><topic>EMERGENCY PROTECTIVE DEVICES</topic><topic>RELAYS</topic><topic>SELECTORS</topic><toplevel>online_resources</toplevel><creatorcontrib>BONN THEODORE HERTZ</creatorcontrib><collection>esp@cenet</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>BONN THEODORE HERTZ</au><format>patent</format><genre>patent</genre><ristype>GEN</ristype><title>Elektromagnetische Betaetigungsvorrichtung mit Rueckkopplung</title><date>1960-06-15</date><risdate>1960</risdate><abstract>841,199. Magnetic amplifiers. SPERRY RAND CORPORATION. Sept. 10, 1956 [Sept. 26, 1955], No. 27633/56. Class 40 (9). [Also in Group XL (c)] In a circuit for operating an electromechanical device such as a relay 10, a signal 14 is applied to an amplifier 13 energized from a source of variable potential V, to produce a flux in the magnetic core 10, a coupling circuit 12 being provided to apply feed-back to the amplifier. The amplifier 13 may include thermionic discharge tubes of the high vacuum or gas type, transistors (see Group XL (c)), or a magnetic amplifier and a further feed-back may be effected over resistor R 1 . While the flux is building up in core 10 a voltage is generated in coil 12 and is effective to increase the drive applied to the amplifier 13. As soon as a steady state has been reached the feed-back decreases so that the holding current of the relay is less than the initial actuating current. The relay may be held operated over an auxiliary contact. To prevent a negative-going signal being fed back to the amplifier 13 due to the fall in flux from the actuating to holding valve, a diode may be included in the feed-back path, Fig. 2 (not shown). When the circuit is operated without a diode in the feed-back path the decrease in flux may be such as to generate a sufficiently large voltage in coil 12 for the amplifier to provide insufficient current to keep the relay 10 operated so that it releases and the cycle subsequently commences again. In a modification, Fig. 4, the input signal is applied at terminal 50 to windings 44, 45 on magnetic cores 40, 41, energized from an A.C. supply over diodes D 3 , D 4 . The output from windings 42, 43 is applied to a winding 48 on a device such as a relay having a magnetic core 49. A feed-back voltage is generated across coil 51 and applied over a diode to the input circuit. As an alternative arrangement a further winding may be added to each of the cores 40, 41 to which the voltage from the feed-back winding 51 is applied.</abstract><oa>free_for_read</oa></addata></record>
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subjects BASIC ELECTRIC ELEMENTS
ELECTRIC SWITCHES
ELECTRICITY
EMERGENCY PROTECTIVE DEVICES
RELAYS
SELECTORS
title Elektromagnetische Betaetigungsvorrichtung mit Rueckkopplung
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