Search Images Maps Play YouTube News Gmail Drive More »
Sign in
Screen reader users: click this link for accessible mode. Accessible mode has the same essential features but works better with your reader.

Patents

  1. Advanced Patent Search
Publication numberUS3728654 A
Publication typeGrant
Publication dateApr 17, 1973
Filing dateSep 20, 1971
Priority dateSep 26, 1970
Publication numberUS 3728654 A, US 3728654A, US-A-3728654, US3728654 A, US3728654A
InventorsK Tada
Original AssigneeHosiden Electronics Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Solenoid operated plunger device
US 3728654 A
Abstract
Within a cylindrical yoke of magnetic material are disposed first and second axially spaced coils in concentric relationship therewith. A first permanent magnet is arranged inside the first coil in abutting relation with one of the end plates of the yoke, and a second permanent magnet is arranged inside the second coil in abutting relation with the other end plate. A movable magnetic body is located inside the first and second coils for movement between the first and second permanent magnets. A plunger extends from one end of the movable magnetic body through a permanent magnet and the yoke to the exterior thereof. A current pulse supplied to the first coil causes the movable body to be attracted to the first permanent magnet, and a current pulse supplied to the second coil causes the movable body to be attracted to the second permanent magnet.
Images(2)
Previous page
Next page
Claims  available in
Description  (OCR text may contain errors)

United States Patent [1 1 Tada [45 Apr. 17, 1973 [54] SOLENOID OPERATED PLUNGER DEVICE [75] Inventor: Kiichiro Tada, Yao-shi, Osaka,

Japan [73] Assignee: Hoshidenki-Seizlo Kabushiki-Kaisha,

Yao-shi, Osaka-fu, Japan [22] Filed: Sept. 20, 1971 [21] Appl. No.: 181,727

[30] Foreign Application Priority Data Sept. 26, 1970 Japan ..45/95447 [52] US. Cl ..335/234, 335/254 [51] Int. Cl. ..H0lf 7/08 [58] Field of Search ..335/229, 230, 234, 335/253, 254

[56] References Cited UNITED STATES PATENTS 3,460,081 8/1969 Tillman ..335/234 2,915,681 12/1959 Troy 335/229 X 3,040,217 6/1962 Conrad ..335/234 3,126,501 3/1964 Flora ..335/254 X Primary ExaminerGeorge Harris Att0meyWillia.m D. Hall et a1.

[ 5 7 ABSTRACT Within a cylindrical yoke of magnetic material are disposed first and second axially spaced coils in concentric relationship therewith. A first permanent magnet is arranged inside the first coil in abutting relation with one of the end plates of the yoke, and a second permanent magnet is arranged inside the second coil in abutting relation with the other end plate. A movable magnetic body is located inside the first and second coils for movement between the first and second permanent magnets. A plunger extends from one end of the movable magnetic body through a permanent magnet and the yoke to the exterior thereof. A current pulse supplied to the first coil causes the movable body to be attracted to the first permanent magnet, and a current pulse supplied to the second coil causes the movable body to be attracted to the second permanent magnet.

6 Claims, 6 Drawing Figures SOLENOID OPERATED PLUNGER DEVICE BACKGROUND OF THE INVENTION The invention relates to a solenoid operated plunger device in which current flow through a solenoid coil controls the movement of a plunger, and in particular, to such device which maintains the operated position of the plunger even after the current flow has been interrupted.

Solenoid operated plunger devices of the kind described are known which have the capability to maintain the device in its operated position after the current applied for its operation has been interrupted. However, such prior art devices of holding type either required a relatively high drive current or required a complex driving circuit because of the necessity to supply two currents separately, i.e. one to demagnetize the magnet for holding the device in one state, and the other to magnetize the magnet for holding the device in the other state.

Therefore, it is an object of the invention to provide a solenoid operated plunger device of holding type which operates with a low drive current and incorporates a simple drive circuit.

It is another object of the invention to provide a solenoid operated plunger device of the holding type in which magnetic circuits for producing attraction to move a plunger are common to those for magnetizing and demagnetizing first and second permanent magnets which hold the plunger in a first operating position and in a second operating position, respectively.

SUMMARY OF THE INVENTION In accordance with the invention, first and second permanent magnets are arranged on opposite sides of, and spaced from, a movable magnetic body in alignment with the direction of movement thereof. A magnetic yoke is provided to connect these permanent magnets to each other. Along the outer periphery of the movable body and magnets are disposed solenoid coils, each extending across one or the other of the permanent magnet and the movable body. When a current is passed through one of the coils, there is formed a magnetic circuit which extends through the movable body, one of the permanent magnets, the magnetic yoke and the other permanent magnet. The magnetizing force of the magnetic circuit thus formed magnetizes one of the magnets to cause it to attract the movable magnetic body, and also demagnetizes the other magnet. The movable body moves toward the magnetized magnet and is held in position by the latter.

Above and other objects, features and advantages of the invention will become more apparent from the following description of embodiments thereof when taken with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. I is a diagrammatic section of an embodiment of the solenoid operated plunger device according to the invention,

FIG. 2 is a circuit diagram of an energizing circuit for the coils shown in FIG. 1,

FIGS. 3A to 3C are similar views to FIG. 1, but illustrating the device in several different positions, and

FIG. 4 is a diagrammatic section of another embodiment of the solenoid operated plunger device according to the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to FIG. I, there is shown a movable magnetic body 1 or core which is arranged for movement lengthwise or horizontally as viewed in the drawing. First and second permanent magnets 2 and 3 are disposed spaced from the movable body 1 on opposite sides thereof and in alignment with the direction of movement thereof. A magnetic yoke 5 is provided to connect the outer sides of the permanent magnets 2 and 3. Within the yoke 5 are disposed a pair of coils 6 and 7, these coils being wound around and extending between the movable body 1 and the magnet 2 or 3, respectively. Thus the magnetic yoke 5 is in the form of a hollow cylinder with its opposite ends closed, and a bobbin 20 is arranged within the yoke 5. The bobbin 20 is formed of a synthetic resin material and is integrally formed with flanges 21, 22 and 23 at its opposite ends and at its median. The bobbin 20 has its opposite ends in contact with end plates 5a and 5b of the magnetic yoke 5 and has its flanges 21, 22 and 23 peripherally extending close to the inner periphery of the yoke 5. The coil 6 is wound on the bobbin 20 intermediate the flanges 21 and 23, and the coil 7 is wound on the bobbin 20 intermediate the flanges 22 and 23. Fitted into the opposite ends of the bobbin 20 are the magnets 2 and 3 with a thin-walled cylindrical spacer 24 interposed between the bobbin and the magnets and extending between the magnets 2 and 3 to maintain a given spacing between them. The movable magnetic body 1 of solid cylindrical form is concentrically disposed within the spacer 24 for movement between the magnets 2 and 3.

In the example shown, plungers 8 and 9 of nonmagnetic material extend from the opposite ends of the movable body 1 and project through the magnets 2, 3 and the yoke 5 externally thereof. The direction of winding of the coils 6 and 7 and the polarity of drive currents supplied to these coils are chosen such that the magnetizing force resulting from excitation of either coil 6 and 7 provide opposite magnetic excitations of the magnets 2 and 3. To this end, the drivecircuit comprises a rectifier circuit 11 connected to commercial power supply terminals 10, for example, as shown in FIG. 2, with the output terminals of the rectifier circuit being connected across the coils 6 and 7 through switches 12 and 13, respectively. In the arrangement shown, it is assumed that the both coils 6 and 7 are wound in the same direction, and hence they are connected to the opposite polarities of the supply current as shown. The magnets 2 and 3 are formed of a magnetic material which can relatively easily be magnetized and demagnetized.

In operation, assuming that the switch 13 is closed to energize the coil 7 in the position illustrated in FIG. 1, the magnet 3 will be magnetized in a direction such that an end plate 5b of the yoke 5 will be an N-pole, and the magnetizing force furnished by the coil 7 will cause the movable magnetic body 1 to be attracted to the magnet 3, thereby assuming its position shown in FIG. 3A. At this time, the magnetic flux passes through a magnetic circuit, indicated by dotted lines 26, which includes the Y thereto.

If then it is desired to move the movable body 1 toward the magnet 2, it is only necessary to close the switch 12. Then the coil 6 produces a magnetizing force which will cause the magnet 2 to be magnetized so that the end plate a of the yoke 5 will be an N-pole, or in a direction opposite to that of previous magnetization of the magnet 3. Now the magnetizing force is effective to magnetize the movable body 1 with a polarity opposite to that of previous magnetization of the magnet 3, so that the movable body 1 is repelled by the latter, which is demagnetized. The force of attraction by the magnet 2 acts simultaneously to cause the movable body 1 to be attracted to the magnet 2, thereby causing it to assume a second position shown in FIG. 3C. The magnetic flux passes through a magnetic circuit indicated by dotted lines 27, which again includes the yoke 5, the both magnets 2 and 3, and the movable body 1. A similar process may be repeated by closing the switch 13 again, which will cause the magnet 2 to be demagnetized and the magnet 3 to be magnetized as shown in FIG. 3A, thereby achieving a position of the movable body 1 as shown in FIG. 3A.

Thus, the solenoid operated plunger device of the invention enables a movable magnetic body to be moved from one position to another by a momentary application of current upon operation of the device, and still holds the movable body in position which it now assumed, subsequent to interruption of the current, thus avoiding further power dissipation. When a drive current is supplied to one of the coils, the resulting magnetizing force causes a magnetization of one of the magnets and also an attraction thereto of the movable body, but immediately before that, causes a demagnetization of the other magnet which has been retaining the movable body. Thus such magnetization, attraction and demagnetization are all provided by the magnetizing force occurring in the same magnetic circuit which includes the movable body l, both magnets 2 and 3 and magnetic yoke 5, and this minimizes the drive current required. The drive circuit does not require separate coils for demagnetization and magnetization, respectively, and hence is extremely simple. In addition to maintaining a given spacing between the magnets 2 and 3, the spacer 24 is also effective to prevent abrasion which may otherwise be caused to surrounding parts by sliding motion of the movable body 1.

While in the above description plungers have been provided on opposite sides of the movable body, one of the plungers may be omitted as shown in FIG. 4 in which corresponding parts are designated by like numerals.

A practical example was constructed according to the embodiment of FIG. 1. Movable body 1 comprised a piece of soft iron of 16.5 mm in diameter and 36 mm long. Magnets 2 and 3 comprised Alnico with an outer diameter of 18.0 mm, an inner diameter of 4 mm and an axial thickness of mm. Magnetic yoke 5 was formed of iron material designated as SS 34 in 118 (Japan Industrial Standard), measuring 40.0 mm and 36.0 mm in outer and inner diameters, respectively, 65.0 mm long and having a thickness of 3.0 mm for end plates 5a and 5b. Coils 6 and 7 each comprised 2,200 turns of wire of 0.13 mm 4) and had a dc. resistance of 74 ohms, plungers 8 and 9 were each a copper rod of 3 mm in diameter. Bobbin 20 was formed of polyacetal synthetic resin in the form of a hollow cylinder having an outer and inner diameter of 20.2 mm and 18.0 mm, respectively, integrally formed with flanges 21, 22 and 23. Spacer 24 was a cylindrical copper pipe having an inner diameter of 17.0 mm, an outer diameter of 18.0 mm and a length of 39.0 mm. When one of the switches 12 and 13 was closed to supply rectified current from a commercial power supply of volts for 50 milliseconds, the movable body I switched in position, moving into contact with one of the magnets with a force of 3.5 kilograms. After interruption of current supply, the movable body 1 was held in position with a retaining force of 5 kilograms. The device exhibited an excellent life response as evidence by more than 100,000 times of reciprocatory motion of the movable body 1.

While the invention has been described with reference to particular embodiments, it should be understood that many modifications will occur to those skilled in the art without departing from the scope and spirit of the invention as defined by the appended claims.

What is claimed is:

l. Solenoid operated plunger device comprising first and second permanent magnets disposed on opposite sides of a movable magnetic body and spaced therefrom in alignment with the direction of movement thereof, a magnetic yoke disposed externally of the magnets and connecting them to each other, a first solenoid coil within the yoke and extending across the first magnet and the movable magnetic body at a position external of both, a second solenoid coil within the yoke and extending across the second magnet and the movable magnetic body at a position external of both, and a plunger mounted on at least one end of the movable magnetic body and extending through an associated one of the magnets and the yoke to the exterior thereof, said permanent magnets, movable magnetic body, coils, and magnetic yoke being so disposed relative to one another that the flux path of the first permanent magnet, the flux path of the second permanent magnet, the path of flux produced upon energization of the first coil, and the path of flux produced upon energization of the second coil all extend in common along a single magnetic path which passes in succession from one of said permanent magnets through said movable body, then through the other of said permanent magnets, and then through said magnetic yoke to said one of said permanent magnets, said movable magnetic body being moved from a position where it is held attracted to one of the permanent magnets to a position adjacent the other permanent magnet by so energizing the coil associated with said other permanent magnet as to produce a flux which cancels the flux from said one permanent magnet and which demagnetizes said one permanent magnet.

2. Solenoid operated plunger device comprising a cylindrical magnetic yoke having its opposite ends closed, a first coil concentrically disposed within the yoke and along the inner periphery thereof within substantially oneehalf of the axial length of the yoke, a second coil concentrically disposed within the other half of the yoke and along the inner periphery thereof, a first permanent magnet located inside the first coil in contact with one of the end plates of the yoke, a second permanent magnet located inside the second coil in contact with the other end plate of the yoke, a movable magnetic body arranged for movement within the first and second coils between the first and second magnets,

and a plunger mounted on one end of the movable magnetic body and extending through the first permanent magnet and one of the end plates to the exterior thereof, the space between said first and second coils being constituted entirely by non-magnetic material, whereby the energization of either of said coils produces a flux which passes through both of said permanent magnets, through said movable magnetic body and through said yoke without extending into the space between said first and second coils.

3. Solenoid operated plunger device according to claim 2 further including means for supplying the first and second coils with a drive current separately, and wherein the direction of winding of the first and second coils and the polarity of the drive current are chosen such that the direction of magnetization of the first and second magnets caused by a current supplied to the first coil is opposite to the direction of magnetization of the first and second magnets caused by a current supplied to the second coil.

4. Solenoid operated plunger device according to claim 2, further including a second plunger mounted on the other end of the movable magnetic body and extending through the second magnet and the other end plate to the exterior thereof.

5. Solenoid operated plunger device according to claim 2, in which the magnetic yoke is in the form of a hollow cylinder and has a bobbin concentrically disposed therein, the first and second coils being wound on one-half and the other half of the bobbin, respectively, the first and second magnets beingfitted into the opposite ends of the bobbin, the movable magnetic body being arranged within the bobbin for move- I ment between the first and second magnets.

6. Solenoid operated plunger device according to claim 5, further including cylindrical spacer means of nonmagnetic material interposed between the inner periphery of the bobbin and the magnets for maintaining'a given spacing between the first and second magnets, the movable magnetic body being arranged within the spacer means for axial movement therein.

i l k

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US2915681 *Nov 20, 1957Dec 1, 1959Indiana Steel Products CoMagnet assemblies
US3040217 *Aug 10, 1959Jun 19, 1962Clary CorpElectromagnetic actuator
US3126501 *Dec 23, 1960Mar 24, 1964International Business Machines CorporationFlora
US3460081 *May 31, 1967Aug 5, 1969Marotta Valve CorpElectromagnetic actuator with permanent magnets
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3864942 *Dec 14, 1972Feb 11, 1975Wildt Mellor Bromley LtdPattern-selecting devices for knitting machines
US4253493 *Jun 16, 1978Mar 3, 1981English Francis G SActuators
US4306206 *Jun 9, 1980Dec 15, 1981Ledex, Inc.Linear solenoid device
US4316167 *Sep 25, 1980Feb 16, 1982La Telemecanique ElectriqueElectromagnet with a moving system and permanent magnet, especially for contactors
US4363980 *Aug 24, 1981Dec 14, 1982Polaroid CorporationLinear motor
US4409576 *Feb 3, 1982Oct 11, 1983Polaroid CorporationMethod and apparatus which change magnetic forces of a linear motor
US4420714 *Oct 2, 1981Dec 13, 1983Polaroid CorporationApparatus for continuously incrementing an output member
US4458227 *Apr 12, 1982Jul 3, 1984Polaroid CorporationElectromagnetic actuators
US4533890 *Dec 24, 1984Aug 6, 1985General Motors CorporationPermanent magnet bistable solenoid actuator
US4641072 *Jul 17, 1985Feb 3, 1987Moog Inc.Electro-mechanical actuator
US4835503 *Mar 20, 1986May 30, 1989South Bend Controls, Inc.Linear proportional solenoid
US4870306 *Oct 8, 1981Sep 26, 1989Polaroid CorporationMethod and apparatus for precisely moving a motor armature
US5149996 *Feb 5, 1990Sep 22, 1992United Technologies CorporationMagnetic gain adjustment for axially magnetized linear force motor with outwardly surfaced armature
US5651391 *May 6, 1996Jul 29, 1997Borg-Warner Automotive, Inc.Three-way solenoid valve
US5765671 *Sep 7, 1995Jun 16, 1998Seiko Epson CorporationElectric power unit and power transmitting unit for electric vehicles
US5853058 *Mar 24, 1997Dec 29, 1998Seiko Epson CorporationElectric power unit and power transmitting unit for electric vehicles
US6005459 *Apr 30, 1997Dec 21, 1999K & L Microwave IncorporatedSwitching device
US6157100 *Jul 16, 1999Dec 5, 2000Rollei Fototechnic GmbhElectromagnetic drive for a focal-plane shutter
US6265956Dec 22, 1999Jul 24, 2001Magnet-Schultz Of America, Inc.Permanent magnet latching solenoid
US6836201 *Dec 1, 1995Dec 28, 2004Raytheon CompanyElectrically driven bistable mechanical actuator
US7222554 *Sep 22, 2004May 29, 2007Isuzu Motors LimitedShift actuator for a transmission
US7449803 *Mar 21, 2005Nov 11, 2008Sahyoun Joseph YElectromagnetic motor to create a desired low frequency vibration or to cancel an undesired low frequency vibration
US7515024 *Oct 26, 2006Apr 7, 2009General Protecht Group, Inc.Movement mechanism for a ground fault circuit interrupter with automatic pressure balance compensation
US7605680 *Sep 7, 2005Oct 20, 2009Kabushiki Kaisha ToshibaElectromagnetic actuator
US7768160Oct 15, 2008Aug 3, 2010Sahyoun Joseph YElectromagnetic motor to create a desired low frequency vibration or to cancel an undesired low frequency vibration
US7800470 *Feb 11, 2008Sep 21, 2010Engineering Matters, Inc.Method and system for a linear actuator with stationary vertical magnets and coils
US7859144Aug 31, 2006Dec 28, 2010Joseph Y SahyounLow frequency electromagnetic motor to create or cancel a low frequency vibration
US8193885 *Dec 7, 2006Jun 5, 2012Bei Sensors And Systems Company, Inc.Linear voice coil actuator as a bi-directional electromagnetic spring
US8387945Feb 10, 2010Mar 5, 2013Engineering Matters, Inc.Method and system for a magnetic actuator
US8686814 *Apr 15, 2010Apr 1, 2014Schneider Electric Industries SasElectric switching device with ultra-fast actuating mechanism and hybrid switch comprising one such device
US8721671 *Jul 6, 2005May 13, 2014Sanofi-Aventis Deutschland GmbhElectric lancet actuator
US8746280 *Mar 17, 2010Jun 10, 2014Airbus Operations GmbhControllable valve for an aircraft
US8860337Jan 6, 2012Oct 14, 2014Resonant Systems, Inc.Linear vibration modules and linear-resonant vibration modules
US8970072 *Nov 18, 2008Mar 3, 2015Koninklijke Philips N.V.Magnetic spring system for use in a resonant motor
US9308307Mar 28, 2013Apr 12, 2016Fresenius Medical Care Holdings, Inc.Manifold diaphragms
US9354640Nov 11, 2013May 31, 2016Fresenius Medical Care Holdings, Inc.Smart actuator for valve
US9358331Dec 24, 2012Jun 7, 2016Fresenius Medical Care Holdings, Inc.Portable dialysis machine with improved reservoir heating system
US9360129 *Jul 13, 2012Jun 7, 2016Fresenius Medical Care Holdings, Inc.Valve system
US9369081Aug 26, 2014Jun 14, 2016Resonant Systems, Inc.Linear vibration modules and linear-resonant vibration modules
US9385578Jan 22, 2015Jul 5, 2016Koninklijke Philips N.V.Magnetic spring system for use in a resonant motor
US9415152May 30, 2014Aug 16, 2016Fresenius Medical Care Holdings, Inc.Disposable apparatus and kit for conducting dialysis
US9455077 *Apr 14, 2015Sep 27, 2016Hyundai Mobis Co., Ltd.Noise reduction type solenoid valve
US9478339Jan 27, 2015Oct 25, 2016American Axle & Manufacturing, Inc.Magnetically latching two position actuator and a clutched device having a magnetically latching two position actuator
US9517296Sep 27, 2013Dec 13, 2016Fresenius Medical Care Holdings, Inc.Portable dialysis machine
US20030000328 *Jul 2, 2002Jan 2, 2003Masahiko HayashiShift actuator for a transmission
US20050034550 *Sep 22, 2004Feb 17, 2005Masahiko HayashiShift actuator for a transmission
US20060208600 *Mar 21, 2005Sep 21, 2006Sahyoun Joseph YElectromagnetic motor to create a desired low frequency vibration or to cancel an undesired low frequency vibration
US20070149024 *Dec 7, 2006Jun 28, 2007Mikhail GodkinLinear voice coil actuator as a bi-directional electromagnetic spring
US20070217100 *Oct 26, 2006Sep 20, 2007General Protecht Group, Inc.Movement mechanism for a ground fault circuit interrupter with automatic pressure balance compensation
US20070257756 *Sep 7, 2005Nov 8, 2007Kabushiki Kaisha ToshibaElectromagnetic Actuator
US20080191825 *Feb 11, 2008Aug 14, 2008Engineering Matters, Inc.Method and System for a Linear Actuator with Stationary Vertical Magnets and Coils
US20090058201 *Feb 28, 2007Mar 5, 2009Resonator AsReciprocating electrical machine
US20090189464 *Jan 26, 2009Jul 30, 2009Luminex CorporationSolenoid Actuator
US20100200788 *Feb 10, 2010Aug 12, 2010Cope David BMethod and System for a Magnetic Actuator
US20100252114 *Mar 17, 2010Oct 7, 2010Lars HoffmannControllable valve for an aircraft
US20100306934 *Nov 18, 2008Dec 9, 2010Koninklijke Philips Electronics N.V.Magnetic spring system for use in a resonant motor
US20100311284 *Dec 5, 2008Dec 9, 2010Kenstronics (M) Sdn BhdAir gap contactor
US20110204096 *Jan 10, 2011Aug 25, 2011Arnd KesslerActuator for a dosing system
US20120280154 *Jul 13, 2012Nov 8, 2012Mark Forrest SmithValve System
US20130027158 *Apr 15, 2010Jan 31, 2013Julien BachElectric Switching Device With Ultra-Fast Actuating Mechanism and Hybrid Switch Comprising One Such Device
US20130147583 *Dec 4, 2012Jun 13, 2013Eto Magnetic GmbhBistable electromagnetic actuating device and camshaft actuating device
US20140018713 *Jul 5, 2013Jan 16, 2014Resonant Systems, Inc.Personal vibration appliance
USRE34870 *Mar 6, 1992Mar 7, 1995Moog Inc.Electro-mechanical actuator
DE4042084A1 *Dec 28, 1990Jul 2, 1992Eberspaecher JMagnet-wegeventil zur volumenstromsteuerung
DE19755957C2 *Dec 17, 1997Oct 31, 2002Pierburg GmbhElektromagnetischer Steller
DE19922089A1 *May 17, 1999Nov 23, 2000Schrott HaraldBistabiles elektromagnetisches Ventil
DE102009002215A1 *Apr 6, 2009Oct 21, 2010Airbus Deutschland GmbhControllable valve for hydraulic control of flame-resistant fluid within aircraft, has magnetic coil which moves component, provided in magnetic coil, from position to another position by short-term electric excitation
DE102009002215B4 *Apr 6, 2009Feb 13, 2014Airbus Operations GmbhSteuerbares Ventil für ein Luftfahrzeug
DE102011103169B4 *Jun 1, 2011Mar 2, 2017Gerhard KirsteinElektromagnetischer Antrieb, Antriebsanlage und deren Verwendung
DE102011115115A1 *Oct 7, 2011Apr 11, 2013Festo Ag & Co. KgValve device e.g. proportional valve for enabling free flow cross section for fluid, has flux guidance body comprising axial extension, which is equal to or smaller than spacing between magnetic effective components of drive device
EP0004967A2 *Apr 17, 1979Oct 31, 1979Werner Dr.Dr. MohlAnchoring means for a probe head, particularly a cardiac probe
EP0004967A3 *Apr 17, 1979Nov 14, 1979Werner Dr.Dr. MohlAnchoring means for a probe head, particularly a cardiac probe
EP1054200A3 *May 13, 2000Oct 24, 2001SCHROTT, HaraldBi-stable electromagnetic valve
EP1298362A3 *Aug 26, 2002Oct 15, 2008Isuzu Motors, Ltd.Shift actuator for a transmission
EP3059480A1 *Jul 14, 2009Aug 24, 2016Henkel AG & Co. KGaAMetering device
WO1981003575A1 *May 13, 1981Dec 10, 1981Ledex IncLinear solenoid device
WO2010007052A2 *Jul 14, 2009Jan 21, 2010Henkel Ag & Co. KgaaActuator for a dosing system
WO2010007052A3 *Jul 14, 2009Mar 25, 2010Henkel Ag & Co. KgaaActuator for a dosing system
WO2017001052A3 *Jun 23, 2016Jun 15, 2017Auma Riester Gmbh & Co. KgActuator and corresponding method
Classifications
U.S. Classification335/234, 335/254
International ClassificationH01F7/16, H01F7/122
Cooperative ClassificationH01F7/1615, H01F2007/1692, H01F7/122
European ClassificationH01F7/16A1