US3239705A - Electric rotating machine - Google Patents

Electric rotating machine Download PDF

Info

Publication number: US3239705A
Authority: US; United States
Prior art keywords: disc; rotor; windings; printed circuit; conductors
Prior art date: 1961-07-13
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.): Expired - Lifetime

Application number

US123780A

Other languages

English (en)

Inventor

Richard J Kavanaugh

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Tri Tech Inc

Original Assignee

Tri Tech Inc

Priority date (The priority date 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 date listed.)

1961-07-13

Filing date

1961-07-13

Publication date

1966-03-08

1961-07-13 Application filed by Tri Tech Inc filed Critical Tri Tech Inc

1961-07-13 Priority to US123780A priority Critical patent/US3239705A/en

1962-02-16 Priority to GB6020/62A priority patent/GB983161A/en

1962-03-10 Priority to DE19621438291 priority patent/DE1438291B2/de

1962-03-12 Priority to BE614977A priority patent/BE614977A/fr

1962-03-14 Priority to CH307162A priority patent/CH431685A/de

1966-03-08 Application granted granted Critical

1966-03-08 Publication of US3239705A publication Critical patent/US3239705A/en

1983-03-08 Anticipated expiration legal-status Critical

Status Expired - Lifetime legal-status Critical Current

Images

Classifications

- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K3/00—Details of windings
- H02K3/04—Windings characterised by the conductor shape, form or construction, e.g. with bar conductors
- H02K3/26—Windings characterised by the conductor shape, form or construction, e.g. with bar conductors consisting of printed conductors
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K23/00—DC commutator motors or generators having mechanical commutator; Universal AC/DC commutator motors
- H02K23/54—Disc armature motors or generators

Definitions

This invention relates to electric rotating machines, and is particularly applicable to D.C. motors having a disc type rotor.
the invention is especially useful in small D.C. motors having a disc-shaped rotor, with conductors formed on each face of the disc, from a layer of conductive material, for example, copper.
Such conductors may be formed by several techniques, especially printed circuit techniques. Thus, for example, they may be formed by silk-screen or lithographie techniques, photo-resist or other intersect techniques, in preparation for various forms of etching, plating, or by engraving or stamping.
printed circuit motors Another factor is that one important application of printed circuit motors, particularly those of small size, is in portable devices employing relatively low-voltage batteries, in some cases only a single cell. For example, in many of the batteries on the market, the lowest available rated voltage is 1.2 volts. Other common battery voltage ratings are 1.5 volts, 2 volts, 6 volts, 12 volts and 24 volts. It is desirable to provide printed circuit motors having voltage and current requirements which are tailored to the voltage and current provided by commercially available cells or batteries. It is also desirable to provide printed circuit motors which satisfy such voltage and current requirements and which are of small size. A problem heretofore existing in some of the smaller printed circuit motors has been that the voltage required at their input terminals was too low (in some cases lower than even the voltage available from a single cell), and their current requirements were too high, to lit available power supplies.
the size of the commutators and brushes should be kept to a minimum in order to provide as much usable space as possible for working conductors, as well as to reduce friction.
This interrelationship between brush and commutator size and conductor length differs from that existing in motors where conventional cylindrical commutators are used because in the latter case the area of the -commutator can be increased by increasing its length without affecting the length of the conductors of the rotor.
An advantageous feature of certain embodiments of the present invention is that it provides a printed circuit rotor, for use in small size D.C. motors, which by a combination of factors is designed fory operation with a larger applied voltage at its input terminals, and which is more efficient, than prior printed circuit motors of comparable size.
a part of this improvement is obtained by a configuration which enables a larger proportion of the surfaces of the rotor to be employed usefully.
Another source of improvement is that, in certain embodiments, the rotor is so designed that, during operation, current, in passing from an input commutator segment through the motor to an output commutator segment, traverses a larger number of windings than in prior such devices.
the current may, in some commutator positions, enter a given commutator segment,
the design of the proposed rotor provides a higher back E.M.F., and thus provides a motor capable of operation at a higher operating voltage, other factors being equal, than prior proposals.
a disc-shaped rotor including printed circuit windings on its opposite surfaces, and these windings may be arranged in pairs, members of a pair being disposed on opposite faces of the disc.
a commutator connected to the winding or windings on one face only of the disc, and it is possible, as described herein, to reduce the number of interconnections between the two surfaces of the disc so that the number' of such interconnections equals the number of pairs of oppositely disposed windings.
the rotor windings employ a form of Y connection.
a ring conductor and a plurality, for example, three, windings having one end of each connected to the ring conductor.
the windings may each be in the shape of a continuous planar geometric figure having portions extending radially with respect to said rotor, and spiraling toward a connection point, one within each of said figures. Electrically, the connections on this first side of the disc may be regarded as a Y connection.
the second side of the disc there may be provided printed circuit windings arranged generally similarly to those on the rst side of the disc, except that, instead of one end of each of the windings being connected to a ring, one end of each is connected to a segment of a commutat-or, and there is a surface-to-surface connection between the other end of each of these windings and the connection points of the firstmentioned set of windings.
the com- -posite arrangement is such that the windings on the second side correspond electrically to an extension of the Y arrangement portions of the windings on the first side, and they are oriented so that their magnetic fields are cumulative.
a permanently magnetized stator magnet Supported in a spaced, face-wise relation to the rotor is a permanently magnetized stator magnet, which may be generally in the shape of a cylinder, the diameter of which is greater than its thickness.
This stator may cornprise at least a pair of permanently magnetized sectors, magnetized in opposite directions, so as to produce flux extending parallel ⁇ to the axis of the stator and of the rotor.
the stator magnet may comprise a magnetically hard material, for example a ferrite material or other highcoercive force magnetic material. Another consideration is that it is desirable to employ a stator magnet of high reluctance material, for example a ferrite, and to employ in other portions of the stator structure a low reluctance material, for example, cold rolled steel, the net effect being a high reluctance circuit through the stator as a whole.
the motor of the present invention has many important advantages, including low cost, high-etlciency operation ⁇ from a practical and readily available power supply, fewer interconnections, and minimum tendency to produce arcing during operation.
FIGURE 1 is a plan View of a D.C. motor constructed in accordance with one illustrative embodiment of the invention, with certain parts broken away and others in section.
FIGURE 2 is a vertical sectional view taken along the line 2-2 in FIGURE 1.
FIGURE 3 is a plan view of one side of a disc type rotor useful in connection with the embodiment of the invention shown in FIGURE l.
FIGURE 4 is a plan view of the opposite side of the rotor of FIGURE 3.
FIGURE 5 is a schematic perspective View of the arrangement of the electrical circuitry on the rotor of FIGURE 3, the rotor disc being omitted in FIGURE 5 for purposes of clarity.
FIGURE 6 is a plan view of one side of a disctype rotor constructed in accordance with another illustrative embodiment of the invention.
FIGURE 7 is a plan view of the opposite side of the rotor of FIGURE 6.
FIGURE 8 is a fragmentary exploded view, partially in section, of certain portions of the motor shown in FIG- URE 1.
FIGURE 9 is a distorted straight-line perspective view showing the arrangement of commutator segments and windings on the rotor of FIGURE 3, the rotor disc being omitted in FIGURE 9 for purposes of clarity.
FIGURE 10 is a sectional view, with certain parts omitted, taken generally along the lines 11)*10 in FIG- URE 2.
FIGURES 1-5 of the drawings there is shown a D C. -motor having a thin, wafer-like rotor 12 mounted at one end of a shaft 13.
the rotor includes a supporting disc 15 which is fabricated from a dielectric material of low permeability, such as epoxy glass, for example.
the disc 15 is provided with electrical circuitry on each side thereof formed by printed circuit techniques.
This circuitry includes three pairs of rotor windings connected in Y.
one side of the disc (the side shown in FIGURE 4) includes a printed ring conductor 17, surrounding and in close proximity to the shaft 13, and three printed circuit windings 20, 21 and 22 having one end of each connected to the conductor 17. These windings spiral inwardly toward connection points 23, 24 and 25, respectively.
FIG. 3 On the opposite (FIGURE 3) side of the disc 15, there are provided three printed circuit windings 30, 31 and 32 which in general are arranged in a manner similar to the windings 2t?, 21 and 22, but are respectively connected to three commutator segments 35, 36 and 37.
the windings 30, 31 and 32 are substantially superimposed over the windings 20, 21 and 22 and spiral inwardly in the same gtational directions toward connection points 40, 41 and
the connection points 23 and 4t) for the opposed windings and 30 are electrically interconnected by a conductive link 45 (FIGURES 5 and 9) which extends directly through the insulating disc 15 at a point intermediate the center of the disc and the disc periphery.
spaced conductive links 46 and 47 serve to connect the connection points 24 and 41 for the opposed windings 21 and 31 and the connection points 25 and 42 for the opposed windings 22 and 32, respectively.
a separate electrically conductive path may be traced from the ring conductor 17 through a pair of windings on the rotor to each of the commutators seg-ments 35, 36 and 37.
One of these paths extends from the ring conductor through the winding 20 to the connection point 23 on one side of the disc, along the link 45 to the connection point 40 on the opposite side of the disc, and then through the winding 30 to the segment 3S.
a second path may be traced from the ring conductor, through the winding 21 to the connection point 24, along the link 46 to the connection point 41 on the opposite side of the disc and through the winding 31 to the segment 36.
the third path extends from the ring conductor through the winding 22, the connection point 25, the link 47, the connection point 42, and the winding 32 to the segment 37.
windings and surface to surface links on the rotor disc are thus arranged so that a single link is provided for each opposed pair of windings.
Each of the windings is in the form of a continuous, planar geometric gure, the windings 20, 21 and 22 lying in a single iiat plane on one face of the disc 15 and the windings 30, 31 and 32 lying in a single at plane on the opposite disc face.
the windings are each of substantially triangular configuration, with portions thereof extending radially with respect to the rotor.
the shape of each winding approximates an inwardly spiraling isosceles triangle, with the sides extending in a radial direction from the center portion of the disc and the base extending along an arcuate path parallel to the disc periphery.
the arrangement is such that, consistent with proper utilization of the available space on the disc surfaces, a considerable portion of each winding extends radially with respect to the rotor, for purposes that will become more fully apparent hereafter.
stator 50 Coaxially mounted in spaced, juxtaposed relationship with the side of the rotor 12 including the ring conductor 17 is a permanently magnet-ized stator 50 (FIGURES 2 and 10).
the stator is of annular configuration and has an outside diameter that is substantially equal to the diameter of the rotor. The thickness of the stator, while greater than that of the rotor, is considerably less than the stator diameter.
the stator magnet 50 com-prises a ferrite material having high coercivity and low permeability.
a ferrite material having high coercivity and low permeability.
One material which is satisfactory for this purpose is barium ferrite, BaFelZOlg, available commercially under the trade name Magnadure from the Ferroxcube Corporation of America. This material is magnetically hard and has a high coeroivity which is around 1600 oersteds. The permeability of the material is low and approximates that of air.
the stator magnet comprises a pair of permanently magnetized sectors or regions S2 and 53 which produce magnetic flux extending in a direction parallel to the common axis of the stator and the rotor. These sect-ors are magnetized in opposite directions, one Ibeing of north (N) polarity and the other of south (S) polarity.
the magnet material having high coercivity, enables the orientation of the oppositely poled regions 52 and 53 in close proximity with each other.
each region advantageously extends through an arc of substantially one hundred eighty degrees of the magnet periphery, as indicated schematically in this figure by the arrows leading from the N and S poles.
the magnetized regions may be spaced farther apart from each other and may describe a lesser arc, for example, one hundred twenty degrees.
the stator magnet need not be ring shaped, but illustratively may be in the form of two spaced-apart, oppositely magnetized sectors, each one hundred and twenty degrees wide, for example.
the stator magnet 50 is supported on a substantially square mounting plate 55 (FIGURE 2), of a magnetically soft material such as cold rolled steel, for exa-rnple, which is provided with an axially disposed bearing ⁇ assembly 56 through which extends the rotor shaft 13.
a square cover plate 60 also of magnetically soft material, is maintained in spaced relationship with the plate 55, as by corner posts 62, land i-s spaced from the rotor 12 on the side thereof opposite that adjacent the stator 50.
the plate 60 is provided with an elongated opening 64 therein which extends outwardly from immediately adjacent the commutator segments 35, 36 and 37 on the rotor to one edge of the plate.
An insulating member 65 is suitably supported within the opening 64 and accommodates two elongated brushes 67 and 68 which are oriented in directions parallel to the motor shaft 13. These brushes are carried by leaf springs 70 and 71, respectively, which serve to 4bias the brushes into engagement with certain of the commutator segments 35, 36 and 37.
a housing member 73 partially encloses the brushes and their leaf springs and is secured to the member 65 by a machine screw 74.
the brushes 67 and 68 are electrically connected to a battery (not shown) or other direct current source by conductors 75 and 76.
the cross-sectional area of each brush is relatively large, and the brush width is substantially greater than the spacing between adjacent commutator segments.
the magnetic iiux from the permanently magnetized stator magnet 50 follows a path of relatively high reluctance which may be traced from the stator sector 52, across .the air gap between the magnet 50 and the rotor 12, through the adjacent portion of the rotor and across the air gap between the rotor and the cover plate 60 to the cover plate 55.
the flux path continues along .the cover plate to a position adjacent the oppositely magnetized stator sector 53, across the gap between the cover and the rotor, through the rotor and then across the Vgap between the lrotor and the sector 53 to this latter sector.
the iiux returns to the sector 52 through the mounting plate 55.
the axial spacing between the cover plate 60 and the stator magnet 5t is small in comparison with the magnet thickness. (In FIGURE 2, this axial spacing has been exaggerated for purposes of clarity.)
the magnet material has a permeability approximately equal to that of air.
the total reluctance of the magnetic circuit is substantially equal to the sum of the reluctance of the magnet 50, a comparatively lar-ge quantity, and the reluctance of the air gap between the magnet and the cover plate, a relatively small quantity.
the D.C. current applied to the motor follows a path from the battery to the conductor 75 and the brush 67. In some commutator positions, the current flows from this brush to one of the commutator se-gments 35, 36 or 37 on the rotor and then flows through four of the rotor windings before returning to the battery through another of the commutator segments, the brush 68 and the Vconductor 76.
the current supplied to the commutator segment 35 ows through the win-ding 30 (FIGURE 5 to the connection point tu on one side of the rotor disc, along the conductive link 4S to the connection point 23 on the opposite side of the disc, through the winding 2t), the ring conductor 17 and the winding 21 to the connection point 24 on this latter disc side, back through the conductive link 46 to the connection point 41 on the first Iside of the disc and then through the Winding 31 to the commutator segment 36 and the brush 68.
the current tiowing through the four series-connected windings 30, 20, 2l and 3'1 interacts with the magnetic .field of the stator 50 to produce a high torque for driving the rotor and thereby increase the overall efficiency of the motor.
the greater effective length of lthe series-connected windings provides a lhigh back and thus enables operation of the motor at an increased applied voltage across the brushes.
the brushes 67 and 68 alternately bridge adjacent pairs of the commutator segments 35, 36 and 37.
the current during this bridging action ows from one of the brushes, through a circuit which includes the bridged segments, the associated parallel pairs of the series-connected rotor windings, the third series-connected 'winding pair and the segment therefore, and then to the other brush.
the overall etiilciency of the motor is further increased.
both the rotor and the stator preferably are fabricated from low permeability materials. 'Ihe comparatively high reluctance of the magnetic circuit reduces self-induction in the rotor windings and there- Iby minimizes the deleterious effects of arcing, radio frequency interference, etc.
the circuit for each successive pair of windings is momentarily opened as the .commutator segment for these 'windings moves out of contact with one of the brushes.
the reduced ind-uctance in the windings serves to minimize the inductive kick which would otherwise occur during these openacircuit conditions.
the rotor windings may be connected in Y, with all the attendant advantages, without the undesirable effects of a high inductive kick.
the rotor I12 is mounted on the shaft 13 in a manner such that the rotor at all times is in accurate dynamic balance.
a bushing 77 is suitably aixed to the shaft, and the rotor is cemented to a face of this bushing, as at 78.
the shaft 4 is rotated at high speed. The centrifugal forces on the rotor serve to orient it perpendicular to the shaft, with the result that, upon operation of the motor, the forces acting on the rotor are uniform and in proper balance.
FIGURES 6 and 7 are illustrative of an alternative rotor 80 useful in connection with the invention.
the rotor 80 is in general similar to the rotor 12 described yabove and includes a supporting disc which is provided with Y connected printed circuit windings arranged in two parallel planes on opposite disc faces.
the conductors forming the various .windings of the rotor 8e are substantially wider than those of the rotor 12.
the ywindings on the side of rotor Si) opposite that including the commutator segments are interconnected by a ring conductor 8S which extends around the periphery of the disc, rather than adjacent the center portion of the disc.
One advantage of the arrangement of FIGURES 4 and 5 is that more space is available adjaleent the center of the ring side of the disc for the windings. Hence, for a given size motor, the number of turns Ifor each winding may be reduced.
the conductive portions on the two sides of the rotor disc may be formed from a pair of sheets of copper, arranged with one lon each side of the disc, separated by insulating material. rIlhus, the commutators land windings and interconnections on one side are formed from one sheet of copper, and the windings and interconnection-s on the other side are formed from another sheet of copper.
connection points 41 and 24 there may be provided, between the connection points 41 and 24, not just a single connecting link 46, but a plurality of such links, for example, three, connected in parallel.
the connecting links may be formed by a variety of techniques.
the rotor disc is provided with a surface-to-surface hole at each point where a link is to be formed, and the hole is plated with copper or other electrically conductive material.
the various windings are then formed in the manner outlined heretofore, with the appropriate connection points in contact with the plated holes.
each hole in the disc is provided with a copper eyelet, slug, etc., which is soldered at opposite ends to the corresponding connection points on the windings.
a printed circuit rotor comprising 9 a disc bearing printed circuit windings conected in Y, including, on a first surface of said disc, at least three printed circuit windings, printed circuit means connecting together one end of each of said windings, and means connecting the other ends of each of said windings to connection points on the second surface of said disc, and including, on said second surface of said disc, at least three windings, one end of each of the windings on said second surface being connected to one of said connection points, a printed circuit commutator, and means connecting the other end of each of said last-mentioned windings to said commutator, the number of the connections through said disc from its two surfaces being equal to the number of windings on each of its surfaces.
a disc-shaped rotor comprising, on each face of the disc, printed circuit conductors arranged in a plurality of continuous geometric figures, there being one end portion for said conductors within each of said figures, means interconnecting pairs of the said end portions on opposite faces of said disc, the conductors forming each of the said continuous geometric figures having a second end portion, a commutator including segments, said segments being connected respectively to the said second end portions on one face only of said disc, and printed circuit means interconnecting the said second end portions of the conductors on the opposite face of said disc with one another, whereby to form a Y-connected printed circuit rotor having windings distributed on opposite surfaces of said disc.
a disc-shaped rotor comprising printed circuit cnoductors arranged to form composite winding means distributed on opposite faces of the disc, each of said printed circuit conductors having a first and a second end portion, means intermediate the center and the periphery of said disc for interconnecting pairs of the said first end portions on said opposite disc faces, a cornmutator connected to the said second end portions of the conductors on one face of said disc, and means including a ring-shaped member interconnecting the said second end portions of the conductors on the opposite face f said disc with one another.
a disc-shaped rotor comprising, on each face of the disc, printed circuit conductors arranged in a plurality of continuous geometric figures, there being one end portion for said conductors within each of said figures, means interconnecting pairs of the said end portions on opposite faces of said disc, the conductors forming each of the said continuous geometric figures having a second end portion, a commutator including segments, said segments being connected respectively to the said second end portions on one face only of said disc, and means including a printed circuit ring near the center of said disc for interconnecting the said second end portions of the conductors on the opposite face of said disc with one another, whereby to form a Y-connected printed circuit rotor having windings distributed on opposite surfaces of said disc.
a disc-shaped rotor comprising, on each face of the disc, printed circuit conductors arranged in a plurality of continuous geometric figures, there being one end portion for said conductors within each of said figures, Imeans interconnecting pairs of the said end portions on opposite faces of said disc, the conductors forming each of the said continuous geometric figures having a second end portion, a commutator including segments, said segments being connected respectively to the said second end portions on one face only of said disc, and means including a printed circuit ring near the outer edge of said disc for interconnecting the said second end portions of the conductors on the opposite face of said disc with one another, whereby to form a Y-connected printed circuit rotor having windings distributed on opposite surfaces of said disc.

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Engineering & Computer Science (AREA)
Power Engineering (AREA)
Dc Machiner (AREA)
Windings For Motors And Generators (AREA)

US123780A 1961-07-13 1961-07-13 Electric rotating machine Expired - Lifetime US3239705A (en)

Priority Applications (5)

Application Number	Priority Date	Filing Date	Title
US123780A US3239705A (en)	1961-07-13	1961-07-13	Electric rotating machine
GB6020/62A GB983161A (en)	1961-07-13	1962-02-16	Electric rotating machine
DE19621438291 DE1438291B2 (de)	1961-07-13	1962-03-10	Rotierender scheibenanker fuer elektrische gleichstrommaschinen
BE614977A BE614977A (fr)	1961-07-13	1962-03-12	Machine électrique tournante ou moteur
CH307162A CH431685A (de)	1961-07-13	1962-03-14	Elektrische Maschine, insbesondere Gleichstrommotor

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
US123780A US3239705A (en)	1961-07-13	1961-07-13	Electric rotating machine

Publications (1)

Publication Number	Publication Date
US3239705A true US3239705A (en)	1966-03-08

Family

ID=22410844

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
US123780A Expired - Lifetime US3239705A (en)	1961-07-13	1961-07-13	Electric rotating machine

Country Status (5)

Country	Link
US (1)	US3239705A (de)
BE (1)	BE614977A (de)
CH (1)	CH431685A (de)
DE (1)	DE1438291B2 (de)
GB (1)	GB983161A (de)

Cited By (9)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US3293466A (en) *		1966-12-20		Axial airgap electric rotary machines
US3459976A (en) *	1966-07-05	1969-08-05	Mohawk Data Sciences Corp	Rotary electrodynamic driver
DE2741423A1 (de) *	1976-09-14	1978-03-16	Olympus Optical Co	Laeufer fuer kleine kernlose elektromotoren sowie ein verfahren zu ihrer herstellung
US4303844A (en) *	1978-08-31	1981-12-01	Tadashi Suzuki	Small D.C. motor
US4315177A (en) *	1978-01-23	1982-02-09	Itsuki Ban	Direct current motor with non-superposed armature windings
US4315178A (en) *	1978-01-23	1982-02-09	Itsuki Ban	Direct current motor with non-superposed armature windings
US4712034A (en) *	1984-03-30	1987-12-08	Aisin Seiki Kabushiki Kaisha	Multiple ring armature core for direct current motor
JP2011078255A (ja) *	2009-09-30	2011-04-14	Hitachi Koki Co Ltd	電動モータ及び作業機械
JP2012161149A (ja) *	2011-01-31	2012-08-23	Hitachi Koki Co Ltd	ディスクモータ及びそれを備えた電動作業機

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
DE102020216112A1 (de)	2020-12-17	2022-06-23	Zf Friedrichshafen Ag	Elektrische Anordnung mit einer Steuerungsvorrichtung und einer elektrischen Maschine

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US2722617A (en) *	1951-11-28	1955-11-01	Hartford Nat Bank & Trust Comp	Magnetic circuits and devices
US2773239A (en) *		1956-12-04		Electrical indicating instruments
US2847589A (en) *	1955-06-09	1958-08-12	Cons Electronics Ind	Electric rotating machinery
US2853637A (en) *	1955-05-03	1958-09-23	Ishikawa Kazuo	Fractional direct current torque motor
FR1232438A (fr) *	1959-04-21	1960-10-07	Normacem Sa	Perfectionnements aux machines électriques tournantes
FR1233656A (fr) *	1959-05-04	1960-10-12	Electronique & Automatisme Sa	Machines électriques tournantes alimentées en courant alternatif
US3095516A (en) *	1959-04-30	1963-06-25	Normacem Sa	Armature coil for axial air gap machines

1961
- 1961-07-13 US US123780A patent/US3239705A/en not_active Expired - Lifetime
1962
- 1962-02-16 GB GB6020/62A patent/GB983161A/en not_active Expired
- 1962-03-10 DE DE19621438291 patent/DE1438291B2/de active Pending
- 1962-03-12 BE BE614977A patent/BE614977A/fr unknown
- 1962-03-14 CH CH307162A patent/CH431685A/de unknown

Patent Citations (7)

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US2773239A (en) *		1956-12-04		Electrical indicating instruments
US2722617A (en) *	1951-11-28	1955-11-01	Hartford Nat Bank & Trust Comp	Magnetic circuits and devices
US2853637A (en) *	1955-05-03	1958-09-23	Ishikawa Kazuo	Fractional direct current torque motor
US2847589A (en) *	1955-06-09	1958-08-12	Cons Electronics Ind	Electric rotating machinery
FR1232438A (fr) *	1959-04-21	1960-10-07	Normacem Sa	Perfectionnements aux machines électriques tournantes
US3095516A (en) *	1959-04-30	1963-06-25	Normacem Sa	Armature coil for axial air gap machines
FR1233656A (fr) *	1959-05-04	1960-10-12	Electronique & Automatisme Sa	Machines électriques tournantes alimentées en courant alternatif

Cited By (12)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US3293466A (en) *		1966-12-20		Axial airgap electric rotary machines
US3459976A (en) *	1966-07-05	1969-08-05	Mohawk Data Sciences Corp	Rotary electrodynamic driver
DE2741423A1 (de) *	1976-09-14	1978-03-16	Olympus Optical Co	Laeufer fuer kleine kernlose elektromotoren sowie ein verfahren zu ihrer herstellung
US4315177A (en) *	1978-01-23	1982-02-09	Itsuki Ban	Direct current motor with non-superposed armature windings
US4315178A (en) *	1978-01-23	1982-02-09	Itsuki Ban	Direct current motor with non-superposed armature windings
US4303844A (en) *	1978-08-31	1981-12-01	Tadashi Suzuki	Small D.C. motor
US4712034A (en) *	1984-03-30	1987-12-08	Aisin Seiki Kabushiki Kaisha	Multiple ring armature core for direct current motor
JP2011078255A (ja) *	2009-09-30	2011-04-14	Hitachi Koki Co Ltd	電動モータ及び作業機械
CN102379079A (zh) *	2009-09-30	2012-03-14	日立工机株式会社	电动机和包括该电动机的工作机
US20120104881A1 (en) *	2009-09-30	2012-05-03	Hideyuki Tanimoto	Electric motor and working machine comprising the same
US8928201B2 (en) *	2009-09-30	2015-01-06	Hitachi Koki Co., Ltd.	Electric motor having an output shaft rotatably supported by a housing and working machine including the same
JP2012161149A (ja) *	2011-01-31	2012-08-23	Hitachi Koki Co Ltd	ディスクモータ及びそれを備えた電動作業機

Also Published As

Publication number	Publication date
GB983161A (en)	1965-02-10
DE1438291A1 (de)	1970-06-18
DE1438291B2 (de)	1972-05-18
CH431685A (de)	1967-03-15
BE614977A (fr)	1962-09-12

Publication	Publication Date	Title
US3312846A (en)	1967-04-04	Electric rotating machines
US3230406A (en)	1966-01-18	High frequency electromechanical generator
US3097319A (en)	1963-07-09	Printed circuit stator for electrical rotating machines
US4197475A (en)	1980-04-08	Direct current motor with double layer armature windings
US3237036A (en)	1966-02-22	Commutating dynamo-electric machine
US3529191A (en)	1970-09-15	Homopolar machine having disklike rotor
US4227107A (en)	1980-10-07	Direct current motor with double layer armature windings
US3261998A (en)	1966-07-19	Axial airgap dynamoelectric machine
US3090880A (en)	1963-05-21	Electrical rotating machines
US3356877A (en)	1967-12-05	Electromechanical energy converter of the double air gap type
GB1514307A (en)	1978-06-14	Dynamoelectric machine stators and stator laminations
US3109114A (en)	1963-10-29	Multiple-winding electrical rotating machines
US2880335A (en)	1959-03-31	Induction motor
US3315106A (en)	1967-04-18	Disk shaped electric motor
US4712034A (en)	1987-12-08	Multiple ring armature core for direct current motor
US3525008A (en)	1970-08-18	Electrical wire wound axial air-gap machines
US3060337A (en)	1962-10-23	Axial air-gap motor with printed stator and rotor
US3558947A (en)	1971-01-26	Discoidal wire wound armatures
US3239705A (en)	1966-03-08	Electric rotating machine
US3500095A (en)	1970-03-10	Multilayer disc armature for dynamo electric machine
US2853637A (en)	1958-09-23	Fractional direct current torque motor
US3290528A (en)	1966-12-06	Direct current double air gap motor
US4605873A (en)	1986-08-12	Electromechanical machine
US3549928A (en)	1970-12-22	Armature
US3668452A (en)	1972-06-06	Dynamoelectric machine with improved magnetic field construction