Indian Patents. 214949:"A POWER TRANSFER ASSEMBLY"

Title of Invention	"A POWER TRANSFER ASSEMBLY"
Abstract	A power transfer assembly has a magnet rotor with permanent magnets co-acting with a pair of electroconductive rings on a conductor rotor. The rotary axes of the two rotors are in laterally spaced parallel relation with one of the rotors being greater in diameter than the other.

Full Text	Description Cross-Reference This application is a continuation-in-part of our copending application Serial No. 08/546,066, filed October 20, 1995, which is a continuation of the application issued as Patent No. 5,477,094 issued December 19, 1995 which is a continuation-in-part of Patent No. 5,477,093 issued December 19, 1995. Technical Field This invention relates to a poveer transfer assembly of the type shown in our prior Patent No. 5,477,094 in which permanent magnets on a magnet rotor co-act with electroconductive elements on a conductor rotor by way of eddy currents induced in the electroconductive elements by the magnetic flux from the magnets when their is relative motion between the rotors. Background of the Invention our prior Patent No. 5,477,094 discloses a permanent magnetic drive arrangement for providing a speed ratio between the magnet rotor and conductor rotor in the described system. In that arrangement the rotary axes of the magnet rotor and conductor rotor are spaced apart a greater distance than the radius of the larger of these rotors. The orbit of the magnets on the magnet rotor overlaps the orbits of the conductor elements. In some instances it is preferred to have a more compact assembly than previously disclosed. Summary of the Invention In accordance with the present invention one or more magnet rotors are located within the confines of a conductor rotor with their respective rotary axes in parallel laterally spaced relation. If more than one magnet rotor is provided they may have a peripheral gear meshing with a central idler. Where multiple speed ratios are desired the magnet rotors may have different effective diameters. The present invention relates to a power transfer assembly comprising: a front shaft having a first rotary axis; a back shaft behind the front shaft and character in that it hashaving a secondary rotary axis in spaced parallel relation to said first axis: a conductor rotor mounted on said front shaft and having two electroconductive rings centered on said first rotary axis and surrounding said second rotary axis, and said rings being spaced apart; and a magnet rotor mounted on said back shaft and partly overlapped by said rings on opposite sides of said magnet rotor, said magnet rotor having permanent magnets each with its opposite poles, facing a respective one of said rings and spaced by an air gap therefrom when the permanent magnets occupy a position between said rings during rotation of the magnet rotor, alternate of the magnets having their poles reversed. BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS. Fig. 1 is a longitudinal cross-sectional view through a first embodiment of my invention; Fig. 2 is a fragmentary elevational view with parts broken away looking to the left from the right hand side of Fig. 1; Fig. 3 is a cross-sectional view of a second embodiment taken like Fig. Fig. 4 is a longitudinal sectional view of another embodiment having multiple magnet rotors and is taken as indicted by line 4-4 in Fig. 5, but without showing the idler gear and related magnet rotors; and Fig. 5 is a transverse sectional view taken as indicated by line 5-5 in Fig. 4. Detailed Description of the Invention Referring to the drawings, shafts 10-11 are connected by couplings 12-13 to a magnet rotor unit 14 and conductor rotor unit 15. The conductor rotor unit presents two axially spaced flat rings (continuous bands) 16-17 having good electroconductive characteristics such, for example, as copper or aluminum. These rings 16-17 have ferrous backing rings 18-19, preferably of mild steel. The ferrous backing 18-19 for the electroconductive rings 16-17, and the electroconductive rings 16-17, are mounted on a support ring 15a and a support plate 15b having a hub 15c receiving the coupling 13. Spacers in the form of sleeves 22 separate the members 15a-15b and they are held by bolts 23 passing through the sleeves and the members 15a-15b. The magnet rotor 14 unit includes a disc 24 having sets 26 of permanent magnets 26a-26b mounted in rectangular opening 27 in the disc. The magnets 26a-26b in each set 26 are arranged so that the poles of each magnet 26a have their polarity reversed relative to like facing poles of each magnet 26b. Hence, the magnet poles facing the electroconductive ring 16 alternate in polarity around the magnet rotor 14, and the same is true of the magnet poles facing the electroconductive ring 17. Furthermore, as indicated in Fig. 2, the longitudinal side faces of the magnets in each set 26 which face one another define a neutral plane 36 therebetween which extends radially from the rotary axis 37 of the shaft 10 for maximum performance of the magnets. The disc 24, support ring 14a, spacers 22, support plate 14b and hub 14c are preferably aluminum. The support members 15a-15b are formed with like annular recesses of a thickness to receive respective of the backing rings 18-19 and electroconductive rings 16-17 in stacked relation. It is preferred to have the mouth of the recesses countersunk with a pattern of indentations matching lobes 26 provided on an expanded outer border portion of the electroconductive rings 16-17 which extends beyond the outer marginal edge of the backing 18-19. Mounting screws extend through holes 26a in the lobes 26 into the support members 15a-15b. Either of the shafts 10-11 can be a power input shaft 11 or an output shaft. The shaft 10 turns at a greater speed than the shaft as determined by the ratio of the effective diameter of the conductor rotor 15 to the magnet rotor 14. The effective diameter of the magnet rotor 14 is measured from a circle centered on the rotary axis of the shaft 10 and passing through the center of the meeting faces of the magnets 26a, 26b in each set 26 at the respective neutral plane 36. The effective diameter of the conductor rotor 15 is measured from the largest circle centered on the rotary axis of the shaft 11 which will have point contact with the previously described circle which is centered on the rotary axis of shaft 10. The actual speed ratio between the shafts 10-11 may vary slightly from that determined in the aforesaid manner depending upon the magnet shapes and arrangements and the amount of slip between the rotors 14-15. In a further embodiment of the invention (Fig. 3) a conductor rotor unit 15' is provided like the rotor unit 15, but having an intermediate support ring 15d added which has recesses on its opposite sides receiving electroconductive rings 16', 17' and ferrous backing rings 18', 19'. Additional spacer sleeves 22' are provided in alignment with the spacer sleeves 22. Tie bolts 23 passing through the spacers 22, 22' and through registering openings in the outer and intermediate support rings 15a, 15d and support disc 15b hold these parts together as a unit. A complementing magnet rotor unit 14' with a pair of magnet carrying discs 24, 24' is provided for use with the conductor unit 15'. Referring to Figures 4-5, a further embodiment of the invention is shown in which the conductor rotor 15 has been radially expanded and interleaves with three magnet rotors 14', 14" and 14"' on respective shafts 10', 10" and 10'". These rotors are like the magnet rotor 14, but each have gear teeth 34 around their periphery. The three magnet rotors mesh with an idler 36 mounted on a center shaft 37. It will be apparent that if any of the shafts 10', 10" 10'", 37 or 11 are driven the remainder of the shafts will responsively rotate as output shafts because of the interaction of the sets of magnets 26 on the magnet rotors with the conductor rings 16-17. A conductor rotor with multiple pairs of electroconductive rings such as the rotor 15' (Fig. 3) may be used in which case each of the magnet rotors 14', 14" and 14'" may be dual rotors such as shown in Figure 3. Three magnet rotors have been shown for purposes of example in Figure 5. It will be appreciated that more or less magnet rotors can be provided depending upon space restrictions and the number of power takeoffs that may be required. The pinion 36 may be eliminated and the magnet rotors may have different effective diameters to provide different speed ratios between the conductor rotor shaft 10 and the magnet rotor shafts. Although not the preferred embodiment, it will be appreciated that the Figure 1 assembly, for example, can be altered to make the rotor 15 a magnet rotor and rotor 14 a conductor rotor. This is done by mounting sets 26 of magnets on the ring 15a and straddling the ring 15a with a rotor on shaft 10 having two axially spaced rotor components spaced by air gaps from the ring 15a and presenting the electroconductive rings 16-17 backed by ferrous rings 18019 on opposite sides of the magnets. From the foregoing it will be appreciated that, although specific embodiments of the invention have been described herein for purposes of illustration, various modifications may be made without deviating from the spirit and scope of the invention. Accordingly, the invention is not limited except as by the appended claims. We Claim: 1. A power transfer assembly comprising: a front shaft (11) having a first rotary axis; a back shaft (10) behind the front shaft (11) and having a secondary rotary axis in spaced parallel relation to said first axis; characterized in that it has a conductor rotor (15)s mounted on said front shaft and having two electroconductive rings (16, 17) centered on said first rotary axis and surrounding said second rotary axis, and said rings (16, 17) being spaced apart; and a magnet rotor (14) mounted on said back shaft (10) and partly overlapped by said rings (16, 17) on opposite sides of said magnet rotor (14), said magnet rotor (14) having permanent magnets (26) each with its opposite poles (26a, 26b), facing a respective one of said rings (16, 17) and spaced by an air gap therefrom when the permanent magnets (26) occupy a position between said rings (16, 17) during rotation of the magnet rotor (14), alternate of the magnets (26) having their poles (26a, 26b) reversed. 2. A power transfer assembly as claimed in claim 1, wherein pairs of said magnets (26) having side-by-side faces which extend radially from said second rotary axis. 3. A power transfer assembly as claimed in claim 1, wherein said magnet rotor (14) is located entirely outward of said first rotary axis. 4. A power transfer assembly as claimed in claim 3, wherein a second magnet rotor (14') like the first mentioned magnet rotor (14), is mounted on a third shaft located beside said back shaft (11), said second magnet rotor (14') also being partly overlapped by said electroconductive rings (16. 17). 5. A power transfer assembly as claimed in claim 4, wherein said magnet rotors (14, 14') have teeth (34) around their circumference meshing with an idler gear (36) between the magnet rotors (14, 14'). 6. A power transfer assembly as claimed in claim 1 in which said electroconductive rings (16, 17) are backed by ferrous rings (18, 19). 7. A power transfer assembly as claimed in claim 1, comprising: a front shaft (11) having a first rotary axis; a back shaft (10) behind the front shaft (11) and having a second rotary axis in spaced parallel to said first axis; a conductor rotor (15) mounted on said front shaft (11) forwardly of said back shaft (10) and having a plurality of pairs of electroconductive rings (16, 17, 16', 17') centered on said first rotary axis and surrounding said second rotary axis in outwardly spaced eccentric relation with respect to said back shaft (10), the rings (16, 17, 16', 17') in each said pair being spaced apart; and magnet rotors (14, 14') mounted on said back shaft (10) and each partly interleaved with a respective one of said pairs of electroconductive rings (16, 17, 16', 17') each of said magnet rotors (14, 14') having permanent magnets (26) each with its opposite poles (26a, 26b) facing one of said electroconductive rings (16, 17, 16', 17') and spaced by an air gap therefrom when the magnets (26) occupy a position between a respective pair of the electroconductive rings (16 17, 16', 17') during rotation of the rotors (14, 14'), alternate of the magnets (26) on each magnet rotor (14, 14') having their poles (26a, 26b) reversed. 8. A power transfer assembly as claimed in claim 1, comprising: a front shaft (11) having a first rotary axis; a back shaft (10) behind the front shaft (11) and having a second rotary axis in spaced parallel relation to said first axis; a conductor rotor (15) mounted on one of said shafts (10, 11) and having two electroconductive rings (16, 17) centered on the respective one of said rotary axes, said rings (16, 17) being spaced apart; and a magnet rotor (14) mounted on the other one of said shafts (10, 11) and partly overlapped by said rings (16, 17), and magnet rotor (14) having permanent magnets (26) each with its opposite poles (26a, 26b) facing a respective one of said electroconductive rings (16, 17) and spaced by an air gap therefrom when the magnets (26) occupy a position between said rings (16, 17) during rotation of the magnet rotor (14), alternate of the magnets (26) having their poles (26a, 26b) reversed. the rotor (14), which is on said front shaft (11), being centered on said first rotary axis and surrounding part of said second rotary axis. 9. A power transfer assembly as claimed in claim 8, wherein said conductor rotor (15) is mounted on said first shaft. 10. A power transfer assembly as claimed in claim 8, wherein said conductor rotor (15) is mounted on said second shaft. 11 A power transfer assembly substantially as herein described with reference to and as illustrated in the accompanying drawings.

Full Text

Description
Cross-Reference
This application is a continuation-in-part of our copending application Serial No. 08/546,066, filed October 20, 1995, which is a continuation of the application issued as Patent No. 5,477,094 issued December 19, 1995 which is a continuation-in-part of Patent No. 5,477,093 issued December 19, 1995.
Technical Field
This invention relates to a poveer transfer assembly of the type
shown in our prior Patent No. 5,477,094 in which permanent magnets on a magnet rotor co-act with electroconductive elements on a conductor rotor by way of eddy currents induced in the electroconductive elements by the magnetic flux from the magnets when their is relative motion between the rotors.
Background of the Invention
our prior Patent No. 5,477,094 discloses a permanent magnetic drive arrangement for providing a speed ratio between the magnet rotor and conductor rotor in the described system. In that arrangement the rotary axes of the magnet rotor and conductor rotor are spaced apart a greater distance than the radius of the larger of these rotors. The orbit of the magnets on the magnet rotor overlaps the orbits of the conductor elements. In some instances it is preferred to have a more compact assembly than previously disclosed.
Summary of the Invention
In accordance with the present invention one or more magnet rotors are located within the confines of a conductor rotor with their respective rotary axes in parallel laterally spaced relation. If more than one magnet rotor is provided they
may have a peripheral gear meshing with a central idler. Where multiple speed ratios are desired the magnet rotors may have different effective diameters.
The present invention relates to a power transfer assembly comprising: a front shaft having a first rotary axis; a back shaft behind the front shaft and
character in that it hashaving a secondary rotary axis in
spaced parallel relation to said first axis: a
conductor rotor mounted on said front shaft and having two electroconductive rings centered on said first rotary axis and surrounding said second rotary axis, and said rings being spaced apart; and a magnet rotor mounted on said back shaft and partly overlapped by said rings on opposite sides of said magnet rotor, said magnet rotor having permanent magnets each with its opposite poles, facing a respective one of said rings and spaced by an air gap therefrom when the permanent magnets occupy a position between said rings during rotation of the magnet rotor, alternate of the magnets having their poles reversed.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS.
Fig. 1 is a longitudinal cross-sectional view through a first embodiment of my invention;
Fig. 2 is a fragmentary elevational view with parts broken away looking to the left from the right hand side of Fig. 1;
Fig. 3 is a cross-sectional view of a second embodiment taken like Fig.
Fig. 4 is a longitudinal sectional view of another embodiment having multiple magnet rotors and is taken as indicted by line 4-4 in Fig. 5, but without showing the idler gear and related magnet rotors; and
Fig. 5 is a transverse sectional view taken as indicated by line 5-5 in Fig. 4.
Detailed Description of the Invention
Referring to the drawings, shafts 10-11 are connected by couplings 12-13 to a magnet rotor unit 14 and conductor rotor unit 15. The conductor rotor unit presents two axially spaced flat rings (continuous bands) 16-17 having good electroconductive characteristics such, for example, as copper or aluminum. These rings 16-17 have ferrous backing rings 18-19, preferably of mild steel. The ferrous backing 18-19 for the electroconductive rings 16-17, and the electroconductive rings 16-17, are mounted on a support ring 15a and a support plate 15b having a hub 15c receiving the coupling 13. Spacers in the form of sleeves 22 separate the members 15a-15b and they are held by bolts 23 passing through the sleeves and the members 15a-15b.
The magnet rotor 14 unit includes a disc 24 having sets 26 of permanent magnets 26a-26b mounted in rectangular opening 27 in the disc. The magnets 26a-26b in each set 26 are arranged so that the poles of each magnet 26a
have their polarity reversed relative to like facing poles of each magnet 26b. Hence, the magnet poles facing the electroconductive ring 16 alternate in polarity around the magnet rotor 14, and the same is true of the magnet poles facing the electroconductive ring 17. Furthermore, as indicated in Fig. 2, the longitudinal side faces of the magnets in each set 26 which face one another define a neutral plane 36 therebetween which extends radially from the rotary axis 37 of the shaft 10 for maximum performance of the magnets. The disc 24, support ring 14a, spacers 22, support plate 14b and hub 14c are preferably aluminum.
The support members 15a-15b are formed with like annular recesses of a thickness to receive respective of the backing rings 18-19 and electroconductive rings 16-17 in stacked relation. It is preferred to have the mouth of the recesses countersunk with a pattern of indentations matching lobes 26 provided on an expanded outer border portion of the electroconductive rings 16-17 which extends beyond the outer marginal edge of the backing 18-19. Mounting screws extend through holes 26a in the lobes 26 into the support members 15a-15b. Either of the shafts 10-11 can be a power input shaft 11 or an output shaft. The shaft 10 turns at a greater speed than the shaft as determined by the ratio of the effective diameter of the conductor rotor 15 to the magnet rotor 14. The effective diameter of the magnet rotor 14 is measured from a circle centered on the rotary axis of the shaft 10 and passing through the center of the meeting faces of the magnets 26a, 26b in each set 26 at the respective neutral plane 36. The effective diameter of the conductor rotor 15 is measured from the largest circle centered on the rotary axis of the shaft 11 which will have point contact with the previously described circle which is centered on the rotary axis of shaft 10. The actual speed ratio between the shafts 10-11 may vary slightly from that determined in the aforesaid manner depending upon the magnet shapes and arrangements and the amount of slip between the rotors 14-15.
In a further embodiment of the invention (Fig. 3) a conductor rotor unit 15' is provided like the rotor unit 15, but having an intermediate support ring 15d added which has recesses on its opposite sides receiving electroconductive rings 16', 17' and ferrous backing rings 18', 19'. Additional spacer sleeves 22' are provided in
alignment with the spacer sleeves 22. Tie bolts 23 passing through the spacers 22, 22' and through registering openings in the outer and intermediate support rings 15a, 15d and support disc 15b hold these parts together as a unit. A complementing magnet rotor unit 14' with a pair of magnet carrying discs 24, 24' is provided for use with the conductor unit 15'.
Referring to Figures 4-5, a further embodiment of the invention is shown in which the conductor rotor 15 has been radially expanded and interleaves with three magnet rotors 14', 14" and 14"' on respective shafts 10', 10" and 10'". These rotors are like the magnet rotor 14, but each have gear teeth 34 around their periphery. The three magnet rotors mesh with an idler 36 mounted on a center shaft 37.
It will be apparent that if any of the shafts 10', 10" 10'", 37 or 11 are driven the remainder of the shafts will responsively rotate as output shafts because of the interaction of the sets of magnets 26 on the magnet rotors with the conductor rings 16-17. A conductor rotor with multiple pairs of electroconductive rings such as the rotor 15' (Fig. 3) may be used in which case each of the magnet rotors 14', 14" and 14'" may be dual rotors such as shown in Figure 3.
Three magnet rotors have been shown for purposes of example in Figure 5. It will be appreciated that more or less magnet rotors can be provided depending upon space restrictions and the number of power takeoffs that may be required. The pinion 36 may be eliminated and the magnet rotors may have different effective diameters to provide different speed ratios between the conductor rotor shaft 10 and the magnet rotor shafts. Although not the preferred embodiment, it will be appreciated that the Figure 1 assembly, for example, can be altered to make the rotor 15 a magnet rotor and rotor 14 a conductor rotor. This is done by mounting sets 26 of magnets on the ring 15a and straddling the ring 15a with a rotor on shaft 10 having two axially spaced rotor components spaced by air gaps from the ring 15a and presenting the electroconductive rings 16-17 backed by ferrous rings 18019 on opposite sides of the magnets.
From the foregoing it will be appreciated that, although specific embodiments of the invention have been described herein for purposes of illustration, various modifications may be made without deviating from the spirit and scope of the invention. Accordingly, the invention is not limited except as by the appended claims.

We Claim:
1. A power transfer assembly comprising:
a front shaft (11) having a first rotary axis;
a back shaft (10) behind the front shaft (11) and having a secondary rotary axis in spaced parallel relation to said first axis; characterized in that it has a conductor rotor (15)s mounted on said front shaft and having two electroconductive rings (16, 17) centered on said first rotary axis and surrounding said second rotary axis, and said rings (16, 17) being spaced apart;
and a magnet rotor (14) mounted on said back shaft (10) and partly overlapped by said rings (16, 17) on opposite sides of said magnet rotor (14), said magnet rotor (14) having permanent magnets (26) each with its opposite poles (26a, 26b), facing a respective one of said rings (16, 17) and spaced by an air gap therefrom when the permanent magnets (26) occupy a position between said rings (16, 17) during rotation of the magnet rotor (14), alternate of the magnets (26) having their poles (26a, 26b) reversed.
2. A power transfer assembly as claimed in claim 1, wherein pairs of said
magnets (26) having side-by-side faces which extend radially from said second
rotary axis.
3. A power transfer assembly as claimed in claim 1, wherein said magnet
rotor (14) is located entirely outward of said first rotary axis.
4. A power transfer assembly as claimed in claim 3, wherein a second
magnet rotor (14') like the first mentioned magnet rotor (14), is mounted on a
third shaft located beside said back shaft (11), said second magnet rotor (14')
also being partly overlapped by said electroconductive rings (16. 17).

5. A power transfer assembly as claimed in claim 4, wherein said magnet
rotors (14, 14') have teeth (34) around their circumference meshing with an
idler gear (36) between the magnet rotors (14, 14').
6. A power transfer assembly as claimed in claim 1 in which said
electroconductive rings (16, 17) are backed by ferrous rings (18, 19).
7. A power transfer assembly as claimed in claim 1, comprising:
a front shaft (11) having a first rotary axis;
a back shaft (10) behind the front shaft (11) and having a second rotary axis in spaced parallel to said first axis;
a conductor rotor (15) mounted on said front shaft (11) forwardly of said back shaft (10) and having a plurality of pairs of electroconductive rings (16, 17, 16', 17') centered on said first rotary axis and surrounding said second rotary axis in outwardly spaced eccentric relation with respect to said back shaft (10), the rings (16, 17, 16', 17') in each said pair being spaced apart; and
magnet rotors (14, 14') mounted on said back shaft (10) and each partly interleaved with a respective one of said pairs of electroconductive rings (16, 17, 16', 17') each of said magnet rotors (14, 14') having permanent magnets (26) each with its opposite poles (26a, 26b) facing one of said electroconductive rings (16, 17, 16', 17') and spaced by an air gap therefrom when the magnets (26) occupy a position between a respective pair of the electroconductive rings (16 17, 16', 17') during rotation of the rotors (14, 14'), alternate of the magnets (26) on each magnet rotor (14, 14') having their poles (26a, 26b) reversed.
8. A power transfer assembly as claimed in claim 1, comprising: a front shaft (11) having a first rotary axis;

a back shaft (10) behind the front shaft (11) and having a second rotary axis in spaced parallel relation to said first axis;
a conductor rotor (15) mounted on one of said shafts (10, 11) and having two electroconductive rings (16, 17) centered on the respective one of said rotary axes, said rings (16, 17) being spaced apart;
and a magnet rotor (14) mounted on the other one of said shafts (10, 11) and partly overlapped by said rings (16, 17), and magnet rotor (14) having permanent magnets (26) each with its opposite poles (26a, 26b) facing a respective one of said electroconductive rings (16, 17) and spaced by an air gap therefrom when the magnets (26) occupy a position between said rings (16, 17) during rotation of the magnet rotor (14), alternate of the magnets (26) having their poles (26a, 26b) reversed.
the rotor (14), which is on said front shaft (11), being centered on said first rotary axis and surrounding part of said second rotary axis.
9. A power transfer assembly as claimed in claim 8, wherein said conductor
rotor (15) is mounted on said first shaft.
10. A power transfer assembly as claimed in claim 8, wherein said conductor
rotor (15) is mounted on said second shaft.
11 A power transfer assembly substantially as herein described with reference to and as illustrated in the accompanying drawings.

Documents:

647-DEL-1997-Abstract.pdf

647-DEL-1997-Claims.pdf

647-del-1997-correspondence-others.pdf

647-del-1997-correspondence-po.pdf

647-DEL-1997-Description (Complete).pdf

647-DEL-1997-Drawings.pdf

647-DEL-1997-Form-1.pdf

647-del-1997-form-13.pdf

647-del-1997-form-19.pdf

647-DEL-1997-Form-2.pdf

647-del-1997-form-3.pdf

647-DEL-1997-Form-4.pdf

647-del-1997-form-6.pdf

647-del-1997-gpa.pdf

647-del-1997-petition-137.pdf

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Patent Number

214949

Indian Patent Application Number

647/DEL/1997

PG Journal Number

10/2008

Publication Date

07-Mar-2008

Grant Date

18-Feb-2008

Date of Filing

14-Mar-1997

Name of Patentee

MAGNA FORCE, INCORPORATED

Applicant Address

2602 WEST 18TH, PORT ANGELES, WASHINGTON 98363, UNITED STATES OF AMERICA

Inventors:

#	Inventor's Name	Inventor's Address
1	KARL J. LAMB	944 MONROE ROAD, PORT ANGELES, WASHINGTON 98363, UNITED STATES OF AMERICA

PCT International Classification Number

H02K 49/04

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	08/616,905	1996-03-15	U.S.A.