Upload
alexmen7411847196
View
229
Download
0
Embed Size (px)
Citation preview
8/11/2019 Motor mag pantentado ''1.docx
1/43
1
Fig. 1a, 1 bare cross sections of a stator with a magnet sequence;
Fig. 2a, 2bare cross sections of stators with multiple magnet sequences;
8/11/2019 Motor mag pantentado ''1.docx
2/43
2
Fig. 3a, 3bdevelopments of outer surfaces of stators;
8/11/2019 Motor mag pantentado ''1.docx
3/43
3
Fig. 4developments of outer surfaces of a stator and a rotor;
8/11/2019 Motor mag pantentado ''1.docx
4/43
4
Fig. 5a - 5ca side view and cross sections of a stator;
8/11/2019 Motor mag pantentado ''1.docx
5/43
5
Fig. 6a - 6fshows, a longitudinal section and cross sections of a rotor; Fig. 7a -
7d views and a cross section of a stator;
8/11/2019 Motor mag pantentado ''1.docx
6/43
6
8/11/2019 Motor mag pantentado ''1.docx
7/43
7
8/11/2019 Motor mag pantentado ''1.docx
8/43
8
8/11/2019 Motor mag pantentado ''1.docx
9/43
9
Fig. 8a - 8dshows and a cross section of a stator;
8/11/2019 Motor mag pantentado ''1.docx
10/43
10
Fig. 9a - 9hillustrate the pitch angle;
8/11/2019 Motor mag pantentado ''1.docx
11/43
11
Fig. 10illustrates of the relationship between Magnet sequences and magnet
rows of the rotor;
8/11/2019 Motor mag pantentado ''1.docx
12/43
12
Fig. 11is a representation of an apparatus according to invention with one rotor
and two stators;
8/11/2019 Motor mag pantentado ''1.docx
13/43
13
Fig. 12aan oblique view of the inner stator of the apparatus after Fig. 11 without
magnets (= stator core);
8/11/2019 Motor mag pantentado ''1.docx
14/43
14
Fig. 12ba schematic representation of the inner stator of the apparatus after Fig.
11, vertical to the shaft axis;
Fig. 13a development of the magnet assembly on the inner stator of the
apparatus after Fig. 11 ;
8/11/2019 Motor mag pantentado ''1.docx
15/43
8/11/2019 Motor mag pantentado ''1.docx
16/43
16
Fig. 15aa view of the fastener of the apparatus after Fig. 11, vertical to the shaftaxis;
8/11/2019 Motor mag pantentado ''1.docx
17/43
17
Fig. 15ba view of the fastener of the apparatus after Fig. 11, toward the shaft
axis;
Fig. 16an oblique view of the rotor of the apparatus after Fig. 11;
8/11/2019 Motor mag pantentado ''1.docx
18/43
18
Fig. 17aa schematic view of the inner stator and the rotor of the apparatus after
Fig. 11; Fig. 17b a scheme of possible inclination angles of the dipole magnets of
the rotor of the apparatus after Fig. 11 ;
8/11/2019 Motor mag pantentado ''1.docx
19/43
19
Fig. 18aa development of the magnet assembly of the rotor of the apparatus after
Fig. 11, along in Fig. 16 direction indicated XY;
8/11/2019 Motor mag pantentado ''1.docx
20/43
20
Fig. 18ba detail view of the development in accordance with Fig. 18a;
8/11/2019 Motor mag pantentado ''1.docx
21/43
21
Fig. 19aa longitudinal section by a mechanical housing to the receptacle of the
apparatus after Fig. 11 ;
Fig. 19ba section by the outside stator of the apparatus after Fig. 11, vertical to
the shaft axis;
8/11/2019 Motor mag pantentado ''1.docx
22/43
22
Fig. 20is an oblique view of the outside stator and the mechanical housing to the
receptacle of the apparatus after Fig. 11;
8/11/2019 Motor mag pantentado ''1.docx
23/43
23
Fig. 21a scheme of the magnet assembly on the stators and the rotor of the
apparatus after Fig. 11, shown as section along that Shaft axis;
8/11/2019 Motor mag pantentado ''1.docx
24/43
24
Fig. 22a scheme of the magnet assembly on the stators and the rotor that
Apparatus after Fig. 11, shown as section along in Fig. 11 indicated line B-B;
Fig. 23ais a schematic representation of a dipole magnet of the outside stator of
the apparatus after Fig. 11 ;
8/11/2019 Motor mag pantentado ''1.docx
25/43
25
8/11/2019 Motor mag pantentado ''1.docx
26/43
26
Fig. 23bis a schematic representation of a dipole magnet of the inner stator of
the apparatus after Fig. 11 ; and
Fig. 23cis a schematic representation of a dipole magnet of the rotor of the
apparatus after Fig. 11. Fig. 1a shows a cross section of a stator 2, whereby the
cutting plane orthogonal to the shaft axis 50 runs. The stator 2 exhibits a circular
cross section. The stator 2 covers a magnet sequence of dipole magnet 8. The
magnetic dipole axle 80 one of these dipole magnets 8 lies in the cutting plane.
The dipole magnet 8 is on an outer surface M2 of a coaxial first circular cylinder
arranged oriented to the shaft axis 50. To the outer surface M2 a tangent
longitudinal in the cutting plane is 81 placed, those the outer surface M2 at the
point touched, at which the dipole axle 80 breaks through the outer surface. Theangle between the dipole axle 80 and the tangent 81 is the inclination angle A,
which amounts to in the present example 90 degree.
Fig.1 b shows a detail of Fig. 1a. The dipole magnet 8 touched those dashed
drawn outer surface M2 in the contact points P1, P2. The scope U of the stator 2
drawn with a continuous line follows the planar Front surface of the dipole
magnet 8 and deviates therefore in the range of the dipole magnet 8 from the
cylindrical outer surface M2.
Fig. 2a shows a cross section of a stator 2 with first and a second magnetsequence. The stator 2 covers two dipole magnets 8, which are next to each other
arranged. The magnetic dipole axles 80 of the two dipole magnets 8 are
appropriate for parallel in the cutting plane and run. The left dipole magnet 8 is
component of the first magnet sequence of the stator 2, the right dipole magnet 8
is component of the second magnet sequence of the stator 2.
Fig. 2b shows a cross section of a stator 2 with first and a second magnet
sequence. The stator 2 covers two dipole magnets 8, which are next to each other
arranged. The magnetic dipole axles 80 of the two dipole magnets 8 lie in the
cutting plane, cut the shaft axis 50 and include an angle [lambda]. The left dipolemagnet 8 is component of the first magnet sequence of the stator 2, the right
dipole magnet 8 is component of the second magnet sequence of the stator 2.
Fig. 3a shows a development of an outer surface M2 of a cylindrical stator with a
magnet sequence F2. The orientation of the outer surface M2 is 50 defined by the
indication of the shaft 5 and the shaft axis. The magnet sequence F2 begins at the
8/11/2019 Motor mag pantentado ''1.docx
27/43
8/11/2019 Motor mag pantentado ''1.docx
28/43
28
regarding the shaft axis 50 around an angle [delta]. In the present embodiment
the angle [delta] amounts to = 12 degree.
Fig. 6a shows a plan view of a rotor 1. The rotor 1 has the form of an hollow
cylinder with an height of H. The height of H e.g. amounts to. 235 mm. The wall
of the rotor 1 exhibits the wall penetrating holes, which serve 15 as recesses forthe receptacle of the dipole magnets. The magnet sequences of the rotor 1 begin
in a distance E of the face of the rotor 1 and end in the distance E of the opposite
face of the rotor 1. In the present embodiment the distance E amounts to 35 mm.
The diameter D15 of the cylindrical recesses 15 e.g. amounts to. 10 mm. Each
recess 15 is a retaining mechanism to the fixation of the dipole magnets 7
associated used into the recesses 15. The retaining mechanism consists of a
threaded hole 150 and a threaded pin, which are pivoted into the threaded hole
and for the fixation of the dipole magnet 7 serve.
Fig. 6b shows a view of on the left of in Fig. 6a of represented rotor 1. The outer
diameter D1A of the rotor 1 e.g. amounts to. 143 mm, its inner diameter D1 I e.g.
93 mm. The rotor 1 exhibits uniform threaded holes M6 distributed over the
scope, which are in a distance DM6 of the outer periphery mounted at its face.
The threaded holes M6 can exhibit for example a metrical ISO thread with a
nominal diameter M6 (ISO = international organization for standardization). The
distance DM6 e.g. amounts to. 10 mm. These threaded holes M6 serve to fasten a
lid on the face of the rotor 1 is 5 connected over which the rotor 1 with the shaft.
At each face the rotor 1 e.g. exhibits a circumferential groove 16, their outer
diameter D16. 97 mm amounts to. This groove 16 takes up a correspondingcircular projection of the lid.
Fig. 6c shows a three-dimensional view in Fig. 6a of represented rotor 1.
Fig. 6d shows a longitudinal section in Fig. 6a of represented rotor 1 along in Fig.
6a indicated cutting plane A-A. The depth TM6 of the Boreholes M6 mounted in
the faces points a value from e.g. 20 mm up. The depth T16, of the
circumferential grooves 16 arranged at the faces e.g. amounts to. 2 mm, its width
B16 has a value of e.g. 2 mm. In Fig. 6d are to be recognized in various recesses
of 15 threaded holes 150, which flow into the recesses 15. Adjacent recesses 15of a magnet sequence e.g. exhibit 50 toward the shaft axis a distance DF1. 11 mm
amounts to.
Fig. 6e shows a cross section in Fig. 6a of represented rotor 1 along in Fig. 6d
indicated cutting plane B-B. In the section uniform recesses 15 for the dipole
magnets, distributed over the scope of the rotor 1, are to be recognized. Everyone
8/11/2019 Motor mag pantentado ''1.docx
29/43
29
of the recesses 15 visible in the section is a separate magnet sequence F1
associated. Related to the shaft axis 50 of the rotor 1 the recess 15 of a magnet
sequence F1 is around the angle [delta] 1 opposite the recess 15 of an adjacent
magnet sequence F1 rotated. In the present embodiment the angle [delta]
amounts to = 20 degree. A dipole axle of a first recess 15 and a central
longitudinal axis of a threaded hole 150, which flows to the first recess 15adjacent recess 15 into one, include an angle [delta] 2, which amounts to in the
present embodiment 25 degree.
Fig. 6f shows a cross section in Fig. 6a of represented rotor 1 along in Fig. 6d
indicated cutting plane CC. Opposite in Fig. 6e represented section are the
recesses 15 around an angle [delta] 1 around the shaft axis 50 twisted. Within a
magnet sequence F1 adjacent dipole magnets are 8 thus regarding the shaft axis
50 around an angle [delta] 1 against each other twisted. In the present
embodiment the angle [delta] amounts to 1 = 12 degree. Fig. 7a shows a plan
view of a stator 2 with group-like arranged magnet sequences F2. Three magnet
sequences F2 form in each case a group G.
Fig. 7b shows a view of on the left of in Fig. 7a of stator shown 2.
Fig. 7c shows a cross section in Fig. 7a of stator shown 2 along in Fig. 7a
indicated cutting plane A-A. The recesses 22 to the receptacle of the cylindrical
dipole magnets 8 are so formed that longitudinal central axis of the recesses 22,
which are a group G the formed magnet sequences F2 associated and are in a
vertical cutting plane arranged longitudinal to the shaft axis 50, are parallel to thecutting plane run and to each other parallel. The straight ones, which the shaft
axis 50 cut and by the points run, in which, longitudinal in the cutting plane,
longitudinal central axis of the recesses 22 break through the scope of the stator 2
a circumscribed cylinder, include with adjacent recesses of a group from magnet
sequences an angle [xi]. In the present embodiment the angle [xi] has a value of
14.24 degree. The outer edges immediate adjacent recesses 22 e.g. exhibit a
minimum distance 23. 1 mm amounted to can.
Fig. 7d shows a three-dimensional view in Fig. 7a of represented stator 2.
Fig. 8a shows a plan view of a stator 2 with group-like arranged magnet
sequences F2. Three magnet sequences F2 form in each case a group G.
Compared with in Fig. 7a shown stator 2 point with in Fig. 8a stator shown 2 a
group G the formed magnet sequences F2 a larger distance from each other up.
Fig. 8b shows a view of on the left of in Fig. 8a of stator shown 2.
8/11/2019 Motor mag pantentado ''1.docx
30/43
30
Fig. 8c shows a cross section in Fig. 8a of stator shown 2 along in Fig. 8a
indicated cutting plane A-A. The recesses 22 to the receptacle of the cylindrical
dipole magnets 8 are so formed that longitudinal central axis of the recesses 22,
which are a group G the formed magnet sequences F2 associated and are in a
vertical cutting plane arranged longitudinal to the shaft axis 50, include parallelto the cutting plane run and with one another an angle [phi] 1. In the present
embodiment the angle [phi] has 1 a value of 28 degree. Immediate neighbors
within the recesses 22, which are the same group G associated, are 22 from each
other separate by a bar of the support body of the stator. The bar exhibits a width
J on the scope of the stator 2, as in Fig. 8c outlines. In the present embodiment
the width J has a value of 11, 94 mm.
Longitudinal central axis of the recesses 22, which are various groups G
associated, 2 includes an angle [phi] at least with one another. In the present
embodiment the angle [phi] has 2 a value of 64 degree.
Fig. 8d shows a three-dimensional view in Fig. 8a of represented stator 2.
Fig. 9a to 9h show in each case a development of the outer surface M1, M2 of a
rotor 1 and/or. Stator 2. A magnet sequence is symbolized by an arrow. By the
arrow direction a direction of a magnet sequence becomes defined. A direction of
a magnet sequence is of importance, if the dipole magnets of the magnet
sequence exhibit a characteristic polarity succession, which is direction-
controlled. For the example it can be for the present invention of importancewhether a magnet sequence with three dipole magnets exhibits the polarity SNN
or the polarity NNS. The orientation of the outer surface M1, M2 is 50 defined
by the indication of the shaft axis.
Fig. 9a shows a pitch angle of b = 10 degree of a magnet sequence, which begins
at the left side of the outer surface. Fig. 9b shows a pitch angle of b = 80 degree
of a magnet sequence, which begins at the left side of the outer surface. Fig. 9c
shows a pitch angle of b = 280 degree of a magnet sequence, which begins at the
right side of the outer surface. Fig. 9d shows a pitch angle of b = 350 degree of a
magnet sequence, which begins at the right side of the outer surface. Fig. 9eshows a pitch angle of b = 10 degree of a magnet sequence, which begins at the
left side of the outer surface. Fig. 9f shows a pitch angle of b = 80 degree of a
magnet sequence, which begins at the left side of the outer surface. Fig. 9g shows
a pitch angle of b = 280 degree of a magnet sequence, which begins at the right
side of the outer surface. Fig. 9h shows a pitch angle of b = 350 degree of a
magnet sequence, which begins at the right side of the outer surface.
8/11/2019 Motor mag pantentado ''1.docx
31/43
31
Fig. 10 serves the illustration of the relationship between magnet sequences F1
and magnet rows 701 to 707 of a rotor 1. Fig. an outer surface M1 of a coaxial
first circular cylinder Z1 oriented to the shaft 5 shows 10. The rotor 1 is coaxial 5
arranged to the shaft. The rotor 1 covers twenty-eight dipole magnets 7, which
are on the outer surface M1 arranged.
The dipole magnets 7 of the rotor 1 are in four magnet sequences F1 with in each
case seven dipole magnets 7 arranged. To the better discrimination the four
magnet sequences F1 with the numbers in deep position of 1 to 4 than F1i to FI4
are durchnummeriert. The dipole magnets 7 of the magnet sequences F1 i to FI4
are so arranged and/or. formed that they sieve longitudinal series 701 to 707 with
in each case four uniform dipole magnets 7 distributed on the scope of the first
circular cylinder Z1 on the outer surface M1 train. The dipole magnets 7 of series
701 to 707 lie in a vertical plane longitudinal to the wave axle 50 of the shaft 5.
The dipole magnets of 7 adjacent rows are against each other alternate so offset
that they form axial to the shaft axis 50 a zigzag pattern uniform over the scope
of the circular cylinder Z1. As example is the uniform zigzag pattern, which the
dipole magnets 7 of the adjacent rows 703 and 704 train, in Fig. 10 with a fat line
indicated.
Fig. a schematic representation of an apparatus according to invention, which
exhibits an inner stator 2, a rotor 1 and an outside stator 3, points 11 the coaxial
to a shaft axis 50 of a rotatable, rod-shaped shaft 5 arranged is. The cylindrical
inner stator 2 exhibits in each case a circle-disc shaped end cap 13 with in eachcase a ball bearing 11 at its two ends. By means of these ball bearings 11 the
inner stator is 2 coaxial 5 stored on the shaft. The shaft is in a typical
embodiment from non magnetic material, e.g. Plastic, made and exhibits a
diameter of 10 to 40 mm and a length from 100 to 400 mm. The inner stator 2
exhibits an inner stator core 12 and whereupon along the outer surface of the
inner stator of 2 arranged magnets 8. The inner stator 2 is connected solid with a
fastener 4, which in a mechanical housing to the receptacle of the apparatus (not
shown) is arranged, by means of screw connections 10 and becomes in this way
fixed held.
The rotor 1, existing from two mirror-image constructed rotor drums with in each
case a pipe section and a circular disk, is 5 connected by means of screw
connections 10 stationary with the shaft. Each of the rotor drums exhibits
magnets 7. It concerns dipole magnets 7, whose magnetic dipole axles in to the
shaft 5 vertical arranged planes run. Each of the rotor drums is by a hollow-
cylindrical air gap of that radial inner stator 2 and by an annular air gap of the
8/11/2019 Motor mag pantentado ''1.docx
32/43
32
attachment disk, arranged within the rotor drums, 4 separate, which represents a
plane of symmetry regarding the two rotor drums of the rotor 1. In a typical
embodiment the annular air gap and the hollow-cylindrical air gap exhibit in each
case a width from 3 to 50 mm. In the circular disks at the faces of the rotor drums
likewise dipole magnets are 700 arranged.
The mass of the rotor 1 and the shaft 5 connected thereby is rotationally
symmetrically distributed, so that with a rotation around the shaft axis 50 no
imbalance arises.
The outside stator 3 consists of two separate annular halves (= stator rings), in
each case with frame 9, magnets 6 and mounting elements to the attachment of
the magnets 6. Everyone the frame consists of an hollow cylinder, at whose both
faces in each case an annular disc arranged is. In this way each of the stator rings
at its outside outer surface and at its two faces of one the frame 9 covered and to
the shaft axis is 50 without frames, i.e. open. Within the frames 9 the magnets 6
are between the mounting elements. Each of the two stator rings in each case one
of the two rotor drums of the rotor is 1 associated. Each of the stator rings is 1
separate by an annular air gap with a width from 3 to 50 mm of the radial rotor
drums of the rotor arranged within the stator rings. The magnets arranged at the
inside of the stator rings and the magnets 8 arranged at the outside of the rotor 1
thus direct face each other 6, only by the annular air gap from each other
separate. Each of the stator rings can become parallel the shaft axis 50 shifted. It
means that the relative position of the outside stator 3 and thus the coverage of
the rotor can become 1 by the outside stator during the operation of the apparatuschanged and adapted.
With the magnets it concerns 6, 7, 8 dipole magnets. In a prefered embodiment
the dipole magnets are 6, 7, 8 as permanent magnets, e.g. existing from the
Materialen SmCo and/or NdFeB, formed. It is however also possible that or the
several dipole magnets are 6, 7, 8 formed as electromagnets. The magnetic flux
density of the magnets 6, 7, 8 preferably lies in a range from 0,4 to 1, 4 tesla.
The frame is preferably from non magnetic material, e.g. Aluminium, made and
exhibits a wall thickness from 2 to 10 mm.
Fig 12a shows out non magnetic material (e.g. Aluminium, copper) existing inner
stator core 12 of the inner stator 2. The core 12 exhibits a circular cylinder 120,
on its outer surface of bars and/or. Ribs 121 in form of a Strahlenkranzes
arranged are. Everyone of the ribs 121 extended itself along the central axis of
the circular cylinder 120 of the base of the cylinder 120 up to its top surface. The
8/11/2019 Motor mag pantentado ''1.docx
33/43
33
ribs 121 run regarding the central axis of the circular cylinder 120 radial and are
uniform distributed over the cylinder extent. In this way 121 grooves develop
and/or between the single ribs. Grooves 122. The circular cylinder 120 exhibits a
circular bore along its central axis to the receptacle of the shaft 5. Both in the
base and in the top surface of the cylinder 120 is in each case a disc shaped
recess, is 11 partial arranged in which one of the ball bearings in each case.
The diameter of the stator core 12 amounts to 50 to 500 mm, its height of 100 to
300 mm. The width of the ribs 121 amounts to
8/11/2019 Motor mag pantentado ''1.docx
34/43
34
outer surface. A first magnet 8-1 is arranged with one of its front surfaces flush
with the base 125 of the inner stator core 12 final on the outer surface. The
residual nine magnets 8 are now toward the shaft axis 50 in uniform
displacement V so arranged that the last magnet locks 8-10 with its right face
flush with the top surface 126 of the inner stator core 12. In this way the
treppenfrmige arrangement of the magnets 8 represented in fig 13 results.
Fig 14 shows a section by the inner stator 2, along the cutting plane A-A
indicated in the fig 12b. The inner stator core 12 exhibits an hollow cylinder 120,
along its central axis the shaft 5 runs and at its outer surface along the ribs 121
run. The hollow cylinder 120 exhibits a diameter of 100 mm and a length of 170
mm. In the grooves formed between the ribs 121 magnets are 8 used, which
exhibit a trapezoidal cross section in the cutting plane A-A. The dipole magnets 8
are so arranged that their magnetic dipole axle 80 within the represented cutting
plane A-A runs. An angle [alpha], formed at the intersection of the magnetic
dipole axle 80 magnets 8 and a tangent 81 to the inner stator 2 in the range
magnets 8, knows values of 14 [deg.] to 90 [deg.] exhibit. In fig 14 illustrated
case the angle [alpha] amounts to = 90 [deg.].
Fig 15a points the fastener 4 in a view vertical to Shaft axis 50. The fastener 4
exhibits an inner hollow cylinder 40 with smaller radius and an outside
attachment annular disc 41 with larger radius. The inner hollow cylinders 40 and
the outside attachment annular disc 41 are solid connected with one another. The
hollow cylinder 40 serves the receptacle and attachment of the inner stator 2 by
screw connections 10. The attachment annular disc 41 is solid connected with amechanical housing (not shown) to the receptacle of the apparatus. The
attachment annular disc 41 exhibits screw connections 10 on its outer periphery.
Fig 15b shows the fastener 4 in a view toward the shaft axis 50. The attachment
annular disc 41 exhibits four screw connections 10 on its scope to the attachment
at the mechanical housing, the hollow cylinder 40 exhibits over its scope a
multiplicity of screw connections 10 to the attachment of the inner stator 2. Fig
16 shows a view of the rotor 1, which is 10 arranged stationary by means of
screw connections on the shaft 5. The rotor 1 consists of two from each other
separate arranged rotor drums, in whose outer surface circular bores are mounted,who serve 7 for the receptacle of the magnets. The rotor 1 does not consist of
magnetic material (e.g. AI, cu). The distance of the rotor drums amounts to 15
mm to each other. The rotor drums exhibit an outside diameter of 165 mm, an
height of 70 mm and a wall thickness of 26 mm. Each of the rotor drums exhibits
a ringscheibenfrmige top surface 102, in which two or more uniform on a
circumference are regarding the center of the top surface 102 distributed dipole
8/11/2019 Motor mag pantentado ''1.docx
35/43
35
magnets 700 arranged. The magnetic dipole axle of these dipole magnets 700
runs parallel to the shaft axis 50.
Fig 17a shows a schematic view of one of the rotor drums of the rotor 1 and the
inner stator 2, whereby the view is vertical to the shaft axis 50. The rotor 1 is 10
connected stationary by means of screw connections with the shaft 5. The shaft 5is by means of a ball bearing of rotatable in the inner stator 2 stored. The rotor 1
surrounds the inner stator 2 trommelbzw. bell-shaped. The rotor 1 exhibits an
hollow cylinder 101, which becomes 102 completed on of the inner stator 2 an
opposite side by the top surface. There the inner stator 2 by the fastener 4 solid (=
not rotatable) held becomes, the rotated rotor 1 with its hollow cylinder 101
around the inner stator 2. The hollow cylinder 101 of the rotor 1 is of the inner
stator 2 by an annular air gap G1 separate. The hollow cylinder 101 of the rotor 1
exhibits bores, are 7 used into whom magnets. The top surface 102 of the rotor 1
exhibits likewise bores, are 700 used into whom magnets.
Fig. 17b points a schematic representation of the possible orientations of the
dipole magnets 7 of the rotor 1 in a viewing direction parallel to the shaft axis 50.
The magnetic dipole axle 70 of the rotor magnets 7 runs in a plane, which is
vertical 50 arranged to the shaft axis, i.e. within the imaging plane. The angle ss
between the magnetic dipole axle 70 and a tangent 71 to the outer periphery of
the hollow cylinder 101 of the rotor 1 by the point, at which the dipole axle 70
breaks through the outer periphery of the hollow cylinder 101, knows values of
14 [deg.] to 90 [deg.] exhibit.
Fig 18a shows a development of the outer surfaces of the two drum halves of the
rotor 1 along in Fig. 16 direction indicated XY. Fig 18a shows on the left of the
left drum half and on the right of the right drum half, which is symmetrical
formed to each other. The development extended itself along the direction x Y,
like in fig 16 indicated. In vertical 50 planes arranged to the shaft axis run series
701 to 708 from magnets 7. Everyone of the series 701 to 708 is somewhat offset
to an adjacent row, so that toward the shaft axis 50 a zigzag arrangement of the
magnets 7 arises.
Fig 18b shows an enlarged cutout of the development of the magnets 7represented in fig 18a. The centers of the magnets 7 within the series 705, 706
are in a constant distance f from each other. The distance between two adjacent
rows 705, 706 is a so large selected that in fig the 18b illustrated arrangement
with constant magnet distance D results. Two magnets 7051, 7052 in the series
705 are 706 so arranged that the centers of the three magnets 7051, regarding
them an associated magnet 7061 in the adjacent row, 7052, 7061 stretch a
8/11/2019 Motor mag pantentado ''1.docx
36/43
36
gleichschenkeliges triangle with legs of the length D and a third side (base) of the
length f. This relationship applies to all magnets 7 in all series 701 to 708. The
magnets 7 cannot only, as shown, a circular cross section to exhibit, but also
other forms, for example square or hexagonal.
The distance D lies in a range of approx. 3 mm up to 50 mm. Particularlyprefered is a distance of 5 mm. The distance f lies in a range of approx. 10 mm
up to 70 mm.
Fig 19a points a longitudinal section by the mechanical housing to the receptacle
of the apparatus, i.e. a section parallel to the shaft axis 50. The mechanical
housing covers the fastener 4 to the receptacle of the inner stator 2, guide means
19 to the guide of the slidable halves of the outside stator 3, as well as a
transmission shaft 14 rotatable by means of a crank to the displacement of the
halves of the outside stator 3 regarding the rotor and/or. inner stator. The
transmission shaft 14 exhibits two threaded rods, which exhibit threads moving
in opposite directions (Rechtsund left-hand thread) to each other. Thus the two
halves of the outside stator 3 can become in symmetrical manner moving in
opposite directions uniform moved to each other or apart. Those Guide means 19
sit on the transmission shaft 14 and regarding the fastener 4 outward or inward
will in this way proceed. The frames 9 of the outside stator 3 are 19 solid
connected with the guide means.
The mechanical housing exhibits an height from 400 to 600 mm, a width of 400
mm, and a depth of 530 mm.
Fig 19b shows a section by the outside stator 3, whereby the cutting plane
vertical to the shaft axis 50 runs. The outside stator 3 exhibits annular arranged
non magnetic mounting elements 18, between those magnets 6 arranged is. From
reasons of clarity some the magnets 6 shown are only exemplary. The person
skilled in the art it is clearer that the magnets are 6 over the whole circumference
of the outside stator 3 arranged. The magnets 6 and the not magnetic mounting
elements 18 are so dimensioned the fact that they result in an hollow cylinder,
whose central axis toward the shaft axis 50 runs in the assembled state. The
magnetic dipole axles 60 of the magnets 6 lie in planes, which run vertical to theshaft axis 50. An angle y between the magnetic dipole axle 60 and a tangent 61 to
the outer periphery of the hollow-cylindrical outside stator 3 by the point, at
which the magnetic dipole axle 60 breaks through the outer periphery, lies in a
range of values of 14 [deg.] to 90 [deg.]. The outside stator 3 is 19 connected
with the guide means, which are for their part 20 slidable stored on attachment
columns.
8/11/2019 Motor mag pantentado ''1.docx
37/43
37
Fig 20 points an oblique view of the mechanical housing to the receptacle of the
apparatus. The mechanical housing exhibits a housing plate 21a, 21b, which is 20
connected by four attachment columns with one another at both faces ever. In the
central plane between the two housing plates 21a, 21 b the attachment disk 4 is to
the receptacle of the inner stator 2. In the centers of the housing plates 21a, 21bone bore each is for the execution of the shaft 5. On the four attachment columns
20 the guide means are 19, at which the halves of the outside stator are 3 fixed,
slidable arranged. Likewise between the two housing plates 21a and 21 b the
threaded shaft 14 (not shown) runs to the symmetrica Displacement of the guide
means 19, and thus the halves of the outside stator 3 mounted on it.
Fig 21 shows a scheme, which the relative disposition of the magnets 6 of the
outside stator 3, which shows magnets 7 of the rotor 1 and the magnets 8 of the
inner stator 2 in a prefered embodiment. The arrangement refers to a
constellation, with which the two halves of the outside stator to each other are as
far 3 as possible shifted. In the case of this constellation a complete coverage of
the three described magnet-planar results. That north pole of the dipole magnets
6, 7, 8 is with the letter N, that south pole with the letter S indicated.
The air gap G1 between the outer periphery of the inner stator 2 and the inner
periphery of the rotor 1, as well as the air gap G2 between the outer periphery of
the rotor 1 and the inner periphery of the outside stator 3 can become in any
range with a width from 3 to 50 mm selected.
Fig 22 points a schematic arrangement of the three magnet-planar 6, 7, 8 to the
shaft axis 50 vertical in a cutting plane B-B, as in Fig. 11 indicated. In a prefered
embodiment 2 uniform are over the outer periphery of the inner stator of 2
distributed ten magnets 8 on the inner stator. The magnets 6 point in the cutting
plane B-B, i.e. vertical to the shaft axis 50, a trapezoidal cross section up. Each of
the two rotor halves exhibits ever four series to sixteen magnets each 7, which
exhibit a circular cross section in a cutting plane vertical to the their magnetic
dipole axle. The outside stator 3 exhibits ever eighteen magnets 6 on each of its
two halves, which are uniform over the scope each of the two stator halves of
distributed. The magnets 6 exhibit a trapezoidal cross section in the cutting planeB-B. In Fig. 22 is a prefered orientation of the dipole magnets 6, 7, 8 shown. That
north pole of the dipole magnets 6, 7, 8 is with the letter N, that south pole with
the letter S indicated.
The ratio of the number of the magnets 8 of the inner stator 2, the number of the
magnet rows on the two rotor drums of the rotor 1 and the number of the magnets
8/11/2019 Motor mag pantentado ''1.docx
38/43
38
6 on the two stator halves of the outside stator 3 becomes a prefered selected
indicated in table I as.
Table I
Fig 23 shows particularly favourable dimensions of the used magnets.
Fig 23a shows a prefered dimension magnets 6 of the outside stator 3. The
magnet 6 exhibits a length of 75 mm toward the shaft axis 50, the height of the
trapezoidal cross section amounts to 50 mm. The baseline of the trapezoid
exhibits a length of 25 mm and those the baseline opposite side a length of 20mm.
Fig 23b shows a prefered dimension magnets 8 of the inner stator 2. The magnet
8 exhibits a length of 100 mm toward the shaft axis 50, the height of the
trapezoidal cross section amounts to 25 mm. The baseline of the trapezoid
exhibits a length of 25 mm and those the baseline opposite side a length of 10
mm.
Fig 23c shows a prefered embodiment magnets 7 of the rotor 1. The magnet 7
exhibits a circle-cylindrical geometry, whereby the magnetic dipole axis 70 withMittelbzw. Longitudinal axis of the circular cylinder collapses. The cylinder
exhibits an height of 20 mm and a diameter of 20 mm.
Concerning the dimensions of the magnets it is to be noted that with other
favourable embodiments the indicated length specifications in a range of
plus/minus 50 percent can vary. There is however also embodiments more
8/11/2019 Motor mag pantentado ''1.docx
39/43
39
conceivable, with which the dimensions of the magnets lie outside of this range.
Reference symbol list
1 rotor
2 stator, inner stator
3 outside stator
4 fastener, - disk
5 shaft
6 dipole magnets of the outside stator 3
7 dipole magnets of the rotor 1
8 dipole magnets (inner) of the stator 2
9 frames
10 screw connection
11 ball bearing
12 core of the inner stator 2 (= inner stator core)
13 end cap
14 transmission shaft
15 recesses of the rotor 1
16 groove
18 mounting elements
19 guide means
20 attachment columns
8/11/2019 Motor mag pantentado ''1.docx
40/43
40
21a, 21 b housing plates
22 recesses of the stator 2
23 distance of the recesses 22
40 hollow cylinders
41 attachment annular disc
50 shaft axis
51 plane, vertical to the shaft axis 50
60 magnetic dipole axles of the dipole magnets 6
61 tangent
70 magnetic dipole axles of the dipole magnets 7
71 tangent
80 magnetic dipole axles of the dipole magnets 8
81 tangent of 101 hollow cylinders of the rotor 1
102 top surface of the rotor 1
120 circular cylinders of the inner stator core 12
121 ribs of the inner stator core 12,122 grooves of the inner stator core 12
125 base of the inner stator core 12
126 top surface of the inner stator core 12,150 threaded hole 511 first plane,vertical 50 512 second plane, vertical to the shaft axis, arranged to the shaft axis,
50 arranged
700 dipole magnets
701 - 708 series of magnets 7
8/11/2019 Motor mag pantentado ''1.docx
41/43
41
A inclination angle b pitch angle b1 of first pitch angles b2 of second pitch
angles
B16 width of the groove 16 C angle of attack D distance
D1A of outside diameters of the rotor 1
D11 of inner diameters of the rotor 1
DM6 distance
D15 diameter of the recesses 15 D16 outer diameters of the groove 16
D22 distance
E distance f distance
F1 first magnet sequences F2 second magnet sequences
G group of first magnet sequences F1 and/or. second magnet sequences F2
G1 air gap
G2 air gap
H height of J width k number of the first magnet sequences F1
M1 outer surface of the first circular cylinder Z1
M2 outer surface of the first circular cylinder Z2
M3 outer surface of the first circular cylinder Z3
M6 threaded hole
N north pole
P1, P2 of contact points
R2 radius
8/11/2019 Motor mag pantentado ''1.docx
42/43
42
S south pole
TM6 depth of the threaded hole M6
T16 depth of the groove 16
T22 depth
U scope
V displacement
Z1 of first circular cylinders
Z2 of second circular cylinders
Z3 of third circular cylinders [alpha], ss, [gamma], [delta], [delta] 1, [delta] 2,
[delta], [delta] 1, [lambda], [xi], [phi] angles
Your Support Maintains this Service --
BUY
T heRex Research ivilization Kit
... It's Your Best Bet & Investment in Sustainable Humanity on Earth ...Ensure & Enhance Your Survival & Genome Transmission ...
Everything @ rexresearch.com plus Bonus Files on a Data DVD !
ORDER PAGE
http://www.rexresearch.com/order.htmhttp://www.rexresearch.com/order.htmhttp://www.rexresearch.com/order.htm8/11/2019 Motor mag pantentado ''1.docx
43/43
>
Rex Research, POB 19250, Jean, NV 89019 USA