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EP 0 383 450 B1 |
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EUROPEAN PATENT SPECIFICATION |
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Mention of the grant of the patent: |
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13.10.1993 Bulletin 1993/41 |
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Date of filing: 29.01.1990 |
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Magnetic rolling apparatus
Magnetische Walzvorrichtung
Dispositif magnétique pour laminer
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Designated Contracting States: |
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DE FR GB IT |
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Priority: |
15.02.1989 JP 35483/89
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Date of publication of application: |
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22.08.1990 Bulletin 1990/34 |
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Proprietor: BELLMATIC LIMITED |
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Higashikurume City, Tokyo (JP) |
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Inventor: |
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- Suzuki, Hideo,
c/o Bellmatic Limited
Higashikurume City, Tokyo (JP)
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Representative: Hillier, Peter et al |
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Reginald W. Barker & Co.,
Chancery House,
53-64, Chancery Lane London, WC2A 1QU London, WC2A 1QU (GB) |
(56) |
References cited: :
DE-A- 3 404 833 DE-B- 2 236 247 GB-A- 2 143 302
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DE-B- 1 574 294 DE-B- 2 742 661
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Note: Within nine months from the publication of the mention of the grant of the European
patent, any person may give notice to the European Patent Office of opposition to
the European patent
granted. Notice of opposition shall be filed in a written reasoned statement. It shall
not be deemed to
have been filed until the opposition fee has been paid. (Art. 99(1) European Patent
Convention).
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[0001] This invention relates according to the precharacterising part of claims 1 and 2
respectively to an apparatus for rolling metal foil, cloth, paper, on the like, for
calendering.
2. Description of the Related Art
[0002] Referring to Fig. 14, one conventional way of rolling metal foil or cloth for calendering
is explained. Numerals 1, 2 and 3 denote rollers, numerals 5, 6 and 7 denote guide
rollers, and numeral 4 denotes a workpiece. The workpiece 4 is guided by the guide
rollers 5, 6 and 7 and rolled by the rollers 1, 2 and 3 respectively such that the
workpiece 4 is flattened or calendered. Referring to Fig. 15, one conventional way
of pressing the workpiece 4 is explained. A hydraulic pump 8 presses a bearing 1a
which supports the roller 1 such that the workpiece 4 is pressed between rollers 1
and 2. It is also possible to press upwardly on a bearing 2a which supports the roller
2 such that the workpiece 4 is pressed in between rollers 1 and 2.
[0003] However, when rollers 1, 2 and 3 are made of metal, they tend to deflect as shown
in Fig. 15 because of the pressure applied to the bearings 1a or 21. So, it is impossible
to clamp the workpiece between the rollers with a uniform pressure, resulting in poor
performance.
[0004] Further, the pressure exerted by the hydraulic pump 8 against the bearings 1a or
2a cannot always be maintained at a constant value, so the unbalanced pressure causes
an unbalanced rolling as shown in Fig. 17. When one of the rollers 1, 2 and 3 is of
an elastic material, for instance, plastic or the like, its surface is easily scratched
resulting in a degraded workpiece.
[0005] Further, since a plastic roller is not heat resistant, when the workpiece is heated
during the rolling process, a plastic roller will deteriorate. To avoid the aforementioned
disadvantages, some detecting means to detect the scratches in the workpiece is required,
as well as frequent replacement of the deteriorated roller resulting
[0006] DE-A-3404833 representing the closest prior art discloses rolling apparatus comprising
two parallel work rollers, adapted to press a workpiece passing between the two rollers.
At least one of the work rollers is movable and means are provided for controllably
urging the or each movable roller towards the other to press the workpiece.
[0007] According to one aspect of the present invention, there is provided a rolling apparatus
comprising a main roller rotatably supported by a frame and a pressure roller rotatably
supported by the frame, the pressure roller being urged towards the main roller under
a force, the workpiece being arranged to pass between the pressure and main rollers
so as to be pressed, characterised in that the main roller is of non-magnetic material
and is hollow, in that a magnet is provided inside the hollow main roller and in that
the pressure roller is of magnetic material so that the pressure roller is urged by
said magnet towards the main roller to provide said force.
[0008] According to another aspect of the present invention, there is provided a rolling
apparatus comprising a frame and two cylindrical main rollers rotatably supported
adjacent and parallel to each other by the frame, at least one of said main rollers
being mounted so as to be movable towards and away from the other main roller and
being urged towards the other main roller under a force, the workpiece being arranged
to pass between the main rollers so as to be pressed, characterised in that the main
rollers are of magnetic material, in that the frame has two yokes, each main roller
being disposed adjacent to a respective yoke, each yoke having a solenoid wound thereon
for magnetising the respective yoke by generating magnetic flux perpendicular to the
direction of motion of the workpiece and along a line through the centres of the two
main rollers, one of the yokes being magnetised as a north and the other as a south
pole, the main rollers being magnetised by the magnetic flux generated by the solenoids
so as to be attracted to each other by said force.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009] The above and other objects, features and advantages of the present invention will
become more apparent from the following description of the preferred embodiment thereof
taken in conjunction with the accompanying drawings in which like reference numerals
denote like members and of which:
Fig. 1 is a side view of a rolling apparatus according to the first embodiment of
the present invention.
Fig. 2 is a partial section view of the rollers shown in Fig. 1;
Fig. 3 is a partial section view of a yoke portion in a main roller shown in Fig.
2;
Fig. 4 is a perspective section view of a yoke shown in Fig. 3;
Fig. 5 is an explanatory view showing a magnetic flux line along an axial direction,
and around a circumference of a yoke shown in Fig. 3 and Fig. 4;
Fig. 6 is a perspective view of a yoke in a main roller according to the second embodiment
of the present invention;
Fig. 7 is an explanatory view showing a magnetic flux along an axial line and around
a circumference of the yoke shown in Fig-. 6;
Fig. 8 is a perspective view of a yoke according to the third embodiment of the present
invention;
Fig. 9 is an explanatory drawing showing magnetic flux along an axial line and around
a circumference of a yoke shown in Fig. 8;
Fig. 10 is a side sectional view of a rolling apparatus according to the fourth embodiment
of the present invention;
Fig. 11 is a side section view of a rolling apparatus according to the fifth embodiment
of the present invention;
Fig. 12 is a side sectional view of a rolling apparatus according to the sixth embodiment
of the present invention;
Fig. 13 is a side view of a rolling apparatus according to the seventh embodiment
of the present invention;
Fig. 14 is a side sectional view of a conventional rolling apparatus;
Fig. 15, Fig. 16, Fig. 17 are explanatory drawings showing inconveniences of operation
associated with a conventional rolling apparatus.
DETAILED DESCRIPTION OF THE INVENTION
[0010] Referring to the accompanying drawings, the preferred embodiments of the present
invention will be described in detail.
[0011] Referring to Figs. 1 to 5, the first embodiment of the present invention will be
described hereinafter. Numeral 11 (Fig. 2) denotes a main roller which is tubularly
shaped and is placed in opposition relation with other pressure rollers and made of
non-magnetic materials. The roller rim is preferably thin so that a sufficient magnetic
attractive force may be established between the main roller 11 and a pressure roller
13. Although a thin roller rim is preferable, it should be mechanically strong enough
to undergo the rolling pressure without excessive deterioration. The main roller 11
is rotatably supported by a frame 12. A suitable number of the pressure rollers 13
which are made of magnetic material are provided around the circumference of the main
roller 11. The pressure rollers 13 are rotatably supported by the frame and in pressing
relation against the main roller 11. In a hollow portion of the main roller 11, a
yoke 14 which consists of magnetic material is inserted and both ends of the yoke
14 are fixed to the frame 12. The yoke 14 is provided with several solenoids 22 which
are in opposing relation to the pressure rollers 13. Magnetic flux caused by these
solenoids 22 is shown in Fig. 5. A suitable number of guide roller 16 are provided
in planetary relation to the main roller 11, and these guide rollers 16 are rotatably
supported by the frame 12. Referring to Fig. 1, a workpiece 17 is inserted and passed
between the main roller 11 and the pressure roller 13 being guided by the respective
guide roller 16. Repeating several equivalent path ways, the workpiece 17 is finally
drawn out. The yoke 14 is provided with salient poles 21a which establish a magnetic
pole and also with grooves 21b which accommodate the solenoids 22 shaped annularly
with the winding coil accommodated therein. The magnetic flux in the yoke, established
by the solenoids 22, is shown in Fig. 5. Along the axial line of yoke 14, N-pole and
S-pole are alternately established, and around the circumference of the yoke 14, N-pole
or S-pole is established. In this drawing, N-pole is shown. It is also possible to
eliminate the guide rollers so that the workpiece 17 is advanced along the circumference
of the main roller 11 being inserted and pressed between the main roller 11 and the
presser roller 13. When the main roller 11 is rotated by any driving source, the workpiece
17 is rolled and advanced. During the rolling process, each pressure roller 13 is
attracted to the main roller 11 because of a magnetic force established by the solenoids
22. The pressure roller 13 is rotated by the fractional force between the pressure
roller 13 and the workpiece 17.
[0012] Thus, the pressing of workpiece between the pressure rollers 13 and the main roller
11 is conducted by the magnetic force established by the solenoids 22, and the magnetic
force is controlled by regulating the electric direct current to the solenoids.
[0013] Referring to Fig. 6 and Fig. 7 the second embodiment of the present invention will
be described. A yoke 26 is provided with solenoids 25 and with salient poles 26a which
establish the magnetic poles and with grooves 26b in which solenoids are accommodated.
The magnetic flux in the yoke 26 is shown in Fig. 7. Along the axial line of the yoke
26, N-pole and S-pole are alternately established, and around the circumference of
the yoke 26, N-pole or S-pole is established. In this drawing, N-pole is shown.
[0014] Referring to Fig. 8 and Fig. 9, the third embodiment of the present invention will
be described. A yoke 31 is provided with solenoids 32 and salient poles 31b established
by the solenoids and grooves 31a grooved in parallel with the axial line of yoke such
that the solenoids 32 are accommodated therein. Under such a construction of the yoke
31, the magnetic flux will be as shown in Fig. 9. Along the axial line of yoke 31,
N-pole or S-pole is established. In this drawing Fig. 9, N-pole is shown. Around the
circumference of yoke 31, N-pole or S-pole is established. According to the above
described three embodiments, the yokes 14, 26 and 31 establish a uniform magnetic
attractive force in a direction perpendicular to the axis of a yoke such that the
presser roller is attracted to the main roller with a uniform attractive force established
along its axial line throughout. The uniform magnetic attractive force can be easily
controlled by regulating the electric current to the solenoids. In this manner the
pressing due to the pressure roller 12 can be adjusted. It is also possible to use
a permanent magnet in lieu of solenoids 22, 25 and 32.
[0015] Referring to Fig. 10, the fourth embodiment of the present invention will be described.
Two main rollers 36, 37 are placed in opposing relation and the distance between these
two rollers is adjustable. Electromagnets 38 and 39 are disposed such that an attractive
force between these two main rollers 36, 37 is established. To establish the attractive
force, the main rollers 36, and 37 are made of magnetic material and are adapted to
be moved in the direction of the attractive force and rotatably supported by a frame
40 and 41. One of the main rollers is driven by a belt 42 connected to a drive source
43. The electric magnets 38 and 39 are provided with yokes 44, 45 respectively which
are fixed to the frames 40, 41. The yokes 44, 45 are provided with solenoids 46, 47
respectively. Salient poles 44a, 45a are placed adjacent to the main rollers 36 and
37 respectively. It is so adapted that when the electromagnet 39 establishes a N-pole,
the electromagnet 38 establishes a S-pole so that both main rollers 36 and 37 attract
each other. According to the fourth embodiment, when a workpiece 49 is inserted between
the main rollers 36 and 37, and solenoids 46 and 47 are energized, the main rollers
36 and 37 approach each other and clamp the workpiece 49. Further, when the drive
motor 43 energizes, the main roller 36 rotates and the workpiece 49 is advanced by
the fractional force established between the workpiece and the main roller. Thus the
workpiece is rolled and the pressing force by these main rollers is controlled by
regulating the electric current to the solenoids 46 and 47.
[0016] Referring to Fig. 11, the fifth embodiment of the present invention will be explained.
A middle roller 50 is placed between main rollers 36 and 37. The middle roller 50
is made of a magnetic material, and is attracted to, in contacting relation with,
both main rollers 36, 37 when solenoids 46, 47 are energized. When the main rollers
36 is rotated by a belt 42 driven by a motor 43, a workpiece 49 clamped between the
middle roller 50 and the main rollers 36 and 37 is advanced by the fractional force
established between the middle roller 50 and the main rollers 36 and 37. According
to the fifth embodiment, several guide rollers 48 are placed such that the workpiece
49 is guided between the middle roller and the main roller. When solenoids 46 and
47 are energized, the main roller 36 and 37 tend to approach each other, and the workpiece
49 is pressed between the main roller and the middle roller. Further, when the main
roller 36 rotates being driven by a belt 42 connected to a motor 43, the workpiece
is advanced by the frictional force established between the main roller and the middle
roller. The pressing force against the workpiece can be controlled by regulating the
electric current to the solenoids 46 and 47.
[0017] Referring to Fig. 12 the sixth embodiment of the present invention will be described.
Two middle rollers 50a, 50b made of a magnetic material are placed between main rollers
36, and 37. The construction of the sixth embodiment is very similar to that of the
fifth embodiment. A workpiece 49 is inserted between the middle roller 50a and a main
roller 37 and is drawn out and finally inserted between the middle roller 50a and
a main roller 36. When solenoids 46, and 47 energize, an attractive force is established
between the main rollers 36, and 37 and between the middle roller 50a, 50b. When the
main roller 36 is rotated by a belt connected to a motor 43, the workpiece 49 is advanced
by the friction force established between the workpiece and the main roller. The pressing
force against the workpiece can be controlled by regulating the electric current to
the solenoids 46, and 47.
[0018] Referring to Fig. 13, the seventh embodiment of the present invention will be described.
One object of the seventh embodiment is to increase the quantity of rolling steps.
Several auxiliary rollers 51 are disposed between main rollers 36, and 37. The auxiliary
rollers 51 are made of magnetic material. Increasing the quantity of auxiliary rollers
51 cause the magnetic force established between solenoids 46, and 47 to be weakened.
To strengthen the weakened magnetic force, auxiliary solenoids 52 are placed proximate
the auxiliary rollers 51. The auxiliary rollers 51 are rotatably supported by frames
53 and are adapted to be moved vertically. The frames 53 are disposed between the
main rollers 36, and 37, and are replaceable. By providing yokes on the frames 53
or substituting the frame for the yoke, the auxiliary solenoids 52 can be eliminated.
It is also possible to establish the necessary magnetic force auxiliary solenoids
52. The direction of magnetic force established by the auxiliary rollers 51 is in
accordance with the direction of magnetic force established by the solenoids 52. According
to the seventh embodiment, as shown in Fig. 13, several guide rollers 48 are located
at suitable positions, and a workpiece 49 is inserted between the main roller 37 and
the auxiliary roller 51, and further between the main roller 36 and the auxiliary
roller 51 being rolled and guided steppingly. When the solenoids 46, and 47 and the
auxiliary solenoids 52 are energized, the attractive force between the main rollers
36, and 37 and between the auxiliary rollers 51 are established. When the main roller
36 is rotated by a belt 42 connected to a drive motor 43, the workpiece 49 is rolled
by the main rollers and auxiliary rollers, guided by guide rollers. The workpiece
49 is advanced by the frictional force established between the workpiece and the opposing
roller. In this embodiment, the solenoids 46, and 47 and the auxiliary solenoids 52
are used but these solenoids can be replaced by permanent magnets. According to the
aforementioned embodiments, the presser rollers undergo the forced drive.
[0019] As aforementioned, according the present invention of a rolling apparatus applying
a magnetic force between the main roller and the presser roller, uniform pressure
can be applied perpendicularly on the workpiece clamped between the main roller and
the pressure roller and the pressure can be freely controlled by regulating the electric
current to the solenoid.
[0020] Further, where both the main roller and the pressure roller are made of metals, the
workpiece is pressed between the main roller and the presser roller by the magnetic
attractive force established therebetween, and the problem of shorter roller life
is eliminated although the pressing force is considerably strong, and the frequency
of exchanging rollers becomes less because the rollers are made of hard metals.
[0021] As many apparently widely different embodiments of this invention amy be made without
departing from the spirit and scope thereof, it is to be understood that the invention
is not limited to the specific embodiments thereof except as defined in the appended
claims.
1. A rolling apparatus comprising a main roller (11) rotatably supported by a frame and
a pressure roller (13) rotatably supported by the frame, the pressure roller (13)
being urged towards the main roller (11) under a force, the workpiece being arranged
to pass between the pressure and main rollers so as to be pressed, characterised in
that the main roller is of non-magnetic material and is hollow, in that a magnet (22)
is provided inside the hollow main roller (11) and in that the pressure roller (13)
is of magnetic material so that the pressure roller (13) is urged by said magnet (22)
towards the main roller to provide said force.
2. A rolling apparatus comprising a frame (40, 41) and two cylindrical main rollers (36,
37) rotatably supported adjacent and parallel to each other by the frame (40, 41),
at least one of said main rollers being mounted so as to be movable towards and away
from the other main roller and being urged towards the other main roller under a force,
the workpiece (49) being arranged to pass between the main rollers (36, 37) so as
to be pressed, characterised in that the main rollers (36, 37) are of magnetic material,
in that the frame has two yokes (44, 45), each main roller (36, 37) being disposed
adjacent to a respective yoke (44, 45), each yoke having a solenoid (46, 47) wound
thereon for magnetising the respective yoke by generating magnetic flux perpendicular
to the direction of motion of the workpiece (49) and along a line through the centres
of the two main rollers (36, 37), one of the yokes being magnetised as a north and
the other as a south pole, the main rollers (36, 37) being magnetised by the magnetic
flux generated by the solenoids (46, 47) so as to be attracted to each other by said
force.
3. A rolling apparatus according to claim 2, characterised by comprising a middle roller
(50) rotatably supported on the frame (40, 41) and disposed adjacent to each of the
two main rollers (36, 37), and a plurality of guide rollers (48) mounted rotatably
on said frame (40, 41) at positions remote from the middle roller (50), the workpiece
(49) being guided by the guide rollers (48) between one of the two main rollers (40,
41) and the middle roller (50) and subsequently guided by the guide rollers (48) between
the main roller and the middle roller (50).
4. A rolling apparatus according to claim 2, characterised by comprising two middle rollers
(50a, 50b) rotatably supported on the frame, each middle roller being disposed adjacent
to said two main rollers (36, 37), and a plurality of guide rollers (48) rotatably
mounted on the frame (40, 41) at positions remote from the middle rollers (50a, 50b),
the workpiece being guided by the guide rollers (48) between one of the two main rollers
(36, 37) and the two middle rollers and then subsequently guided between the other
main roller and the two middle rollers.
5. A rolling apparatus according to claim 2, characterised by comprising a plurality
of auxiliary rollers (51) of magnetic material disposed one after the other between
the two main rollers (36, 37), a plurality of auxiliary frames (53) disposed between
the two main rollers and each rotatably supporting a respective auxiliary roller (51),
a plurality of solenoids (52) each disposed on a respective auxiliary frame (53) for
magnetising the respective auxiliary roller (51), and a plurality of guide rollers
(48) rotatably supported on the frame at locations remote from the auxiliary rollers
(51), the workpiece (49) being guided by the guide rollers (48) between one of the
two main rollers and one of the auxiliary rollers (51) and then guided by the guide
rollers (48) between each pair of auxiliary rollers (51) until it passes between the
other main roller and the adjacent auxiliary roller (51).
6. A rolling apparatus according to any of claims 2 to 5, characterised in that the pressing
force applied to the workpiece (49) can be controlled by controlling the electric
current supplied to the solenoids (46, 47).
1. Appareil de cylindrage comprenant un cylindre principal (11) supporté à rotation par
un bâti et un cylindre de pression (13) supporté à rotation par le bâti, le cylindre
de pression (13) étant sollicité vers le cylindre principal (11) sous l'effet d'une
force, la pièce à travailler étant agencée de manière à passer entre le cylindre de
pression et le cylindre principal de façon à être comprimée,
caractérisé en ce que le cylindre principal est en matériau non-magnétique et est
creux, en ce qu'un aimant (22) est disposé à l'intérieur du cylindre principal creux
(11), et en ce que le cylindre de pression (13) est en matériau magnétique, de sorte
que le cylindre de pression (13) est sollicité par ledit aimant (22) vers le cylindre
principal pour exercer ladite force.
2. Appareil de cylindrage comprenant un bâti (40, 41) et deux cylindres principaux (36,
37) supportés à rotation par le bâti (40, 41), adjacents l'un à l'autre et parallèles
entre eux, au moins l'un desdits cylindres principaux étant monté de façon à être
mobile pour se rapprocher ou s'écarter de l'autre cylindre principal et étant sollicité
vers l'autre cylindre principal sous l'effet d'une force, la pièce à travailler étant
agencée de manière à passer entre les cylindres principaux (36, 37) afin d'être comprimée,
caractérisé en ce que les cylindres principaux (36, 37) sont en matériau magnétique,
et en ce que le bâti est pourvu de deux culasses (44, 45), chaque cylindre principal
(36, 37) étant disposé près d'une culasse respective (44, 45), chaque culasse étant
pourvue d'un sélénoïde (46, 47) qui y est enroulé pour aimanter la culasse respective
en engendrant un flux magnétique perpendiculaire à la direction de mouvement de la
pièce à travailler (49) et le long d'une ligne passant par les centres des deux cylindres
principaux (36, 37), l'une des culasses étant aimantée pour former un pôle nord et
l'autre pour former un pôle sud, les cylindres principaux (36, 37) étant aimantés
par le flux magnétique engendré par les sélénoïdes (46, 47) de façon à être attirés
l'un vers l'autre par ladite force.
3. Appareil de cylindrage selon la revendication 2, caractérisé en ce qu'il comprend
un cylindre intermédiaire (50), supporté à rotation sur le bâti (40, 41) et adjacent
à chacun des deux cylindres principaux (36, 37), et une pluralité de cylindres de
guidage (48) montés à rotation sur ledit bâti (40, 41) à des emplacements éloignés
du cylindre intermédiaire (50), la pièce à travailler (49) étant guidée par les cylindres
de guidage (48) entre l'un des deux cylindres principaux (40, 41) et le cylindre intermédiaire
(50), et étant ensuite guidée par les cylindres de guidage (48) entre le cylindre
principal et le cylindre intermédiaire (50).
4. Appareil de cylindrage selon la revendication 2, caractérisé en ce qu'il comprend
deux cylindres intermédiaires (50a, 50b), supportés à rotation sur le bâti, chaque
cylindre intermédiaire étant adjacent auxdits deux cylindres principaux (36, 37),
et une pluralité de cylindres de guidage (48) montés à rotation sur le bâti (40, 41)
à des emplacements éloignés des cylindres intermédiaires (50a, 50b), la pièce à travailler
étant guidée par les cylindres de guidage (48) entre l'un des deux cylindres principaux
(36, 37) et les deux cylindres intermédiaires, et étant ensuite guidée entre l'autre
cylindre principal et les deux cylindres intermédiaires.
5. Appareil de cylindrage selon la revendication 2, caractérisé en ce qu'il comprend
une pluralité de cylindres auxiliaires (51) en matériau magnétique, disposés l'un
après l'autre entre les deux cylindres principaux (36, 37), une pluralité de bâtis
auxiliaires (53) disposés entre les deux cylindres principaux et supportant chacun
à rotation un cylindre auxiliaire respectif (51), une pluralité de sélénoïdes (52)
disposés chacun sur un bâti auxiliaire respectif (53) pour aimanter le cylindre auxiliaire
respectif (51), et une pluralité de cylindres de guidage (48) supportés à rotation
sur le bâti à des emplacements éloignés des cylindres auxiliaires (51), la pièce à
travailler (49) étant guidée par les cylindres de guidage (48) entre l'un des deux
cylindres principaux et l'un des cylindres auxiliaires (51), et étant ensuite guidée
par les cylindres de guidage (48) entre chaque paire de cylindres auxiliaires (51)
jusqu'à ce qu'elle passe entre l'autre cylindre principal et le cylindre auxiliaire
adjacent (51).
6. Appareil de cylindrage selon l'une quelconque des revendications 2 à 5, caractérisé
en ce que la force de pression appliquée à la pièce à travailler (49) peut être réglée
en réglant le courant électrique amené aux sélénoïdes (46, 47).
1. Walzvorrichtung mit einer drehbar mittels eines Rahmens gelagerten Hauptwalze (11)
und einer drehbar mittels des Rahmens gelagerten Preßwalze (13), wobei die Preßwalze
(13) unter einer Kraft gegen die Hauptwalze (11) getrieben wird und wobei das Werkstück
so angeordnet ist, daß es zwischen der Preßwalze und der Hauptwalze hindurchläuft,
um zusammengepreßt zu werden, dadurch gekennzeichnet, daß die Hauptwalze aus nichtmagnetischem
Werkstoff besteht und hohl ist, daß innerhalb der hohlen Hauptwalze (11) ein Magnet
(22) vorgesehen ist, und dadurch, daß die Preßwalze (13) aus magnetischem Werkstoff
besteht, so daß die Preßwalze (13) mittels des Magneten (22) gegen die Hauptwalze
getrieben wird, um die Kraft zu erzeugen.
2. Walzvorrichtung mit einem Rahmen (40, 41) und zwei zylindrischen Hauptwalzen (36,
37), die drehbar nebeneinander und parallel zueinander mittels des Rahmens (40, 41)
gelagert sind, wobei wenigstens eine der Hauptwalzen so angebracht ist, daß sie in
Richtung auf die andere Hauptwalze und von dieser weg beweglich ist und unter einer
Kraft gegen die andere Hauptwalze getrieben wird, und wobei das Werkstück (49) so
angeordnet ist, daß es zwischen den Hauptwalzen (36, 37) hindurchläuft, um zusammengepreßt
zu werden, dadurch gekennzeichnet, daß die Hauptwalzen (36, 37) aus magnetischem Werkstoff
bestehen und daß der Rahmen zwei Joche (44, 45) aufweist, wobei jede Hauptwalze (36,
37) angrenzend an ein entsprechendes Joch (44, 45) angeordnet ist und wobei jedes
Joch eine darauf gewickelte Magnetspule (46, 47) aufweist, um das entsprechende Joch
zu magnetisieren, indem senkrecht zu der Bewegungsrichtung des Werkstücks (49) und
entlang einer Linie durch die Mitten der beiden Hauptwalzen (36, 37) ein magnetischer
Fluß erzeugt wird, wobei eines der Joche als Nordpol und das andere als Südpol magnetisiert
wird und wobei die Hauptwalzen (36, 37) mittels des durch die Magnetspulen (46, 47)
erzeugten magnetischen Flusses magnetisiert werden, so daß sie mittels der Kraft gegenseitig
angezogen werden.
3. Walzvorrichtung nach Anspruch 2, dadurch gekennzeichnet, daß sie eine Mittelwalze
(50), die drehbar an dem Rahmen (40, 41) gelagert und angrenzend an jede der beiden
Hauptwalzen (36, 37) angeordnet ist, und mehrere Leitwalzen (48), die in von der Mittelwalze
(50) entfernten Stellungen drehbar an dem Rahmen (40, 41) gelagert sind, aufweist,
wobei das Werkstück (49) mittels der Leitwalzen (48) zwischen einer der beiden Hauptwalzen
(36, 37) und der Mittelwalze (50) geführt ist und nachfolgend mittels der Leitwalzen
(48) zwischen der anderen Hauptwalze und der Mittelwalze (50) geführt ist.
4. Walzvorrichtung nach Anspruch 2, dadurch gekennzeichnet, daß sie zwei Mittelwalzen
(50a, 50b), die drehbar an dem Rahmen gelagert sind, wobei jede Mittelwalze angrenzend
an beide Hauptwalzen (36, 37) angeordnet ist, und mehrere Leitwalzen (48), die in
von den Mittelwalzen (50a, 50b) entfernten Stellungen drehbar an dem Rahmen (40, 41)
gelagert sind, aufweist, wobei das Werkstück mittels der Leitwalzen (48) zwischen
einer der beiden Hauptwalzen (36, 37) und den beiden Mittelwalzen geführt ist und
dann nachfolgend zwischen der anderen Hauptwalze und den beiden Mittelwalzen geführt
ist.
5. Walzvorrichtung nach Anspruch 2, dadurch gekennzeichnet, daß sie mehrere Hilfswalzen
(51) aus magnetischem Werkstoff, die hintereinander zwischen den beiden Hauptwalzen
(36, 37) angeordnet sind, mehrere Hilfsrahmen (53), die zwischen den beiden Hauptwalzen
angeordnet sind und jeweils eine entsprechende Hilfswalze (51) drehbar lagern, mehrere,
jeweils an einem entsprechenden Hilfsrahmen (53) angeordnete Magnetspulen (52) zum
Magnetisieren der entsprechenden Hilfswalze (51) und mehrere Leitwalzen (48), die
an von den Hilfswalzen (51) entfernten Stellen drehbar an dem Rahmen gelagert sind,
aufweist, wobei das Werkstück (49) mittels der Leitwalzen (48) zwischen einer der
beiden Hauptwalzen und einer der Hilfswalzen (51) geführt ist und dann mittels der
Leitwalzen (48) zwischen jedem Paar von Hilfswalzen (51) geführt ist, bis es zwischen
der anderen Hauptwalze und der angrenzenden Hilfswalze (51) hindurchtritt.
6. Walzvorrichtung nach einem der Ansprüche 2 bis 5, dadurch gekennzeichnet, daß die
auf das Werkstück (49) ausgeübte Preßkraft gesteuert werden kann, indem der den Magnetspulen
(46, 47) zugeführte elektrische Strom gesteuert wird.