TECHNICAL FIELD
[0001] This invention relates to a method of controlling a rotary spinning ring assembly
used in a textile machine including a ring rail and a spindle driving mechanism, such
as a ring spinning frame, a ring twisting frame or the like and comprising an annular
holder fixed in a horizontal posture on the ring rail, a ring rotary member supported
coaxially and rotatably through a bearing mechanism by the holder, a spindle arranged
coaxially in an inside space of the ring rotary member and driven by the spindle driving
mechanism, and a rotation speed control means for controlling a rotational speed of
the ring rotary member, and a related apparatus.
[0002] The term spinning machine as used herein includes all machines having a twisting
mechanism in which a twist is applied to a yarn by using a ring and the spindle, including
at least a machine for spinning a spun yarn, and further includes a draw twister used
for manufacturing a synthetic fiber and a twisting machine used for manufacturing
a covered yarn. Further all yarn like materials, such as a natural fiber yarn, a man-made
fiber yarn, a metallic wire or the like, can be used as a yarn for the present invention.
PRIOR ART
[0003] A twisting method using a spindle and ring is an ancient and well known technique.
The ring is fixed on a ring rail in this conventional twisting technique, and a rotary
ring which rotates to stably twist a yarn, even if a rotational speed of the spindle
is raised to increase productivity, is known. Several bearing mechanisms for rotatably
supporting a ring rotary member of a rotary spinning ring assembly using the rotary
ring in a spinning operation have been proposed. Namely, Japanese Examined Patent
Publication (Kokoku) No. 54-15934 discloses a slide type bearing mechanism having
a sliding face; Japanese Examined Patent Publications (Kokoku) No. 54-13528 and No.
54-15528 disclose a pneumatic bearing formed by injecting compressed air; and Japanese
Unexamined Patent Publication (Kokai) discloses a bearing using a ball bearing.
[0004] Nevertheless, the bearing mechanisms used in the conventional rotary spinning ring
assembly have various disadvantages; for example, when a machine such as a spinning
frame or the like is stopped and the rotation of the spindle is then stopped, a lowering
of a rotational speed of the ring rotary member is later than a lowering of a rotational
speed of the spindle, due to an inertial rotation of the ring rotary member, and thus
the ring rotary member may overrun the spindle. This overrun causes a generation of
snarls in a yarn being twisted, and a breaking of the yarn may be caused by the snarl
upon restarting the spinning operation. Accordingly although the rotary spinning ring
assembly is considered to an excellent method by which a high speed rotation of the
spindle, can be followed by the rotary spinning ring assembly, such an assembly has
not been put to practical use.
[0005] To solve the above problems, a method of lowering a spinning tension of a yarn and
relieving a torque of the ring rotary member including a traveller, by intermittently
lowering the rotational speed of the spindle when the machine is to be stopped, whereby
the machine is stopped after the rotational speed of the ring rotary member is lowered,
or a method of simultaneously braking all of the ring rotary members by applying a
friction thereto due to a grasping thereof upon stopping the machine, or of simultaneously
braking all of the ring rotary members by imposing a resistance thereon of a fluid
such as an oil, air or the like have been proposed, but although such methods can
stop all of the ring rotary members in the machine when full bobbins are stopped,
it is impossible to stop each ring rotary member, individually.
[0006] As described above, the rotary spinning ring assembly has been widely expected to
become a useful means of enabling a high speed rotation of the spindle, but a problem
of a control of the rotational speed of the ring rotary member, arising because a
rotational speed of the spindle becomes too high occurs also in a twisting operation
when all of the spindles in the machine are simultaneously stopped. Namely, the rotational
speed of the ring rotary member is increased in proportion to an increase of a rotational
speed of the spindle in the rotary spinning ring assembly, and accordingly, when the
rotational speed of the spindle is high, the inertia of the ring rotary member becomes
large. Therefore, when a twisted yarn is wound on a bobbin in the rotary spinning
ring assembly, a rotation speed of the traveller on a portion of the bobbin having
a larger diameter of a yarn layer is slightly bigger than that at a portion of the
bobbin having a smaller diameter of a yarn layer, and thus a stable winding operation
is achieved. When the ring rotary member has a much higher rotational speed, however,
the above balance is lost due to an inertial rotation of the ring rotary member, and
a rotational speed of the ring rotary member is synchronized with a maximum rotational
speed in a chase of the traveller on the ring rotary member, and thus an irregularity
in the spinning tension of the yarn arises. When a strong irregularity of the spinning
tension is repeated in the chase, problems such as a generation of fuzz, a generation
of nap by a scraping operation, and a lowering of a yarn quality, including a yarn
weakening which depends on a type of fiber used, are generated.
[0007] Further in a spinning machine having a plurality of a spindles, e.g., 400 spindles,
a twisting state at each spindle is different, as it is at each stage from a beginning
stage to a finishing stage, i.e., a full bobbin stage. Accordingly, to obtain a stable
twisting operation at all of the spindles in the machine the rotational speed of the
ring rotary member must be controlled at each spindle, i.e., each ring rotary member
in the machine. Nevertheless, such a control means has not been proposed.
[0008] The same inventor as of the present application proposed a rotary spinning ring assembly
enabling a high rotational speed of the ring rotary member and having a rotational
speed control means for controlling the rotational speed of the ring rotary member,
in Japanese Unexamined Patent Publication (Kokai) No. 2-74633, and Japanese Patent
Application No. 1-107060 filed on April 26, 1990, and claiming a priority of Japanese
Patent Application No. 63-282854 filed on November 8, 1988. In the rotary spinning
ring assembly disclosed in the former publication, the ring rotary member is rotatably
supported through a magnetic bearing including an electrical magnet in at least a
portion thereof with a holder. In the rotary spinning ring assembly filed in the later
application, a motor having a permanent magnet arranged on a ring rotary member and
an armature arranged on a holder is provided.
[0009] Nevertheless, even if the rotary spinning ring assembly proposed by the same inventors
as of the present application is used, it is impossible to attain an essential object
and quality of the rotary spinning ring assembly such that all of the ring rotary
members arranged on all of the spindle, can be individually operated in a stable spinning
state at all of the spinning stages by a conventional drive method.
DISCLOSURE OF THE INVENTION
[0010] The primary object of the present invention is to provide a method of controlling
a twisting operation of a rotary spinning ring assembly, which prevents a synchronization
of a rotation of a ring rotary member with a rotation of a traveller, an overrun of
the ring rotary member when the machine is stopped or the like, for all of the spindles
of the machine, and by controlling a rotational speed of the ring rotary member during
all the spinning process, when a twisting operation is performed by using the rotary
spinning ring assembly.
[0011] The second object of the present invention is to provide a twisting operation controlling
apparatus for a rotary spinning ring assembly capable of obtaining the primary object
of the present invention.
[0012] The primary object of the present invention is attained by a method of controlling
a rotary spinning ring assembly, characterized in that a rotational speed of a ring
rotary member and a rotational speed of a spindle are detected, respectively, the
two detected rotational speed values are compared, and the rotational speed of the
ring rotary member is controlled by a rotational speed control means in such a manner
that the rotational speed of a ring rotary member is kept within a range of a predetermined
optimum ratio of the rotational speed of the ring rotary member to the rotational
speed of the spindle.
[0013] Preferably, a control program for controlling the rotational speed of the spindle,
from a start of the manufacture of a yarn package to a completion thereof, to a predetermined
rotational speed, and another control program for controlling a rotational speed of
the ring rotary member to a rotational speed determined by a predetermined optimum
ratio in connection with the control program for controlling the rotational speed
of the spindle are provided, whereby the control of the rotational speed of the ring
rotary member controlled by an optimum ratio controlling means is performed in such
a manner that a difference between the detected rotational speed of the ring rotary
member and a target rotational speed of the ring rotary member set in the control
program is reduced.
[0014] The programmed control of the rotational speed of the ring rotary member is preferably
performed in such a manner that the ring rotary member is rotated at a lower rotational
speed than that of a traveller, and the rotation of the ring rotary member is proportionally
controlled according to a ring rotary member speed-elevation curve having a speed-elevation
ratio which is at least not larger than that of a spindle speed-elevation curve during
a period of from a starting time to a time at which the rotational speed of the ring
rotary member reaches a maximum rotational speed, the rotational speed of the ring
rotary member is reduced and is kept within a region of between 40% and 60% of the
rotational speed of the spindle during a period in which a half yarn package is spun,
the rotational speed of the ring rotary member is raised before the rotational speed
of the spindle is reduced from the maximum rotational speed thereof during a period
before the yarn package becomes a full bobbin and in which a yarn breakage becomes
larger, the rotational speed of the ring rotary member is reduced at a reduction ratio
which is at least not lower than that of the rotational speed of the spindle during
a period in which the yarn package becomes a full bobbin, and then the rotational
speed of the spindle is reduced and the ring rotary member is stopped at the same
time as or before the spindle is stopped.
[0015] It is possible to make the time for which the spindle is driven at a maximum rotational
speed a maximum value, to thereby attain an improved productivity and a stable spinning
operation, by combining the control program for controlling the rotational speed of
the spindle in a optimum correlative relationship with the control program for controlling
the rotational speed of the ring rotary member, and by controlling the rotational
speed of the ring rotary member on the basis of a comparative value of the detected
rotational speed of the spindle and the detected rotational speed of the ring rotary
member.
[0016] Further, it is preferable to include a start control in which a start of the rotation
of the ring rotary member is applied after a slight time lag from a start of the rotation
of the spindle, to ensure a first winding of the yarn on a bobbin. It is possible
to apply a suitable winding tension to the bobbin by delaying the start of the rotation
of the ring rotary member and thus it is possible to obtain a first winding of the
yarn on the bobbin.
[0017] A magnetic bearing can be used as the bearing mechanism. The magnetic bearing is
constituted by annular magnets coaxially arranged, respectively, on axial and radial
opposite faces of the ring rotary member and the holder, with a minute gap therebetween
in such a manner that the pole of the annular magnet of the ring rotary member is
arranged to be opposite the pole of the annular magnet of the holder having the same
magnetic properties as that of the annular magnet of the ring rotary member. Each
opposite face of the annular magnets may have a profile such the both opposite faces
are in contact with each other by at least a portion thereof when the ring rotary
member moves in the axial direction thereof toward the holder, and an electromagnet
may be used to form at least a plurality of magnets arranged in the annular magnet
of the holder. When the magnetic bearing is used, the control of the rotational speed
of the ring rotary member by the rotational speed controlling means can be performed
by controlling an intensity of the magnetic field of the electromagnet and adjusting
a gap between the ring rotary member and the holder in the magnetic bearing, to thus
control a torque generated by the rotating of the ring rotary member.
[0018] The control of the intensity of the magnetic field of the electromagnet can be performed
by changing an intensity or a direction of an electric current.
[0019] A rotary spinning ring assembly in which the ring rotary member is rotatably supported
through a bearing mechanism with a holder, wherein the bearing mechanism is formed
by an annular permanent magnet arranged on the ring rotary member and an armature
arranged on the holder, can be used. In this rotary spinning ring assembly, the control
of the rotational speed of the ring rotary member by the rotational speed control
means is performed by controlling an electric current supplied to the armature. The
control of the electric current fed to the armature can be performed by adjusting
a value of a frequency, a value of an electric current, an electric voltage or a vector
of the electric current.
[0020] A control apparatus of the rotary spinning ring assembly used for attaining the second
object of the present invention can be used in a spinning machine such as a ring spinning
frame and a ring twisting machine or a draw twister having a ring rail and a spindle
driving mechanism, and is an apparatus for controlling each rotary spinning ring assembly
of the textile machine including a plurality of the rotary spinning ring assemblies
comprising, respectively, an annular holder fixed in a horizontal posture to the ring
rail, a ring rotary member supported coaxially and rotatably through a bearing mechanism
to the holder, a spindle arranged coaxially in an inner space of the ring rotary member
and driven by the spindle driving mechanism, and a rotational speed control means
of controlling a rotational speed of the ring rotary member. The control apparatus
is characterized in that a magnetic bearing is used as the bearing mechanism, the
magnetic bearing being constituted by annular magnets coaxially arranged, respectively,
on axial and radial opposite faces of the ring rotary member and the holder, with
a minute gap therebetween, in such a manner that a pole of the annular magnet of the
ring rotary member is arranged to be opposite to a pole of the annular magnet of the
holder having the same magnetic properties as that of the annular magnet of the ring
rotary member, and the each opposite face of the annular magnets has a profile such
that the both opposite faces are in contact with each other by at least a portion
thereof, when the ring rotary member moves in the axial direction thereof toward the
holder, at least a magnet in a plurality of magnets arranged in the annular magnet
of the holder is an electromagnet, and the rotary spinning ring assembly control apparatus
is comprised of a ring rotational speed detecting means for detecting a rotational
speed of the ring rotary member, a spindle rotational speed detecting means for detecting
a rotational speed of the spindle, a suppressing ratio storing means for storing a
suppressing ratio, i.e., a target rotational speed ratio of the ring rotary member
to the spindle, a multiplying means for multiplying the suppressing ratio by the rotational
speed detected by the spindle rotational speed detecting means, a comparing means
for comparing multiplied data obtained by the multiplying means with the rotational
speed detected by the ring rotational speed detecting means, and an electric current
control means for controlling an electric current supplied to the electromagnet arranged
on the holder, and of the bearing mechanism, on the basis of a result obtained by
the comparative means, in such a manner that the rotational speed of the ring rotary
member reaches the target rotational speed thereof, and the spindle rotational speed
detecting means, the suppressing ratio storing means, and the multiplying means, as
elements constituting the rotary spinning ring assembly control apparatus, are arranged
on each textile machine, respectively, and the other elements are arranged on each
of a plurality of the ring rotary members, respectively.
[0021] It is possible to arrange on annular permanent magnet at a region constituting the
bearing mechanism of the ring rotary member and arrange an armature in the holder,
to form a motor, used instead of the magnetic bearing as the bearing mechanism.
[0022] It is preferable to further provide a means of storing a control program for controlling
the rotational speed of the spindle to a predetermined rotational speed for the whole
period of from a start of winding a yarn package to a completion thereof in the rotary
spinning ring assembly control apparatus, to rotate the spindle according to the control
program held in the storing means.
[0023] Where the rotary spinning ring assembly control apparatus in accordance with the
present invention includes a control program setting means for setting a program in
such a manner that a rotational speed of the spindle can be changed according to an
advance of a formation of a cop over the whole period from the start to the completion,
optimum spinning conditions of all the spinning process for the various types of yarn
are stored in a program storing means, and a suppressing ratio, which is a target
rotational speed ratio of the ring rotary member to the rotational speed of the spindle,
is stored in a storing program thereof in such a manner that a variable speed control
of the rotational speed of the spindle can be performed according to a package size
ratio of the cop obtained by, for example, detecting a stretch length. It is further
preferable to perform a group control of the rotational speeds of the spindle and
the ring rotary member by inputting and storing the optimum spinning program in a
group control system for a textile machine group composed of several machines having
the same conditions, detecting the optimum spinning conditions including a mean spinning
tension from the textile machine group to obtain an average group value, and by operating
the textile machines according to the optimum spinning program prepared in such a
manner that the detected average group value is within a region of the optimum spinning
conditions including the predetermined optimum spinning tension.
[0024] A function of the control of the rotational speed of the ring rotary member, which
is performed by a control method and a control apparatus in accordance with the present
invention, will be described with reference to a rotary spinning ring assembly equipped
with a magnetic bearing as an example.
[0025] The rotary spinning ring assembly equipped with the magnetic bearing is provided
with a permanent magnet arranged in an annular state at a substantially center portion
of an outer circumference of the ring rotary member and formed as one body with the
ring rotary member and a magnet arranged on a fixed holder surrounding same coaxially
in an annular state to the ring rotary member from an outside thereof, wherein the
permanent magnet is located opposite to the magnet, with a minute annular air gap
therebetween, and with the same poles of the permanent magnet and the magnet are opposite
to each other, and accordingly the permanent magnet and the magnet repulse each other,
and thus the ring rotary member floats in a non-contact state with the holder, and
as a result, the magnetic bearing is formed.
[0026] A part of annular magnets arranged on the holder is constituted by an electromagnet,
and since this electromagnet has a component in an axial direction of the holder,
an electromagnetic floating force or an electromagnetic absorbing force in the axial
direction or an upper and lower direction of the ring rotary member can be changed
by changing a value of the electric current or a direction of the electric current
supplied to the electromagnet, and the ring rotary member moved in a direction in
which the electromagnetic floating force is reduced or the electromagnetic absorbing
force is increased, and thus a magnetic pole face of the ring rotary member, through
a sliding member or the like, is in contact with a magnetic pole face of the holder.
The degree of contact pressure can be controlled according to an intensity and a direction
of the electric current supplied to the electromagnet of the holder, and accordingly,
a braking force can be controlled by changing the contact and friction force.
[0027] When a magnet force of the ring rotary member and a magnet force of the holder are
provide an equivalent support of the ring rotary member, the ring rotary member is
fully floating, and thus the magnet bearing is maintained in a noncontact state whereby
a rotational speed of the ring rotary member is increased to a maximum rotational
speed at which the rotational speed of the ring rotary member reaches the same rotational
speed as that of a traveller. Accordingly, to lower the rotational speed of the ring
rotary member to a suitable range for a spinning condition, i.e., 60% of the rotational
speed of the traveller as a mean value or 90% of the rotational speed of the traveller
as a maximum value, a rotation of the ring rotary member is controlled by applying
a resistance thereto caused by a difference between the magnetic forces of the poles
of the magnetic bearing held in the non-contact state. When the difference in the
magnetic forces becomes larger, the ring rotary member, through the sliding member,
is in contact with either one of an upper pole or a lower pole of the magnet of the
holder and a friction is generated therebetween. When a plus direction and a minus
direction of the electric current supplied to the electromagnetic coil is reversed,
an equilibrium state in which the pole of the ring rotary member and the pole of the
holder face each other and are balanced by the repelling magnetic force or the absorbing
magnetic force is broken, and the ring rotary member is suddenly braked by being brought
into magnetic contact with either one of the upper magnetic pole or the lower magnetic
pole of the magnet of the holder and the ring rotary member stop. Thus, the rotation
of the ring rotary member can be electrically controlled from the outside.
BRIEF DESCRIPTION OF THE DRAWINGS
[0028]
Figure 1 is a block diagram illustrating a preferable example of a method of controlling
a rotary spinning ring assembly in accordance with the present invention;
Fig. 2 is a partially axial sectional view illustrating an example of a rotary spinning
ring assembly controlled in accordance with the present invention;
Fig. 3 is a graph illustrating an example of a spinning program stored in a program
storing means;
Fig. 4 is a flow chart illustrating an example of an operation of a comparative means
of a control driving circuit;
Figs. 5 to 7 are a partial axial crosssectional view illustrating other examples of
the rotary spinning ring assembly controlled in accordance with the present invention,
respectively.
BEST MODE OF CARRYING OUT THE INVENTION
[0029] A rotary spinning ring assembly to which a control of the present invention is applied
will be described, before a method of controlling the rotary spinning ring assembly
and an apparatus therefor are described.
[0030] Figure 2 is a partial axial crosssectional view illustrating an example of the rotary
spinning ring assembly controlled in accordance with the present invention.
[0031] In the rotary spinning ring assembly A shown in Fig. 2, a ring rotary member 1 is
constituted by a flange rotor 2 having a ring flange portion 2a on which a traveller
21 is slidably rotated, and a lower rotor 3 is connected to the flange rotor 2 by
screws 2b. The lower rotor 3 is made of a non-magnetic metal material such as an aluminum
alloy having a magnetic resistance, a copper alloy, a stainless steel, a carbon group
material or the like, and an electrical conductive synthetic material or the like,
and thus a leakage of a magnetic flux is cut to a minimum value.
[0032] The ring rotary member 1 is rotatably supported in a holder 7 by a bearing mechanism
G, and the holder 7 is inserted into an attaching hole 23a of a ring rail 23 and fixed
by a screw 25.
[0033] The bearing mechanism is constituted as follows. Two annular permanent magnets 11
and 12 are fixed through a spacer 15a and 15b into a concave groove 3a formed in the
lower rotor 3 of the ring rotary member 1. An outer circumference in a radial direction
of the permanent magnets 11 and 15 has a tapered face 11a and 12a having an angle
of around 45° relative to an axis thereof, and the magnetic pole of the tapered face
11a and 12a is an N pole.
[0034] The spacer 15b is used as a magnetic sealing means so that a leakage of magnetic
flux of the permanent magnets 11 and 12 to the outside, in particular the ring flange
portion 2a and the traveller 21, is prevented.
[0035] The holder 7 is constituted with a holder main body 8 and a cover 9 connected thereto
by a screw 8a or the like.
[0036] An annular permanent magnet 13 and an annular electromagnet 14 are fixed through
a spacer 13a into a concave portion 7a formed in the holder 7. Tapered faces 13a and
14a having an angle of 45° relative to an axis of the ring rotary member are formed
on an inside circumference in a radial direction of the permanent magnet 13 and the
electromagnet 14, in such a manner that both tapered faces form a groove having a
substantial V shape, and the tapered faces 13a and 14a and the tapered faces 11a and
12a are arranged in an opposite relationship with a suitable gap therebetween.
[0037] A magnetic pole of the tapered face 13a is the same as the magnetic pole of the tapered
face 11a, i.e., an N-pole, and a magnetic pole of the tapered face 14a of the electromagnet
14 is made an N pole by supplying an electric current in a normal direction, to a
lead line 14b of the electromagnet 14. An intensity of the electromagnet 14 can be
adjusted by adjusting the electric current.
[0038] It is possible to use electromagnets having various structures. For example, it is
possible to use an electromagnet having a structure in which a plurality of pillar-like
electromagnets constituted by winding a coil on a pillar-like core having a circular
section or a fan-like section are arranged in a concave portion 7a of the holder 7
along a circumferential direction thereof, in a state such that a magnetic pole of
the pillar-like electromagnet is fixed to an annular plate having magnetic properties,
respectively, and an electromagnet having a structure in which a coil is wound on
an iron core having a shape of a circular pillar is then accommodated in the concave
portion 7a or the like.
[0039] The electromagnets 11, 12 and 13 are an isotropic magnet of a metal, a ferrite (an
axidate ceramic), a rare earth element, a rubber, a plastic or the like. Further,
if necessary, opposite faces of the permanent magnets 11, 12 and 13 and the electromagnet
14 are provided with a cover such as a sheet, a film or a coating layer, to protect
a pole surface. This cover may be made of a non-lubricated sliding material having
a lower friction coefficient, a superior resistance to abrasion and a superior resistance
to heat, e.g., a ceramic, a tetrafluoroethylene including a filler such as a carbon
fiber or the like, or a high polymer engineering plastic such as a polyimide, a polyimideamide
or the like.
[0040] A spacer 16 is made of an electrical insulating material such as mica, a high polymer
resin, a ceramic or the like, to electrically insulate the electromagnet 14 from the
permanent magnet 13.
[0041] A sensor 17 is attached to a holder body 8, and a detecting member 18 for generating
a pulse, i.e., a detecting signal, to the sensor 17 is arranged on an outer circumferential
face of a lower rotor 3. Accordingly, by providing light and dark portions or notches,
the rotational number, i.e., the rotational speed, can be detected by counting the
detection signals from the sensor 17. The numeral 4 denotes a dust cover, and 22 a
yarn supplied from a snarl wire in a ballooning state and wound on a cop (not shown).
[0042] In this ring rotary member A, a magnetic pole having substantially the same intensity
as that of a tapered face 13a of the permanent magnet 13 is formed on a tapered face
14a of the electromagnet 14 by supplying a suitable electric current through a lead
line 14b to the electromagnet 14, and thus the permanent magnets 11 and 12 are floated
from the permanent magnet 13 and the electromagnet 14, because the tapered faces 11a
and 12a and the tapered faces 13a and 14a repel each other, and is in a noncontact
state.
[0043] Accordingly, the ring rotary member 1 can be rotated by an extremely small rotational
speed and an energy loss caused by a friction or the like become extremely small,
and thus the ring rotary member can be rotated at the high rotational speed by a torque
applied from a traveller 21.
[0044] When the electric current supplied to the electromagnet 14 is reduced, since a magnetic
force of the electromagnet 14 lowers and a component pressing up the permanent magnets
11 and 12 is lowered, the ring rotary member 1 moves downward and the tapered face
12a comes into contact with the tapered face 14a by a repelling force between the
tapered face 11a of the permanent magnet 11 and the tapered face 13a of the permanent
magnet 13 and the ring rotary member's own weight. This contact pressure can be controlled
by varying the intensity of the electric current supplied to the electromagnet 14.
[0045] When a direction of the electric current is reversed, the magnetic pole of the tapered
face 14a of the electro magnet 14 becomes a S-pole, and a strong braking force is
generated because the S-pole of the tapered face 14a and the tapered face 12a of the
permanent magnet 12 are attracted to each other.
[0046] Accordingly, the braking force can be controlled by controlling the amperage and
the direction of the electric current supplied to the electromagnet 14, and thus a
rotational number of the ring rotary member and a time required to stop the ring rotary
member when rotating at a high rotational speed can be controlled.
[0047] A method of controlling the rotary spinning ring assembly in accordance with the
present invention, and an apparatus therefor will be described hereafter.
[0048] Figure 1 is a block diagram of a controller H relating to the present invention.
Note, only two spindles are illustrated in Fig. 1, but in practice all of the spindles
in a spinning frame are controlled by the controller H.
[0049] In Fig. 1 a program storing means 58 is a RAM or ROM, and is provided with a spinning
program for all of the spinning process, as determined for each type and yarn count
of the various yarns to be spun. This spinning program is an optimum range of a spinning
tension for each spun yarn, and data of a standard rotational speed of a spindle 53
and the ring rotary member 1, are determined according to a size ratio of a cop and
by a stretch length from a starting time to a time at which a full bobbin is wound.
[0050] The rotational number of the spindle can be controlled on the basis of the size ratio
by detecting and inputting a position of the ring rail on a linear scale or by bringing
the ring rail into sequential contact with a plurality of microswitches, comparing
the input data with a preinput program and then changing the rotation of the spindle.
[0051] A data of the rotational number of the ring rotary member 1 is stored as a suppressing
ratio K, i.e., a target rotational speed ratio of the ring rotary member 1 to the
spindle 53.
[0052] A rotation of the spindle drive motor 51 is controlled such that the spindle 53 is
rotated at a predetermined rotational number on the basis of the data sent from the
program storing means 58, by a spindle control means 50.
[0053] A spindle drive main shaft 52 is rotated by the spindle drive motor 51, and a rotation
of each spindle 53 is obtained through a belt or the like driven by the rotation of
the spindle drive main shaft 53. The spindle drive main shaft is provided with a rotational
number detector 59, such as a tachogenerator, a rotary pulse generator or the like,
and a rotational number Rs of the spindle 53 is detected by a rotational number detecting
circuit 60 which receives an output of the rotational number detector 59.
[0054] The rotational number Rs of the spindle 53 detected by the rotational number detecting
circuit 60 is multiplied by a suppressing ratio K output from a storing means 58,
and the obtained data is output as a target rotational number Rj.
[0055] A rotational number detecting circuit 54 detects a rotational number Rr of the ring
rotary member 1 by counting pulses output by the sensor 17.
[0056] A comparing means 56 compares the rotational number Rr detected by the rotational
speed detecting circuit 54 with the target rotational number Rj output by the multiplying
means 57, and outputs an adjusting signal Rh determined on the basis of the difference
obtained by the comparison.
[0057] A braking and driving circuit 56 controls an amperage and a direction of the electric
current supplied to the electromagnet 14, on the basis of the adjusting signal Rh
output from the comparing means 56, and adjusts a braking force in the bearing mechanism
G, whereby the rotational number Rr of the ring rotary member 1 is controlled to the
target rotational number Rj.
[0058] The above circuits and means are realized by hardware or a microprocessor including
a suitable program.
[0059] An example of the rotational number control of the ring rotary member as performed
by the controller H will be described with reference to Fig. 3.
[0060] Fig. 3 is a diagram of an example of a spinning program of a standard cotton spun
yarn having a medium yarn count, e.g., 40's to 60's, and manufactured by a high speed
spinning frame equipped with a controller such as a sequencer or the like. This spinning
program is prepared in such a manner that yarn breakages are kept to a minimum in
a period from the rotation of an empty bobbin, or a time at which a yarn is first
wound on a bobbin, to size ratio of 0.3, and a period from a size ratio of 0.9 to
a full bobbin. If too many yarn breakages occur, a rotational speed of the spindle
is increased to an allowable maximum value, a period in which the yarn is spun at
the maximum rotational speed of the spindle reaches a maximum value to complete the
entire spinning process in the shortest time. As a result, a minimum of yarn breakages,
a high quality, and a maximum productivity can be attained.
[0061] Recently, a multiple stage speed control of the rotational speed of the spindle using
an inverter or the like has been proposed. The present invention aims to provide a
controlling means which can control the rotation of the ring rotary member before
a control of the rotation of the spindle, and a control program thereof, in such a
manner that an optimum spinning condition including an optimum spinning tension in
a spinning program for every yarn type and yarn count can be obtained by applying
a control of the rotational speed of the ring rotary member by using an electrically
controllable rotary spinning ring assembly controlled according to a control of the
rotational speed of the spindle.
[0062] The control of a rotational speed of the ring rotary member according to the rotation
of the spindle will be described hereafter.
(1) A suppressing ratio K, which is an optimum ratio of a ring rotary member rotational
speed control curve RC to a spindle rotational speed control curve SC in each spinning
program, is determined, an upper limit of the ring rotation to the spindle rotation
is denoted as ru, and a lower limit thereof is denoted as rd.
(2) A time relationship between a speed change diagram in the SC curve and a speed
change diagram in the RC curve is determined.
(3) A control process of the rotational speed of the ring rotary member is as follows.
① Variable widths of a spinning tension for every yarn type and yarn count are predetermined,
an upper spinning tension at which yarn breakages are not generated is denoted as
TSU, and a lower spinning tension at which a collapse of a ballooning of the yarn
does not occur is denoted as TSD. When the variable width of the spinning tension
will be come outside a range determined by the upper spinning tension TSU and the
lower spinning tension TSU, the rotational number of the ring rotary member is controlled
before a control of the rotation of the spindle, to return a spinning tension to a
spinning tension region in which yarn breakages are not generated.
If the return of the spinning tension to the suitable spinning tension region by the
speed control of the ring rotary member is difficult, a control of the rotational
speed of the spindle is performed as an additional adjusting control.
② A diagram speed control of the rotational speed of the ring rotary member corresponding
to a change of the size ratio caused by an advance of the spinning time is performed
by detecting positions of the ring rail and a rapet rail, and measuring a size of
the bobbin on the basis of a change of a stretch length.
③ A speed control of the rotational speed of the ring rotary member in a chase in
which control a rotational speed of the ring rotary member at an upper portion and
a lower portion of the chase and during an elevation and a descent movement of the
ring rail is accelerated around the most upper portion by detecting a position of
the ring rail and a moving direction of the ring rail and following an accelerating
speed control of the ring rotary member between the chases, i.e., a V-letter time
chart having a bottom thereof at the upper portion of the chase and corresponding
to a change of the spinning tension between the chases of the cop, and without the
use of decelerating control of the spindle at an upper portion of the chase, i.e.,
the portion having a minimized diameter, are applied during a whole spinning process.
(4) In accordance with Fig. 3 showing an example of a standard spinning program.
① An SC curve is prepared by setting a rotational number NS of the spindle when a
machine is switched from 10,000 r.p.m. to 12,000 r.p.m. A required time P1 of an accelerating
1st period N1 from the switching-on to a set speed S1 is generally 5 sec to 10 sec,
but this depends on a load at the main drive source. The rotational number NR of the
ring rotary member in this period is set at zero, and a ring rotation control curve
RC is started later by a time difference, i.e., a period P1, e.g., 5 sec to 10 sec
from the start of the machine, and at this time, the rotational speed NS of the spindle
is raised to a set speed S1 of between 10,100 r.p.m. and 12,000 r.p.m.
② After the SC curve reaches the initial set speed N1, the rotational speed of the
ring rotary member is accelerated to a 1st speed S.S. of 15,000 r.p.m. corresponding
to a half value of a target maximum speed Sh for a period P2 of 20 sec to 30 sec from
the switch on, the rotational speed of the ring rotary member is immediately accelerated
to a speed S3 of around 18,000 r.p.m. corresponding to 60% of the target maximum speed
Sh, within 60 sec from the switch on, and further, is accelerated to a speed S4 of
around 20,000 r.p.m. corresponding to two-thirds of the target maximum speed Sh along
an accelerating line N4, and reaches a second speed or a constant speed Sℓ. An initial
cop bottom portion having a size ratio of 0.05 or more is formed at this constant
speed Sℓ.
In a ring rotation control diagram RC in the above region of the rotation of the spindle,
a rotational speed of the ring rotary member NR is determined to be a value of 40%
to 50% of the rotational speeds N2 and N3, as shown by the marks K1, K2 in Fig. 3,
and is accelerated to the speed. R1 along an accelerating line N4 corresponding to
50% to 60% of the value of N4. As a result, the rotational number R1 of the ring rotary
member is determined to be 10,000 r.p.m. to 12,000 r.p.m., corresponding to a value
of 50% to 60% of the value of Sℓ.
With regard to the proportional control of the ring rotation control program RC to
the spindle rotation control program SC in an initial cop bottom portion forming period
from the switch on to the size ratio of 0.05 to 0.1, when an increment of a torque
applied to the ring rotary member is rapid, due to a sharp angle of the curve SC when
the spindle is started, it is possible to absorb an accelerating shock applied to
a traveller by increasing a rotational ratio of the rotational number NR of the ring
rotary member to the rotational number NS of the ring, from 40% to 60% as described
herebefore to 80% to 90%. Generally, an accelerating ratio of the ring rotary member
to the spindle rotation control curve SC is determined in such a manner that a suitable
resistance to friction is applied between the ring rotary member and the traveller,
and a collapse of a shape of the bottom portion is prevented during a long spinning
time under a high speed, because the yarn is wound on the bobbin with a normal spinning
tension at a value preferably determined as a higher winding tension in a region whereat
yarn breakages are not generated when starting the spinning operation.
③ After the operation described above, a limit of the spinning speed depends on a
yarn type, a yarn count, a mechanical condition of the machine or the like. Generally,
in a region where the rotational speed of the spindle is accelerated along a line
N5 and a region where the rotational speed of the spindle is kept at a constant 3rd
speed s.m. in which the formation of the cop bottom portion is completed and a cop
having a size ratio of 0.22 to 0.30 is formed, the ring rotation control curve RC
may be determined as 85% of the value corresponding to the maximum speed Sh in the
spindle rotation control curve SC. For example, the rotational number Sm in Fig. 3
is determined to be 25,000 r.p.m. corresponding to 85% of the value of Sh of 30,000
r.p.m.
In a region after the cop bottom portion is formed and the cop is formed by the size
ratio of 0.4 to 0.5, the rotational number of the spindle is slowly accelerated to
the maximum spinning speed Sh, i.e., 30,000 r.p.m., along a slow acceleration line
N6. A ring rotation control curve RC in this region, follows the spindle rotation
control curve SC at a proportion of 50% to 60%, as shown as K4 to N5, R2 to Sm, and
K5 to N6 in Fig. 3, to maintain a relative speed at the rotational speed of the spindle
in a range in which yarn breakages do not occur, to absorb shock generated by a variation
of the spinning tension or the like and caused by the acceleration of the rotational
speed of the ring rotary member, and to unify the spinning tension, by changeably
controlling the rotational speed of the ring rotary member according to a change of
the rotational speed of the traveller in a chase, caused by a change of the stretch
and a bobbin winding operation.
④ In a period from the size ratio of 0.45 to 0.50 to the size ratio of around 0.55
in which the spinning condition becomes stable, the ring rotation control curve RC
keeps the maximum value R3 thereof. In a period upto the size ratio of 0.85 to 0.90
in which the spinning condition is stable and few yarn breakages occur, the rotational
speed of the ring rotary member is decelerated to the rotational speed R4 of 40% -
50% of the maximum value Sh of the rotational speed of the spindle, to reduce a torque
necessary to rotate the ring rotary member. In this period, the rotation of the ring
rotary member can be easily changed in the chase according to a torque applied to
the traveller, and it is possible to make the spinning condition stable, and a saving
of an electric consumption required in this period which is at the highest speed and
the longest time in all of the spinning process, and an abrasion of a bearing of the
ring rotary member can be reduced.
⑤ When the size ratio becomes around 0.85 to 0.95, the rotational speed of the ring
rotary member is accelerated from R4 to R5, i.e., 18,000 r.p.m., corresponding to
50% to 60% of the maximum speed Sh of the spindle along an accelerating line K7, and
this speed R5 is kept at a point just before the size ratio of 0.95 to 1.00. After
the size ratio of 0.95, the rotation of the spindle is decelerated from the maximum
speed Sh to a speed SS corresponding to a half or two thirds of Sh along a decelerating
line N7. When the cop becomes a full bobbin at the point SS-(a), a motor of the machine
is switched off by a signal from an automatic stopping device, a ring rail is automatically
lowered, and a tail winding is completed. The rotation of the ring rotary member is
decelerated to R6, i.e., 6,000 r.p.m. or less, corresponding to a value of 30% to
40% of the speed SS of the spindle to reduce an inertia of the ring rotary member.
The rotation of the ring rotary member is further decelerated from a point R6-b corresponding
to a point SS-a of the spindle rotation control curve along a decelerating line having
an angle β which is smaller than an angle α of a decelerating line of the rotation
of the spindle. Thus a time H.R. from the point R6-b to a point at which the ring
rotary member is completely stopped is determined to be a short value compared with
a time HS from the point SS-a to a point at which the spindle is completely stopped.
Namely, the rotation of the ring rotary member must be stopped at the same time or
earlier than a time at which the spindle is stopped.
[0063] The time HS depends on various conditions, such as a total load of the yarn package
or the like, use of various braking devices used in the machine, and a rotational
speed of the spindle and a torque when the inertial rotation of the ring rotary member
starts, but the value of HR can be reduced to around 10 sec by using an inverter and
a main motor braking device. When the value of HS is determined, it is necessary to
determine the value of HR as 5 sec to 9 sec.
[0064] Fig. 4 is a flow chart illustrating an example of the operation of a comparing means
56 and a braking and controlling circuit 55.
[0065] As shown in Fig. 4, a difference between the rotational number Rr of the ring rotary
member and the target rotational number Rj at the step #11.
[0066] When the rotational number Rr is bigger than the target rotational number Rj, an
electric current supplied to the electromagnet 14 is controlled by multiplying a difference
between the rotational number Rr and the target rotational number Rj by a gain α,
to generate an increment F of a braking force caused by the electromagnet 14 in step
#12.
[0067] When the rotational number Rr is smaller than the target rotational number Rj, an
electric current supplied to the electromagnet 14 is controlled to reduce a braking
force caused by the electromagnet 14 in step #13.
[0068] When the rotational speed Rr is identical to the target rotational speed Rj, the
value of the electric current is kept without change.
[0069] When the size ratio becomes 1, i.e., the cop becomes a full bobbin, a command of
a rotational speed of 0 is applied to a spindle drive motor 51 or a supply of an electric
power is switched off and the electric current supplied to the electromagnet 14 is
controlled by the braking and controlling circuit 55. For example, a direction of
the electric current is changed to generate an absorbing power between the permanent
magnet 12 and the electromagnet 14 and suddenly increase a braking force of the bearing
mechanism, and thus the rotation of the ring rotary member is controlled in such a
manner that the ring rotary member is stopped at the same time or before the spindle
is stopped.
[0070] Where the ring rotary member 1 and the spindle 53 are controlled in accordance with
the spinning program shown in Fig. 3, a generation of a snarl caused by a yarn winding
having an opposite direction can be prevented, and it is possible to perform a suitable
control of a spinning tension during a high speed spinning operation. Further, a centripetal
force is generated by the use of tapered faces 11a to 14a having an angle inclined
to an axis thereof, and thus a fluctuation of the axis of the ring rotary member 1
and a waving rotation in a horizontal plane thereof are not generated, whereby a stable
rotation can be obtained.
[0071] No yarn breakages occur in a period between first winding the yarn and a period near
to a full bobbin when the spinning operation is performed as described in the example,
and thus it is possible to obtain a high speed spinning operation. Further, since
it is possible to perform a stable spinning operation under a high speed in a period
of around a half size ratio, by lowering a rotational speed of the ring rotary member
and minimizing a variation of the spinning tension caused by a change of the speed
in a chase, the productivity is increased by using less power for rotating the ring
rotary member.
[0072] Although, the spinning program is set according to a size ratio based on a stretch
length in the above-mentioned example, it is possible to set the spinning program
on the basis of a time schedule which is previously known. A storing operation of
the spinning program to a program storing means 58 may be performed by loading from
a suitable external device, or may be input by a keyboard, a digital switch or the
like. The other circuits can be adopted as a circuit of the controller H.
[0073] It is possible to use the two permanent magnets 11 and 12 used in the example, as
one body. Further, the two permanent magnets 11 and 12 can be made as one body with
the ring rotary member 1. An electromagnet 14 is used as a magnet arranged on a lower
one of the magnets arranged on a holder 7, in the example, but the electromagnet 14
can be used for a magnet arranged on an upper one of the magnet, and further, both
magnets in the holder can be electromagnets. The pole of the magnet arranged on opposite
faces is N in the example, but an S-pole also can be used in this case, and it is
possible to use magnets having different poles as an upper magnet and a lower magnet.
[0074] Fig. 5 is a partial axial crosssectional view of another example B of a rotary spinning
ring assembly in accordance with the present invention. Members having the same function
in the rotary spinning ring assembly shown in Fig. 5 as that of members used in the
rotary spinning ring assembly shown in Fig. 2 are given the same reference numeral,
and a description thereof is omitted.
[0075] In a ring rotary member 1 in this example, a flange rotor 2 and a lower rotor 3 are
connected by a thread 2b and are fixed through a belleville spring 31b by a locknut
31 having a tool engaging groove. A notch 18a is provided in a lower end of the lower
rotor 3 and a sensor 17 detects the notch 18a and generates a signal denoting a rotational
number.
[0076] A holder 7 is attached with a yoke case 34, a plurality of equally spaced holes are
arranged in a circumferential direction in the yoke case 34, and a wave guide 35 is
accommodated in each hole. Electromagnets 32 and 33 having a crosssection of a circular
shape or a fan-like shape, and on which a coil is wound, are accommodated in the wave
guide. The lead lines extend from the electromagnet 32 and 33. The numeral 10 denotes
a cover, 36 a bottom plate, 37, an end ring, 38 a stop ring, and 39 a spring used
for fixing the ring.
[0077] It is possible to greatly increase an intensity of a magnetic force of the electromagnets
32 and 33 in the rotary spinning ring assembly B, whereby the operation of a bearing
mechanism G is stabilized, and thus it is possible to effect a strong braking force
by a control of an electric current supplied to the electromagnets 32 and 33.
[0078] A constitution wherein the permanent magnets 11, 12 and 13, and electromagnets 14,
32 and 33 include a tapered face, respectively, is used in the above examples, but
it is possible to adopt a constitution not having the tapered face. For example, in
a rotary spinning ring assembly C shown in Fig. 6, a permanent magnet 41 adhered to
the ring rotary member 1 is formed as an annular plate having a rectangular crosssection,
and permanent magnets 42 and 43, and an electromagnet 44 may be arranged in such a
manner that a part of an upper side and a lower side, and a side between the upper
side and the lower side, form a C letter type crosssection.
[0079] Fig. 7 shows a partial axial crosssection of another example D of the rotary spinning
ring assembly in accordance with the present invention.
[0080] In this rotary spinning ring assembly D, a ring rotary member 1 is rotatably supported
through a bearing 72 in a holder 7, a motor 71 comprised of a permanent magnet rotator
73 arranged on a substantially center portion in an axial direction in an outer circumferential
portion of the ring rotary member 1, and an armature 74 arranged on a substantially
center portion is an axial direction in an inner circumferential portion of the holder
7, so that the rotator 73 and the armature 74 are opposite to each other. This motor
71 directly drives the ring rotary member 1 and a rotational speed of the ring rotary
member 1 can be changed by adjusting a frequency or an amperage of the electric current
supplied to the motor 71. The numeral 18b denotes a detecting plate having a white
portion and a black portion used for detecting a rotational speed thereof by a reflection
type sensor 17, 76 is a rebound spring, 77 a spacer, and 78 a stop ring.
[0081] When using this rotary spinning ring assembly D, it is possible to control the assembly
D by adjusting a frequency or an amperage of the electric current supplied to the
motor 71 by the braking and controlling circuit 55, and coincide the rotational number
Rr of the ring rotary member 1 with the target rotational number Rj.
[0082] It is possible to calculate a rotational number Nt of a traveller 21 by detecting
a delivering speed ℓ of a yarn based on the rotational speed of the spindle and a
thickness of a yarn layer on an bobbin. It is also possible to control the rotational
number Rr of the ring rotary member 1 so that it does not exceed the rotational number
of the traveller 21, on the basis of the above detected value. Note, since a difference
between the rotational number Rs of the spindle and the rotational number Nt of the
traveller is not large, a maximum value of the rotational number Rr of the ring rotary
member may be roughly determined from the following equation.
[0083] Note, the above control operation is performed by a fuzzy control method.
[0084] As described in the above examples, a control of a rotation of a spindle based on
an optimum spinning diagram depending on a yarn type or a yarn count of the yarn to
be spun, a control of the ring rotary member performed by following the control of
the rotation of the spindle to make a ratio between the rotational speed of the spindle
and the rotational speed of the ring rotary member an optimum value, an attaining
of a maximum rotation of the machine in a minimum time, and an attaining of a stop
of the machine in a minimum time can be performed in accordance with the present invention,
and accordingly, a preparation of a spinning program whereby a spinning operation
is performed at a maximum rotational speed, a maximum value can be attained, and further,
it is possible to prevent a synchronization of the rotations of the ring rotary member
and the traveller and an overrun of the ring rotary member when stopping the ring
rotary member.
[0085] The flange rotor 2 and the lower rotor 3 may be united as one body by pressing one
member into another. A shape, a dimension, a structure, a material, a number of members
used, and an arrangement of the members are optionally determined in accordance with
the present invention.
CAPABILITY OF EXPLOITATION IN INDUSTRY
[0086] A control of a rotation of a spindle based on an optimum spinning diagram depending
on a yarn type or a yarn count of the yarn to be spun, a control of the ring rotary
member performed by the control of the rotation of the spindle to make a ratio between
the rotational speed of the spindle and the rotational speed of the ring rotary member
an optimum value, an attaining of an maximum rotation of the machine in a minimum
time, and an attaining of a stop of the machine in a minimum time can be performed
in accordance with the present invention, and accordingly, a preparation of spinning
program making a spinning operation performed at a maximum rotational speed a maximum
value can be attained, and further, it is possible to prevent a synchronization of
the rotations of the ring rotary member and the traveller and an overrun of the ring
rotary member when stopping the ring rotary member.
[0087] Accordingly, it is possible to prevent a generation of snarls caused by winding the
yarn in an opposite direction, and to maintain a controlled operation of a spinning
tension, and thus a spinning operation under a high speed and without yarn breakages
can be attained and the productivity of a spinning machine can be remarkably improved
when the method and the apparatus in accordance with the present invention are used
in a spinning frame.
[0088] In particular, since a control of the rotational speed of the ring rotary member
in the rotary spinning ring assembly can be applied to each spindle in the textile
machine, using a method and an apparatus in accordance with the present invention,
it is possible to obtain a stable operation of all of the spindle in the textile machine,
and to obtain a yarn having a superior quality.
[0089] The method and the apparatus in accordance with the present invention can be applied
not only to a spinning frame but also to all textile machines having a twisting mechanism
using a ring and a spindle, such as a twisting machine, a draw twister, a twister
manufacturing a cover yarn or the like.
LIST OF REFERENCE NUMBERS AND MARKS
[0090]
- 1
- Ring rotary member
- 2
- Holder
- 14, 32, 33
- Electromagnet (Rotational speed controlling means)
- 17
- Sensor
- 54
- Rotational speed detecting circuit (Ring speed detecting means)
- 55
- Braking and driving circuit (Braking force controlling means)
- 56
- Comparing means
- 57
- Multiplying means
- 58
- Program storing means (Suppressing ratio storing means)
- 59
- Rotational number detector (Spindle speed detecting means)
- 60
- Rotational number detecting circuit (Spindle speed detecting means)
- 71
- Motor (Rotational speed control means)
- 72
- Bearing (Bearing mechanism)
- 73
- Permanent magnet
- 74
- Armature
- Rr
- Rotational number (Rotational number of ring rotary member)
- Rs
- Rotational number (Rotational number of spindle)
- Rj
- Target rotational number
- K
- Suppressing ratio
- G
- Bearing mechanism (magnet bearing)
- H
- Controller
1. A method of controlling a rotary spinning ring assembly used in a textile machine
including a ring rail and a spindle driving mechanism, such as a ring spinning frame,
a ring twisting frame or the like and comprising an annular holder fixed in a horizontal
posture on the ring rail, a ring rotary member supported coaxially and rotatably through
a bearing mechanism by the holder, a spindle arranged coaxially in an inside space
of the ring rotary member and driven by the spindle driving mechanism and a rotation
speed control means of controlling a rotational speed of the ring rotary member: characterized
in that the rotational speed of the ring rotary member and a rotational speed of a
spindle are detected, respectively, the two detected values of the rotational speeds
are compared, and the rotational speed of the ring rotary member is controlled by
a rotational speed control means in such a manner that the rotational speed of the
ring rotary member is kept within a range of a predetermined optimum ratio of the
rotational speed of the ring rotary member to the rotational speed of the spindle.
2. A method according to claim 1, characterized in that a control program for controlling
the rotational speed of the spindle for the entire period from a starting of a yarn
package to a completion thereof to a predetermined rotational speed, and another control
program for controlling a rotational speed of the ring rotary member to a rotational
speed determined to be a predetermined optimum ratio in connection with the control
program for controlling the rotational speed of the spindle, are provided, and the
control of the rotational speed of the ring rotary member by an optimum ratio control
means is performed in such a manner that a difference between the detected rotational
speed of the ring rotary member and a target rotational speed of the ring rotary member
set in the control program is reduced.
3. A method according to claim 2, characterized in that the program control of the rotational
speed of the ring rotary member is performed such that the ring rotary member is rotated
at a lower rotational speed than that of a traveller and the rotation of the ring
rotary member is proportionally controlled according to a ring rotary member speed-elevation
curve having a speed-elevation ratio which is at least not bigger than that of a spindle
speed-elevation curve in a speed-elevation period from a starting time to a time at
which the rotational speed of the ring rotary member reaches a maximum rotational
speed, the rotational speed of the ring rotary member is reduced and is kept in a
region between 40% and 60% of the rotational speed of the spindle for a period in
which a half yarn package is suitably spun, the rotational speed of the ring rotary
member is increased before the rotational speed of the spindle is reduced from the
maximum rotational speed thereof for a period before the yarn package becomes a full
bobbin the rotational speed of the ring rotary member is reduced at a reduction ratio
which is at least not lower than that of the rotational speed of the spindle for a
period in which the yarn package becomes a full bobbin, and then the rotational speed
of the spindle is reduced, and the ring rotary member is stopped at the same time
as or before the spindle is stopped.
4. A method according to claim 3, characterized in that a starting control of the rotation
of the spindle is performed in such a manner that a start of the rotation of the ring
rotary member is performed at the same time or later than start of the rotation of
the spindle.
5. A method according to claim 1, characterized in that a magnetic bearing is used as
the bearing mechanism, the magnetic bearing is constituted by annular magnets coaxially
arranged, respectively, on axially and radially opposite faces of the ring rotary
member and the holder, with a minute gap therebetween in such a manner that a pole
of the annular magnet of the ring rotary member is opposite to a pole of the annular
magnet of the holder having the same magnetic properties as that of the annular magnet
of the ring rotary member, and the each opposite face of the annular magnet has a
profile which ensures that both opposite faces are in contact with each other at least
at a portion thereof, when the ring rotary member moves in the axial direction thereof
toward the holder, at least a magnet in a plurality of magnets arranged in the annular
magnet of the holder is an electric magnet, and a control of the rotational speed
of the ring rotary member by the rotational speed controlling means can be performed
by controlling an intensity of a magnetic field of the electromagnet and adjusting
a gap between the ring rotary member and the holder in the magnetic bearing to control
a torque obtained by rotating the ring rotary member.
6. A method according to claim 5, characterized in that the control of the intensity
of the magnetic field is performed by changing an intensity of an electric current
supplied to the electromagnet.
7. A method according to claim 5, characterized in that the control of the intensity
of the magnetic field is performed by changing a direction of an electric current
supplied to the electromagnet.
8. A method according to claim 5, characterized in that the control of the intensity
of the magnetic field is performed by changing an intensity and a direction of an
electric current supplied to the electromagnet.
9. A method according to claim 1, characterized in that an annular permanent magnet is
arranged in a region of the bearing mechanism on the ring rotary member and an armature
is arranged on the holder, to form a ring motor, and the control of the rotational
speed of the ring rotary member by the rotational speed control means is performed
by controlling an electric current supplied to the armature.
10. A method according to claim 9, characterized in that the control of the electric current
is performed by changing a frequency thereof.
11. A method according to claim 9, characterized in that the control of the electric current
is performed by changing an amperage of the electric current.
12. A method according to claim 9, characterized in that the control of the electric current
is performed by changing a voltage of the electric current.
13. A method according to claim 9, characterized in that the control of the electric current
is performed by changing a vector of the electric current.
14. An apparatus for controlling a rotary spinning ring assembly of a textile machine
such as a ring spinning frame, a ring twisting machine or the like having a ring rail,
a spindle driving mechanism and a plurality of the rotary spinning ring assemblies
comprising, respectively, an annular holder fixed in a horizontal posture to the ring
rail, a ring rotary member supported coaxially and rotatably through a bearing mechanism
to the holder, a spindle arranged coaxially in an inner space of the ring rotary member
and driven by the spindle driving mechanism, and a rotational speed control means
for controlling a rotational speed of the ring rotary member, characterized in that
a magnetic bearing is used as the bearing mechanism, the magnetic bearing is composed
of annular magnets coaxially arranged, respectively, on axially and radially opposite
faces of the ring rotary member and the holder, with a minute gap therebetween, in
such a manner that a pole of the annular magnet of the ring rotary member is opposite
to a pole of the annular magnet of the holder and having the same magnetic properties
as that of the annular magnet of the ring rotary member, and each opposite face of
the annular magnet has a profile such that both opposite faces are in contact with
each other at at least a portion thereof, when the ring rotary member moves in the
axial direction thereof toward the holder, at least a magnet in a plurality of magnets
arranged in the annular magnet of the holder is an electric magnet, and the rotary
spinning ring assembly control apparatus is comprised of a ring rotational speed detecting
means for detecting a rotational speed of the ring rotary member, a spindle rotational
speed detecting means for detecting a rotational speed of the spindle, a suppressing
ratio storing means for storing a suppressing ratio, i.e., a target rotational speed
ratio of the ring rotary member to the spindle, a multiplying means for multiplying
the suppressing ratio on the rotational speed detected by the spindle rotational speed
detecting means, a comparing means for comparing multiplied data obtained by the multiplying
means with the rotational speed detected by the ring rotational speed detecting means,
and an electric current control means for controlling an electric current supplied
to the electromagnet arranged on the holder, and of the bearing mechanism, on the
basis of a result obtained by the comparative means, in such a manner that the rotational
speed of the ring rotary member reaches the target rotational speed thereof, and the
spindle rotational speed detecting means, the suppressing ratio storing means, and
the multiplying means as elements constituting the rotary spinning ring assembly control
apparatus are arranged on each textile machine, respectively, and the other elements
are arranged at each of the plurality of ring rotary members, respectively.
15. An apparatus according to claim 14, characterized in that a storing means of storing
a control program for controlling the rotational speed of the spindle to a predetermined
rotational speed in the entire period from a starting of a winding a yarn package
to a completion thereof is provided in the rotary spinning ring assembly control apparatus
and the spindle is rotated on the basis of the control program in the storing means.
16. An apparatus of controlling a rotary spinning ring assembly of an textile machine
such as a ring spinning frame, a ring twisting machine or the like having a ring rail,
a spindle driving mechanism and a plurality of the rotary spinning ring assemblies
comprising, respectively, an annular holder fixed in a horizontal posture to the ring
rail, a ring rotary member supported coaxially and rotatably through a bearing mechanism
to the holder, a spindle arranged coaxially in an inner space of the ring rotary member
and driven by the spindle driving mechanism, and a rotational speed control means
for controlling a rotational speed of the ring rotary member, characterized in that
an annular permanent magnet is arranged in a region of the bearing mechanism on the
ring rotary member and an armature is arranged on the holder to form a ring motor,
and the rotary spinning ring assembly control apparatus is comprised of a ring rotational
speed detecting means for detecting a rotational speed of the ring rotary member,
a spindle rotational speed detecting means for detecting a rotational speed of the
spindle, a suppressing ratio storing means for storing a suppressing ratio, i.e.,
a target rotational speed ratio of the ring rotary member to the spindle, a multiplying
means for multiplying the suppressing ratio on the rotational speed detected by the
spindle rotational speed detecting means, a comparing means for comparing a multiplied
data obtained by the multiplying means with the rotational speed detected by the ring
rotational speed detecting means, and an electric current control means for controlling
an electric current supplied to the armature arranged on the holder, and of the bearing
mechanism, on the basis of a result obtained by the comparative means, in such a manner
that the rotational speed of the ring rotary member reaches the target rotational
speed thereof, and the spindle rotational speed detecting means, the suppressing ratio
storing means, and the multiplying means as elements constituting the rotary spinning
ring assembly control apparatus are arranged on each textile machine, respectively,
and the other elements are arranged at each of the plurality of the ring rotary members,
respectively.
17. An apparatus according to claim 16, characterized in that a storing means for storing
a control program for controlling the rotational speed of the spindle to a predetermined
rotational speed in the entire period from a starting of a winding a yarn package
to a completion thereof is provided in the rotary spinning ring assembly control apparatus
and the spindle is rotated on the basis of the control program in the storing means.