BACKGROUND OF THE INVENTION
[0001] The present invention relates to a single spindle driving ring fine spinning machine.
[0002] It has been known that the spindles of a ring fine spinning machine are driven independently
of one another by dedicated motors.
[0003] Such a conventional single spindle driving fine spinning machine uses induction motors
10 for driving the spindles, respectively, as shown in FIG. 4, and these induction
motors 10 are collectively driven by only one inverter 11. Note that reference numeral
12 denotes a draft roller drive motor and that reference numeral 13 denotes an inverter
for the draft roller drive motor 12.
[0004] Slip occurs in the induction motor. Thus, the induction motor has addressed a shortcoming.
That is, slip causes the rotational speed of the motor to change with changing yarn
winding amount, and then causes the yarn twisting amount to change with changing rotational
speed of the motor. Further, since the only one inverter collectively drives many
induction motors, the machine can not stop only the motor that corresponds to a spindle
suffering from an abnormality such as a yarn breakage singly and through remote operation.
Still further, in order to detect a driving abnormality such as a yarn breakage in
each spindle, a special current detector for detecting a current supplied to each
driving motor needs to be provided.
SUMMARY OF THE INVENTION
[0005] An object of the present invention is to provide a single spindle driving ring fine
spinning machine that has overcome the aforementioned shortcomings that: the yarn
twisting amount is changed due to a change in winding amount and due to a change in
rotational speed caused by the fact that the induction motor is used as a single spindle
driving motor; and a special detector such as a current detector needs to be provided
in order to check the driving condition of each spindle, i.e., whether an abnormality
such as a yarn breakage has occurred at each spindle.
[0006] According to a first aspect of the present invention, there is provided a single
spindle driving ring fine spinning machine comprising single spindle driving motors
dedicated to spindles, respectively, wherein the single spindle driving motors are
synchronous motors; each of the synchronous motors is subjected to a pulse width modulation
control based on a difference between a speed reference inputted from an outside source
and a speed of that synchronous motor; and the driving condition of each of the spindles
is monitored based on a control signal used for the drive control of a corresponding
one of the synchronous motors.
[0007] Synchronous motors are used in place of the conventional induction motors. That is,
each spindle is driven by an electric motor such as a brushless dc motor or an SR
motor in which the winding is provided on the stator to produce a rotating field,
and the rotor having dc magnetic poles is rotated at a synchronous speed that is the
same as the speed of the rotating field. Using such a synchronous motor, slip no longer
occurs, and thus the rotational speed of the motor does not change even if the yarn
winding amount is increased, and hence the problem that the yarn twisting amount is
changed is eliminated. Further, when an abnormality such as a yarn breakage has occurred,
the synchronous motor maintains its rotational speed constant, and thus the control
signal used for the drive control of the synchronous motor undergoes a drastic change.
Therefore, by monitoring the control signal, the driving condition of each spindle
can be checked.
[0008] According to a second aspect of the present invention, in such a single spindle driving
ring fine spinning machine, the control signal is a PWM duty used in the pulse width
modulation control. Thus, by monitoring the PWM duty of each synchronous motor on
software, the driving condition of each spindle can be checked.
[0009] According to a third aspect of the present invention, as another method, the driving
condition of each spindle may be checked by monitoring a current reference used in
a speed PI control.
[0010] Further, according to a fourth aspect of the present invention when the control signal
corresponding to a spindle has undergone such a drastic change as to exceed a predetermined
rate, the synchronous motor for driving such a spindle may be stopped. As a result
of this arrangement, the operation of only a spindle at which an abnormality such
as a yarn breakage has occurred can be stopped singly as well as through remote operation.
BRIEF DESCRIPTION OF THE DRAWINGS
[0011] In the accompanying drawings:
FIG. 1 is a diagram showing the construction of a ring fine spinning machine according
to the present invention;
FIG. 2 is a diagram showing a speed command section of a spindle drive motor shown
in FIG. 1;
FIG. 3A is a diagram showing the rotational speed and current of the spindle drive
motor according to the present invention in function of winding time;
FIG. 3B is a diagram showing the current and the phase voltage of the winding of the
spindle drive motor according to the present invention during normal operation;
FIG. 3C is a diagram showing the current and the phase voltage of the winding of the
spindle drive motor according to the present invention at the time of a yarn breakage;
and
FIG. 4 is a diagram showing the construction of a conventional ring fine spinning
machine.
DESCRIPTION OF THE PREFERRED EMBODIMENT
[0012] An embodiment of the present invention will now be described in detail with reference
to the accompanying drawings. In a single spindle driving ring fine spinning machine
according to the present invention, a draft roller (not shown) is driven by a draft
roller drive motor 12 as shown in FIG. 1. The draft roller drive motor 12 is driven
by a commercial alternating current feed line 4 through an inverter 13. Further, many
spindles (not shown) are driven by synchronous motors 1 such as brushless dc motors
or SR motors for driving spindle. Each spindle drive motor 1 has a dedicated inverter
2 connected thereto, and each inverter 2 is supplied with direct current from a dc
power supply 3. Each inverter 2 effects control to drive the corresponding spindle
drive motor 1 based on the difference between a speed reference signal from a main
control section 5 and a speed signal from a corresponding speed sensor 6.
[0013] The drive control of each spindle driving synchronous motor is effected by the inverter
2 in such a manner as shown in FIG. 2. When the inverter 2 receives a speed reference
from the main control section 5, a speed command section 7 of the inverter 2, which
is constructed of a speed amplifier, sends a predetermined speed reference signal.
Based on the signal from the speed command section 7, the current amplifier of a current
command section 8 sends a current reference. In response to the current reference,
a PWM circuit 9 sends a predetermined PWM signal to base drive circuits 10, and the
corresponding spindle drive motor 1 is driven based on the PWM signal.
[0014] The spindle drive motor 1 has the speed sensor 6. A signal from the speed sensor
6 is fed back to the input side of the speed command section 7. Further, in this embodiment,
the PWM duty set by the PWM circuit 9, which serves as a control signal, is fed back
to the input side of the speed command section 7 via a determination section 11.
[0015] The PWM duty is monitored as follows. FIG. 3A schematically shows the rotational
speed of the spindle drive motor 1 and its current changes in function of winding
time. If it is supposed that the rotational speed of the spindle drive motor 1 is
maintained constant in function of the winding time, then the load increases with
a gradual increase in the winding amount from the winding start, and thus the current
supplied to the spindle drive motor 1 also increases. However, when a yarn breakage
has occurred for some reason, the load gets reduced, and as a result, the current
supplied to the spindle drive motor 1 gets reduced drastically and remains almost
constant at such a reduced level. The current supplied to the spindle drive motor
1 and the phase voltage of its winding exhibit such values as shown in FIG. 3B during
normal operation. That is, when the spindle drive motor 1 is in the steady state,
the phase voltage of its winding is repeatedly turned on and off at a predetermined
pulse width, and thus the current supplied to the spindle drive motor 1 is maintained
on and off within a predetermined range defined by an average value. The PWM duty
under this condition is as follows: PWM duty = ON time x 100% / {(ON time) + (OFF
time)}.
[0016] On the other hand, when the load of the spindle is reduced due to, e.g., a yarn breakage,
the average current is reduced. The phase voltage of each winding of the spindle drive
motor 1 exhibits a longer OFF time than its ON time as shown in FIG. 3C. Thus, when
a drastic change of the PWM duty from the state shown in FIG. 3B to the state shown
in FIG. 3C is detected by monitoring the PWM duty, a load fluctuation due to, e.g.,
a yarn breakage can be located. When the determination section 11 determines such
a load fluctuation, the determination section 11 outputs an abnormality signal to
the main control section 5. In response to the abnormality signal, the main control
section 5 stops the spindle drive motor 1 for the spindle of interest. It may also
be designed so that the abnormality of the spindle of interest is only displayed on
a display unit (not shown) without stopping the corresponding spindle drive motor
1.
[0017] While the PWM duty is inputted to the determination section 11 from the PWM circuit
9 in the aforementioned embodiment, an abnormality such as a yarn breakage can be
determined by causing the current command section 8 to input the current reference
to the determination section 11 as shown by the broken line in FIG. 2, the current
reference serving as a control signal to be inputted from the current command section
8 to the PWM circuit 9. Further, as shown by the one-dot chain line in FIG. 2, an
abnormality can be determined by causing the speed command section 7 to input the
speed reference signal to the determination section 11, the speed reference signal
serving as a control signal to be inputted from the speed command section 7 to the
current command section 8.
[0018] Further, the spindle drive motor 1 can be stopped in the following ways. A control
signal such as the PWM duty in the inverter 2 is outputted directly to the main control
section 5, so that a determination section commonly used by the spindles is provided
in the main control section 5. Further, the speed reference from the main control
section 5 is invalidated based on the determination result obtained by the determination
section 11 of each inverter 2.
[0019] According to the present invention, by effecting PWM control of a synchronous motor
that serves as a single spindle driving motor of a single spindle driving ring fine
spinning machine, the rotational speed of the spindle drive motor can be maintained
at a predetermined value independently of a change in the winding amount, and thus
the shortcoming that the twisting amount of a yarn is changed due to a change in the
rotational speed of the motor that is caused by a change in the winding amount can
be eliminated.
[0020] Further, according to the present invention, the driving conditions of the spindles
can be detected on control software by monitoring a control signal used for the drive
control of each of the synchronous motors, and thus abnormalities can be detected
without using current sensors.
1. A single spindle driving ring fine spinning machine comprising single spindle driving
motors dedicated to spindles, respectively, characterized in that
said single spindle driving motors are synchronous motors,
each of said synchronous motors is subjected to a pulse width modulation control based
on a difference between a speed reference inputted from an outside source and a speed
of said synchronous motor and
the driving condition of each of the spindles is monitored based on a control signal
used for the drive control of a corresponding one of said synchronous motors.
2. The single spindle driving ring fine spinning machine according to claim 1, wherein
said control signal is a PWM duty used in the pulse width modulation control.
3. The single spindle driving ring fine spinning machine according to claim 1, wherein
said control signal is a current reference used in a speed PI control.
4. The single spindle driving ring fine spinning machine according to any one of claims
1 to 3, wherein when said control signal corresponding to a spindle has undergone
such a drastic change as to exceed a predetermined rate, said synchronous motor for
driving the spindle is stopped.