JP6337837B2 - Stepping motor drive - Google Patents

Description

  The present invention relates to a stepping motor driving device that drives a stepping motor used in an image forming apparatus such as a copying machine, a printer, or a facsimile machine.

  In image forming apparatuses such as copying machines, printers, and facsimiles, stepping motor driving apparatuses that drive a stepping motor by open loop motor control are generally used. In the stepping motor drive device that performs motor control by the open loop, when the stepping motor is overloaded or suddenly changes in the rotation speed, the synchronization between the drive control pulse signal and the motor rotation is lost to prevent step-out. Therefore, for example, as shown in Patent Document 1 below, there is a technique for performing constant current control with a current value corresponding to the phase difference between the edge of the drive control pulse signal and the zero cross and the drive frequency of the stepping motor. Proposed. This technology monitors the A-phase (or B-phase) drive current value during bipolar drive, and performs current control that varies the current setting according to the time from the edge after forward / reverse inversion to the zero cross point. It has become.

JP 2011-147236 A

  However, when the stepping motor rotates, the time from the edge after forward / reverse inversion to the zero cross point changes due to the change of the load torque. Therefore, in the control shown in Patent Document 1, the change occurs when the load torque fluctuates. It is difficult to accurately maintain the synchronization between the drive control pulse signal and the motor rotation. For this reason, it is desired to develop a technique for accurately preventing stepping motor step-out and further vibration.

  The present invention has been made in view of the above-described circumstances, and an object of the present invention is to make it possible to more accurately prevent stepping motors and stepping out of vibration than before.

Stepping motor driving apparatus according to an aspect of the present invention includes a current detector for detecting a current value of each phase winding of stearyl Tsu ping motors,
Constant current control that supplies a predetermined default drive current to each phase winding of the stepping motor and performs constant current control on each phase current flowing through each phase winding based on the detection result of the current detection unit And
An edge detection unit for detecting an edge of a control clock used by the constant current control unit for the constant current control;
A current increase rate detection unit that detects a current increase rate indicated by a current value detected by the current detection unit within a predetermined period from the detection time of the edge by the edge detection unit;
When the current increase rate detected by the current increase rate detection unit exceeds a predetermined value, a current value increased by a value corresponding to the detected current increase rate is set as the default drive current. a drive moving the current value determination section that determine,
The constant current control unit determines the default drive current used for the constant current control by the drive current value determination unit when a control clock of the stepping motor is larger than a predetermined low-frequency frequency. There line current value change control for changing the current value, the control clock, if the frequency of the low-speed region does not perform the current value change control is intended.

  According to the present invention, it is possible to prevent the stepping motor from stepping out or vibrating more accurately than in the past. For example, in the past, the driving current value of the stepping motor was changed according to the time from the edge after forward / reverse inversion to the zero cross point, but this time depends on the fluctuation of the load torque during the rotation driving of the stepping motor. Therefore, when the load torque fluctuates unexpectedly, step-out cannot be prevented. On the other hand, the present invention increases the drive current value of the stepping motor according to the current increase rate after the edge detection in which the influence of the load torque fluctuation appears. It becomes possible to change the current value, and it is possible to more accurately prevent the stepping motor from stepping out and vibrating more than before.

It is a block diagram which shows the structure of the stepping motor drive device which concerns on one Embodiment of this invention. It is a figure which shows the internal circuit of a stepping motor. It is a figure which shows schematic internal structure of a stepping motor. It is a figure which shows the electric current i of A / phase component from A phase, the electric current -i of A / phase to A phase component, a synthetic | combination current, and a counter electromotive voltage with a graph. It is a figure which shows the example of a switching of excitation by an excitation control part. It is a figure which shows the behavior of the back electromotive force at the time of a load change with a graph. It is a figure which shows each waveform of the electric current value of a stepping motor in each case where load changed. It is a flowchart which shows the electric current value change control by a stepping motor drive device.

  Hereinafter, a stepping motor driving apparatus according to a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a stepping motor driving apparatus according to an embodiment of the present invention.

  The stepping motor driving device 10 is a device that drives a stepping motor 1 used in an image forming apparatus such as a copying machine, a printer, or a facsimile. The stepping motor driving device 10 includes a drive circuit 2, an excitation control unit 3, a control clock switching unit 4, an edge detection unit 5, a current detection unit 6, a current increase rate detection unit 7, and a drive current value determination unit. 9 and a CPU 8 for controlling the whole. The stepping motor drive device 10 performs open loop control, and the excitation control unit 3 and the drive circuit 2 perform start-up control and steady rotation control of the stepping motor 1 by a control clock (pulse input) from the CPU 8 and the control clock switching unit 4. Then, the fall control is performed.

Drive circuit 2 is H bridge circuit with FET as a switching element for turning on / off the exciting phase of the stepping motor 1, driving the stepping motor 1.

  The excitation control unit (an example of a constant current control unit) 3 is based on the control clock input from the control clock switching unit 4, the excitation mode (MODE) and the rotation direction (CW / CCW) instructed by the CPU 8. This is a control circuit that switches on / off each excitation phase of the stepping motor 1 by driving the FET of the drive circuit 2.

  The control clock switching unit (an example of a constant current control unit) 4 sets the drive frequency corresponding to the drive current value and control clock (that is, the rotation speed (number of rotations per unit time)) instructed by the CPU 8 to the excitation control unit 3. Output to. The control clock switching unit 4 determines the duty ratio of the drive frequency according to the drive current value indicated by the CPU 8. The excitation control unit 3 controls the FET of the drive circuit 2 on / off with the drive frequency indicated by the control clock output from the control clock switching unit 4 and the duty ratio (chopping operation), thereby keeping the motor drive current constant. Constant current control is performed. The CPU 8 sets, for example, a driving frequency exceeding 1000 kHz as a high speed from a driving frequency of 0 to 1000 kHz as a low speed, and outputs it to the control clock switching unit 4.

  Here, the back electromotive force generated in the stepping motor 1 and the stepping motor 1 will be described. FIG. 2 is a diagram showing an internal circuit of the stepping motor 1. The internal circuit of the stepping motor 1 has the configuration shown in FIG. 2 because it is bipolar drive. In FIG. 2, only one direction of the H-bridge circuit is shown. In the current switching by the control clock, the following components are combined. Here, a state in which the phase switching is switched from A phase to A / phase will be described.

Since the stepping motor 1 is bipolar drive, a bi-directional drive voltage is applied to the two motor windings (A phase / B phase) while switching in the H bridge circuit. At this time, A phase → A / phase component: current i is expressed by Equation 1 shown in Equation 1.

Further, A / phase → A phase component: current-i is expressed by Equation 2 shown in Equation 2.

For this reason, the combined current is expressed by Equation 3 shown in Equation 3.
t: Elapsed time after switching to 2-phase excitation τ: 2-phase excitation for 2 clock cycles

  In this way, when the stepping motor 1 is bipolar driven, a bidirectional drive voltage is applied to the two motor windings (A phase / B phase) in the H bridge circuit. When the motor (rotor) rotates, a counter electromotive voltage (Vb) opposite to the drive voltage is generated.

  A schematic internal configuration of the stepping motor 1 is shown in FIG. FIG. 3 shows the internal structure of the PM motor. Since the stepping motor 1 is a bipolar drive, a bi-directional drive voltage is applied to two motor windings (A phase / B phase) in an H-bridge circuit to make the A phase and B phase magnetic poles, thereby rotating the rotating body. By pulling the opposite polarity side of the rotor (magnet), it is converted into rotational motion. As shown in FIG. 3, a rotor (magnet) crosses each winding in this rotational movement. That is, according to the change of the magnetic field, a counter electromotive voltage (Vb) opposite to the drive voltage is generated in the winding, and the point where the peak of the magnetic field from the rotor (magnet) intersects the winding in the vertical direction is It appears as a peak of the back electromotive force as it is.

This counter electromotive voltage has the following relationship and is expressed by Equation 4 shown in Equation 4.
Vb0: Maximum counter electromotive voltage t: Elapsed time after switching to two-phase excitation T: Two-phase excitation for two clock cycles

Further, the counter electromotive voltage is proportional to the motor rotation speed ω (control clock) and is expressed by Equation 5 shown in Equation 5.
Ke: Back electromotive force constant

  The A phase → A / phase component: current i, A / phase → A phase component: current-i, combined current, and counter electromotive voltage represented by the above equations are as shown in FIG.

  As shown in FIG. 4, the back electromotive voltage has a waveform close to a smooth sine wave. This is because a stable rotational drive is input from the outside. Actually, the stepping motor 1 performs a rotational motion by switching the excitation by the excitation control unit 3 for each step of the input control clock. When the excitation switching is observed microscopically by the excitation control unit 3, as shown in the example in FIG. 5, every time the phase is switched, operation (on) → stop (off, hold) → operation (on) → stop (off) , Hold) → Repeat.

  Referring to FIG. 5, in the stepping motor 1, for example, in the case of two-phase excitation, when the A phase and the B phase are excited (N pole), a magnetic pole (S pole) is held between both phases. The Next, when the step proceeds, the B phase and the / A phase are excited (N pole). Also in this case, the switching control that the magnetic pole (S pole) is held between the two phases is continuously performed, resulting in a rotational motion.

  Since the back electromotive force is proportional to the rotational speed ω of the stepping motor 1, if the load fluctuates and the angular speed of each step of the control clock changes, the behavior shown in (1) and (2) below. Is confirmed.

  (1) Heavy load → Retractable force (torque margin of electromagnetic force) decreases → Angular speed decreases (rotation speed decreases) → Back electromotive force decreases

  (2) Lighter load → Retractable force (electromagnetic force torque margin) increases → Angular speed increases (rotation speed increases) → Back electromotive force increases

FIG. 6 shows the behavior of the counter electromotive voltage during the (1), (2) and driven rotation. In FIG. 6, the one-dot chain line: When the load is heavy, the angular speed is slow (the rotational speed is low) → The back electromotive force is low Broken line: When the load is light, the angular speed is high (the rotational speed is high) → Back electromotive force is high Solid line: At the time of driven rotation (when external drive is input)

  Returning to the description of each part of the stepping motor driving apparatus 10 using FIG. The current detection unit 6 is a current detection unit that detects a motor drive current that flows through each excitation phase of the stepping motor 1, and includes, for example, a current detection resistor.

  The edge detection unit 5 detects an edge of the control clock output from the control clock switching unit 4 (hereinafter referred to as a clock edge). In the present embodiment, the edge detector 5 detects the rising clock edge of the control clock.

  The current increase rate detection unit 7 detects the current increase rate based on the current value detected by the current detection unit 6 within a predetermined period from the detection time of the rising clock edge by the edge detection unit 5.

  When the current increase rate detected by the current increase rate detection unit 7 exceeds a predetermined value, the drive current value determination unit 9 increases the current by a value corresponding to the detected current increase rate. Determine the value.

  In the present embodiment, a case where a part of the CPU 8 functions as the current increase rate detection unit 7 and the drive current value determination unit 9 will be described as an example.

  The CPU 8 instructs the rotation speed to the control clock switching unit 4 and instructs the excitation control unit 3 about the excitation mode (MODE) and the rotation direction (CW / CCW). The CPU 8 obtains the current value detected from the current detection unit 6 and sets the duty ratio of the drive frequency so that the current value becomes constant. When the drive current value determining unit 9 determines that the current increase rate exceeds the predetermined value, the CPU 8 determines that the current value increased by a value corresponding to the detected current increase rate is determined. The drive current is changed to the current value determined by the drive current value determination unit 9. In the present embodiment, the CPU 8 changes the drive current to the determined current value, and the control clock switching unit 4 changes the duty ratio of the drive frequency according to the current value changed by the CPU 8.

  In the present embodiment, the set including the excitation control unit 3, the control clock switching unit 4, and a part of the CPU 8 that performs the constant current control is an example of the constant current control unit in the claims.

  Here, the predetermined value used by the drive current value determination unit 9 is a default value determined in advance according to the performance of the stepping motor 1 in a situation where it is within an ideal load fluctuation range. When the CPU 8 starts to rotate the stepping motor 1 using the drive current value, the current value detected by the current detection unit 6 from the time point when the edge detection unit 5 detects the rising clock edge is the target value. Current value increase rate until reaching the current value of. The current value increase rate until the target current value is reached is obtained in advance by experiments or the like, and is set in the drive current value determining unit 9 by the manufacturer or the like.

  A waveform A shown in FIG. 7 shows a state in which the current value detected by the current detection unit 6 increases at the predetermined value when the CPU 8 rotates the stepping motor 1 with the default drive current value. It is shown.

On the other hand, when the stepping motor 1 is rotationally driven with the driving current value, for example, a current waveform when a large load fluctuation LF1 exceeding the ideal load fluctuation range occurs is shown in FIG. As shown. In this case, the current waveform has a steeper slope than the waveform A when the stepping motor 1 is driven to rotate within the range of the ideal load fluctuation after the rising edge of the control clock arrives due to the large load fluctuation. become. As the current value suddenly increases as described above, the back electromotive voltage Vb generated in the stepping motor 1 becomes larger than that in the case where the waveform A is shown due to the load fluctuation. As shown in FIG. 7, the waveform B shows a steep rise from the arrival timing of the rising edge of the control clock. When the change occurs in the back electromotive voltage Vb in this way, the back electromotive voltage is increased at a certain time. The timing of increasing the current increase rate by Vb and reaching the current value + I ₀ shown as the target current value is later than in the case of the waveform A.

As yet another example, a waveform C represents a current waveform when a load fluctuation LF2 larger than the load fluctuation LF1 occurs when the stepping motor 1 is driven with the default drive current value. In this case, due to the load fluctuation LF2, the current waveform has a steeper slope than the waveform B after the rising edge of the control clock arrives. Then, with such a sudden increase in current value, the back electromotive voltage Vb generated in the stepping motor 1 becomes even larger than when the waveform B is shown. For this reason, as shown in FIG. 7, the waveform C shows a sharper rise than the waveform B from the rising edge of the control clock, but at the time of rising to some extent, the current rise rate is greatly reduced by the counter electromotive voltage. However, the timing of reaching the target current value + I ₀ is further delayed than in the case of the waveform B.

Since each of the waveforms A to C is a sine wave, after reaching the target current value + I _0, it is inverted and falls to a current value indicating the minimum value. In this case, the time for reaching the target current value + I ₀ is shorter than that in the case of the waveform A, so that the drive current used for driving the stepping motor 1 is reduced.

  For this reason, in the stepping motor driving apparatus 10, the current increase rate detected by the current increase rate detection unit 7 based on the current value detected by the current detection unit 6 exceeds the predetermined value, and the current waveform is In the case where the slope is steeper than the waveform A indicating an ideal current value rise as in the waveform B or the waveform C, the CPU 8 sets the drive current value as described above to the drive current value determination unit 9. The current value change control is performed such that the current value is changed to the current value determined by the above and increased.

As described above, in the stepping motor driving apparatus 10, the load torque is increased by increasing the driving current value of the stepping motor 1 according to the current increase rate after the rising edge detection of the control clock, which is affected by the fluctuation of the load torque. It is possible to prevent a situation in which the drive current used for driving the stepping motor 1 decreases due to a delay in the timing of reaching the ideal current value + I ₀ due to the influence of fluctuation. Thereby, the stepping motor drive device 10 according to the present embodiment can prevent the stepping motor 1 from stepping out or vibrating more accurately than in the past.

  In a general stepping motor drive device that uses a constant current drive system, in open loop control, in order to prevent step-out (out of synchronization with the control clock) due to load fluctuations, allow for the load side maximum torque. A default drive current value is set. The default drive current value is not changed and is used in a fixed manner. However, in this case, since the stepping motor 1 generates surplus torque in anticipation of the load fluctuation, the mechanism other than the stepping motor may cause heat generation of the drive device, and it is difficult to save power. It is.

  On the other hand, in the stepping motor driving apparatus 10 according to the present embodiment, the default driving current is rotationally driven with a load torque that is the sum of the steady torque of the stepping motor 1 and the torque required when the stepping motor 1 is accelerated. This is the minimum value that can be used. As described above, the stepping motor drive device 10 increases the drive current value of the stepping motor 1 according to the current increase rate after detection of the rising edge of the control clock, which is affected by the variation of the load torque, as described above. Therefore, when the load increases, the default drive current value is increased to a value that allows for the maximum torque on the load side in order to prevent step-out by increasing the default drive current value at that time. There is no need to set it all the time.

  For this reason, the stepping motor driving device 10 does not generate surplus torque in anticipation of the load fluctuation, causes no concern about heat generation of the driving device in mechanisms other than the stepping motor 1, and saves power without increasing power consumption. It is also possible to make it easier.

  Next, the current value change control by the stepping motor driving device 10 will be described. FIG. 8 is a flowchart showing current value change control by the stepping motor driving apparatus 10.

  At the start of driving of the stepping motor 1, the CPU 8 sets a default driving current having a predetermined value and a duty ratio corresponding to the driving current for the stepping motor 1 (S1). At this time, the CPU 8 sets a control clock corresponding to the required rotation speed of the stepping motor 1 (S2).

  The control clock switching unit 4 generates a drive frequency corresponding to the drive current value and the control clock instructed from the CPU 8. At this time, the control clock switching unit 4 determines the duty ratio of the drive frequency according to the drive current value instructed by the CPU 8, and outputs the control clock to the excitation control unit 3 (S3). The drive circuit 2 rotationally drives the stepping motor 1 according to the output from the excitation control unit 3 (S4).

  At this time, the current detection unit 6 detects a current value (S5). The current detection unit 6 outputs the detected current value to the current increase rate detection unit 7. The edge detector 5 detects the rising edge of the control clock (S6), and outputs a detection signal to the current rise rate detector 7 when the rising edge is detected. The CPU 8 performs constant current control according to the current value detected by the current detection unit 6.

  Here, the current increase rate detection unit 7 determines whether or not the drive frequency of the control clock used for driving the stepping motor 1 at this time is higher than a predetermined low-frequency range frequency (S7). ).

  When the current increase rate detection unit 7 determines that the control clock is larger than the frequency in the low speed range (YES in S7), the subsequent processing from S8 is performed. When the current increase rate detection unit 7 determines that the control clock has the low frequency range (for example, 0 to 1000 kHz) (NO in S7), the process proceeds to S12. When the control clock has the frequency in the low speed range, the rotational speed of the stepping motor 1 is relatively slow, the back electromotive voltage generation timing is delayed, and is detected by the current detection unit 6 from the rising edge timing of the control clock. This is because the influence of the counter electromotive voltage that delays the time until the current value reaches the target current value is small.

As described above, when the current increase rate detection unit 7 determines that the control clock is larger than the low frequency range and is not in the low speed range (YES in S7), the current increase rate detection unit 7 is the edge detection unit. 5 according to a certain predetermined time period from the detection Timing in g of the rising edge has passed (e.g., from the detected Timing in g of the edge, when outputting the single-frequency rectangular wave as a control clock) of the current value in An increase rate is calculated based on the current value detected by the current detector 6 (S8).

  Here, the drive current value determination unit 9 determines whether or not the calculated increase rate of the current value is higher than a predetermined increase rate (S9). Here, the predetermined rate of increase is, as described above, the rotational drive of the stepping motor 1 according to the drive current value determined in advance according to the performance of the stepping motor 1, and the ideal load fluctuation range. Is the rate of increase in current value from the timing of the rising edge of the control clock until the current value detected by the current detector 6 reaches the target current value.

  When the drive current value determining unit 9 determines that the calculated increase rate of the current value is higher than the predetermined increase rate (YES in S9), the drive current value of the stepping motor 1 is calculated as described above. The current value is changed according to the increased rate (S10). That is, when the calculated increase rate of the current value is higher than the predetermined increase rate, the drive current value determination unit 9 increases the value of the drive current of the stepping motor 1 according to the current increase rate. Let

  On the other hand, when the drive current value determination unit 9 determines that the calculated increase rate of the current value is equal to or less than the predetermined increase rate (NO in S9), the drive current value of the stepping motor 1 is set to S2. The set default drive current value is maintained. The process proceeds to S12.

  After changing the current value in S10, the drive current value determination unit 9 changes the drive current value of the stepping motor 1 to a drive current value corresponding to the rate of increase as described above, for example, a predetermined period (for example, , 1 ms), a timer for performing a process for returning the changed drive current to the default drive current composed of the initial value set in S1 is set (S11). That is, the drive current value determination unit 9 starts time measurement with a built-in timer, and when the predetermined period has elapsed, the drive current value determination unit 9 sets the changed drive current to a default value including the initial value set in S1. Return to the drive current.

  As described above, the drive current value determination unit 9 increases the drive current in response to the temporary load fluctuation by returning the drive current to the initial value after a certain period of time, and after the load fluctuation is settled. Since the original drive current is restored, the drive current can be accurately changed in response to a temporary load fluctuation. In parallel with the processing of S11, the processing after S12 is continued.

  Thereafter, until the stop instruction for the stepping motor 1 is input (NO in S12), the processing after S5 is continued, and when the stop instruction for the stepping motor 1 is input (YES in S12), the CPU 8 and the control clock The switching unit 4 and the excitation control unit 3 stop the rotation driving of the stepping motor 1 (S13).

  Thereby, according to the stepping motor driving device 10 according to the present embodiment, the load during driving of the stepping motor 1 becomes large and the rising of the current waveform becomes steep, and the target current is generated by the back electromotive force generated in association with this. When the arrival time to the value is delayed from the scheduled time, the drive current value is increased in accordance with the rate of increase in the current value, so that the maximum value of the current value increases as shown in FIG. . For this reason, the situation where the drive current required for driving the stepping motor 1 is reduced is avoided.

  As a result, a sufficient current necessary for rotational driving can be supplied to the stepping motor 1, so that the synchronization between the drive control pulse signal and the motor rotation can be accurately maintained. Can be prevented more accurately than in the past.

  The present invention is not limited to the configuration of the above embodiment, and various modifications can be made. For example, in the above embodiment, in the current value change control shown in FIG. 8, the processing after S8 is performed only when the control clock used for driving the stepping motor 1 is larger than the frequency in the low speed range. (S7) S7 is not performed in the current value change control, and the processes after S8 may be performed regardless of the control clock.

  Further, in the above embodiment, when the value of the drive current is changed according to the current increase rate in the current value change control shown in FIG. 8, the changed drive current is changed to S1 when a predetermined period has elapsed. The default drive current is reset to the initial value set in step S11 (S11), but the step S11 may not be performed in the current value change control.

  In the above embodiment, the stepping motor driving device 10 is described as being applied to an image forming apparatus, but may be applied to other electronic devices.

  The configuration and processing shown in the above embodiment using FIGS. 1 to 8 are only one embodiment of the present invention, and are not intended to limit the present invention to the configuration and processing.

DESCRIPTION OF SYMBOLS 1 Stepping motor 10 Stepping motor drive device 2 Drive circuit 3 Excitation control part 4 Control clock switching part 5 Edge detection part 6 Current detection part 7 Current rise rate detection part 8 CPU
9 Drive current value determiner

Claims (3)

A current detector for detecting the current value of each phase winding of the stepping motor;
Constant current control that supplies a predetermined default drive current to each phase winding of the stepping motor and performs constant current control on each phase current flowing through each phase winding based on the detection result of the current detection unit And
An edge detection unit for detecting an edge of a control clock used by the constant current control unit for the constant current control;
A current increase rate detection unit that detects a current increase rate indicated by a current value detected by the current detection unit within a predetermined period from the detection time of the edge by the edge detection unit;
When the current increase rate detected by the current increase rate detection unit exceeds a predetermined value, a current value increased by a value corresponding to the detected current increase rate is set as the default drive current. a drive moving the current value determination section that determine,
The constant current control unit determines the default drive current used for the constant current control by the drive current value determination unit when a control clock of the stepping motor is larger than a predetermined low-frequency frequency. There line current value change control for changing the current value, the control clock, if the frequency of the low-speed region does not perform the current value change control, a stepping motor drives. The drive current value determination unit performs the default drive current value used for the constant current control at the time when a predetermined period has elapsed after performing the current value change control. The stepping motor driving device according to claim 1, wherein the stepping motor driving device is returned to an initial value at the time of starting rotational driving. 2. The default drive current value is a minimum value that enables rotational driving with a load torque comprising a steady torque of the stepping motor and a torque required for acceleration of the stepping motor. Alternatively, the stepping motor driving device according to claim 2 .