Brushless direct current (DC) motors typically include electronic circuitry that energizes and de-energizes electric coils (windings) in the motor in order to make the rotor spin. Brushless DC motors are commonly used to drive cooling fans in electronic devices such as personal computers (PCs). A typical brushless DC motor used in a PC is packaged in such a way that only two terminals are accessible: a positive power supply terminal VS and a ground terminal GND (also referred to as a positive and a negative rail, respectively). A third terminal which provides a signal that indicates the speed of the motor is sometimes accessible as well.
Cooling fans driven by brushless DC motors have traditionally been run at full speed at all times since this is the simplest implementation. In a typical PC, this is accomplished by simply connecting the GND terminal to a power supply ground, and the VS terminal to the computer's +12 Volt or +5 Volt power supply. This is an inefficient scheme, however, since most electronic devices only require maximum cooling power for short periods of time and at random intervals. Running the fan constantly at fall speed wastes energy and generates unnecessary noise.
A recent trend is to run the fan motor at different speeds depending on the cooling demand. One way to accomplish this is to drive the motor with a variable voltage power supply. This is sometimes referred to as linear fan speed control. Linear fan speed control, however, can be difficult and expensive to implement because it requires a variable voltage power supply. There are also problems such as those associated with fact that most 12 Volt fans must initially be driven with at least 6 to 8 Volts to overcome the initial resistance to rotation.
Another solution involves the use of pulse width modulation (PWM). In a PWM scheme, the power supply to the motor is repetitively turned on and off at a fixed frequency but variable duty cycle. When the power supply signal has a relatively low duty cycle, for example 25 percent (that is, the power supply is on 25 percent of the time and off 75 percent of the time), the motor to turns at a relatively slow speed. Increasing the duty cycle causes the motor to spin faster. Full power is achieved by leaving the power supply signal on at all times, i.e., 100 percent duty cycle.
Although prior art PWM schemes are relatively easy and inexpensive to implement, they generates vibrations that can damage the motor and other components in the system. They also generate audible noises such as ticking noises. These problems are believed to be caused by stresses that occur when the pulse width modulated power supply signal is switched at inopportune times.
These stresses can be understood by first considering the operation of a typical brushless DC motor such as the two-phase motor shown in FIG. 1. One set of windings in the stator 50 is designated a-a′ (also referred to as phase a), and another set is designated b-b′ (also referred to as phase b). Internal electronic circuitry in the motor operates on the assumption that the power supply signal is a constant DC voltage. The circuitry alternately energizes phase a and phase b, depending on the position of the rotor 52, which rides on bearing 54. When one phase is energized, it generates a magnetic field that attracts one pole of the rotor, thereby creating a torque that causes the rotor to spin. When the rotor reaches a certain position, the internal circuitry switches the first phase off and energizes the other phase so as to generate a magnetic field that attracts the other pole of the rotor. To minimize stresses in the motor, the phases are switched when the rotor reaches a minimum torque position. The internal circuitry generally senses the rotor position by using a position sensing device such as a hall-effect sensor that generates a position signal TACH as shown in FIG. 2.
When the speed of a brushless DC motor is reduced by lowering the power supply voltage, the magnetic field created by each phase is weaker, so the rotor spins at a lower speed. The internal circuitry has no problem switching the phases at the proper times because it can always detect the rotor position using the TACH signal as shown in FIG. 3. As discussed above, however, it is expensive and difficult to provide a variable voltage power supply in many electronic systems.
In a prior art PWM scheme, a fixed frequency (30 Hz for example) is selected for the PWM signal.
Since the PWM power supply signal is free running, that is, not synchronized to anything, the phases are energized at positions of random torque, and sometime maximum torque, between the rotor and the stator. This can cause several problems. First, bearings in the motor rely on a nominal point contact between a race and a ball. The bearings are easily damaged by high instantaneous torque which causes impact loading between the ball and race. This creates indentations known as Brinell marks in the race. Brinell marks quickly become potential sites for structural damage, thereby reducing the overall reliability of the motor.
Second, energizing a phase at a high torque position produces a torque burst that causes minute flexing of the entire motor structure, thereby resulting in an audible ticking noise. The amount of noise depends on the motor speed, the frequency of the PWM power supply signal, and the duty cycle, all of which change depending on the particular configuration.
Third, if the fixed frequency of the PWM power supply signal happens to be a harmonic of the rotational speed of the motor, the windings are energized at the same place during each revolution. This can cause the motor to shake, thereby causing further damage to both the motor and other apparatus to which the motor is attached.
One aspect of the present invention involves synchronizing pulses in a power supply signal with the position of the rotor in a brushless DC motor.
When the motor is energized, instantaneous torque is characterized as follows:
where:
For a given permanent magnet AC motor, P, Lsr, is and ir are constant. This reduces the equation to T=K*sin(θm). If the phases change when the torque is zero, it will not cause any undo torque in the system. Because K is a constant, the only thing that can be controlled is θm. The angle θm can be controlled when the motor is energized. In order to set the equation to a minimum, θm must be equal to zero. Since the tachometer signal is also a relative position signal, the fan can be energized with a pulse stream that is synchronous with the tachometer.
As the duty cycle of the power supply signal increases, the rotational speed of the motor increases. Therefore, the frequency of the pulses in the power supply signal is increased accordingly so that the pulses remain synchronized with the rotor position as shown in FIG. 6. The duty cycle of the VS signal in
Different techniques can be used to determine the rotor position. If the motor has a position signal that is accessible (from a digital tachometer for example), the drive circuit can read the rotor position by directly monitoring the position signal.
A technique for determining the rotor position in accordance with the present invention is illustrated in FIG. 8. The drive circuit 16 shown in
In prior art PWM control schemes for brushless DC motors, the power supply signal is usually driven at full power (i.e., not pulsed) for a fixed period of time at start-up, typically in the range of a few milliseconds to a few seconds, to allow the motor to come up to full speed. The power supply signal is then pulse width modulated to operate the motor at the required speed. Since different motors have different start up times, the fixed period of start-up time for prior art PWM motor drives is typically made longer than necessary to assure that it will be long enough for the slowest starting motors. This is inefficient and generates unnecessary noise.
One method for determining when the motor has reached a suitable speed in accordance with the present invention is to count the number of tachometer edges from a tachometer signal. Since a given motor typically takes a certain number of rotations to come up to speed, this provides a rough approximation of the motor speed.
A more sophisticated technique for determining when the motor has reached a suitable speed in accordance with the present invention is to measure the time between tachometer edges. Since the number of poles is known, the motor speed can be accurately calculated based on the time between tachometer edges. An advantage of this method is that it optimizes the start-up time. That is, the power supply signal is switched from constant-on to PWM operation just as soon as the motor reaches a suitable speed.
As used herein, tachometer edge or pulse refers not only an edge or pulse in a position signal from an actual tachometer, but also more generally to anything that signifies events relating to the position of the rotor. Thus, if the current monitoring scheme described above with reference to
The normal on time A1 and normal off time B1 for the first rotation are calculated as follows:
Ø1/P=A1+B1
where P is the number of poles in the motor. The duty cycle determines the relationship between A and B:
A1=DC(A1+B1)
B1=(1−DC)(A1+B1)
where DC is the duty cycle (percentage on time).
During the second rotation (Φ2) the PWM power supply signal is turned on during times A1 and off during time B1. At the end of the last “on” time A1, the power supply signal is turned off for a shortened “off” time D2, and then turned on for an indeterminate amount of time until a tachometer edge is detected, and then for an additional amount of time equal to A1. As a result, “on” time C2 is longer than A1. By turning the power supply signal on slightly earlier than needed during the last tachometer cycle, it assures that power to the motor will be switched on before the tachometer edge marking the end of the complete rotation. This assures that the entire PWM power supply signal can be resynchronized at the end of each rotation. The “D” off times should be shorter than the “B” off times by as little as possible while still allowing an adequate margin to accommodate changing rotational speeds. Using D=0.75 B has been found to provide reliable results. The resynchronization can be accomplished with suitable position sensing technique such as the current monitoring scheme described above.
The motor speed is controlled by varying the duty cycle DC. After a complete revolution is completed, the duty cycle is updated, and the on and off times for the next revolution are recalculated.
The methods described herein can be used with brushless DC motors having any number of poles, and not all poles need be utilized. That is, the motor can be driven by using fewer than all of the poles. For example, in the technique described above with respect to
Another method in accordance with the present invention involves the use of multiple pulses on each phase during a single revolution. An example embodiment of such a technique is illustrated in FIG. 12.
Further aspects of the present invention involve determining the number of poles in a brushless DC motor. The poles in a brushless DC motor are arranged almost symmetrically around the stator. However, the poles are not spaced at exactly even intervals to assure that the motor will begin rotating at start-up regardless of the position in which the rotor stopped previously. This asymmetry causes slight variations in the time between tachometer edges. By measuring the time between tachometer edges and looking for patterns, it is possible to determine the number of poles in the motor.
A useful pattern that emerges from
If T1 is less than T2 at 210, the counter CNTR is tested again at 214. Here, if the counter has a nonzero value, it is the number of phases in the motor, so the method stops at 216. Otherwise, the counter is again set to zero at 218, the value of T2 is assigned to T1 at 212, and a new value of T2 (the next time between pulses) is determined at 204.
To increase reliability, the entire process illustrate in
In some brushless DC motors, the time between successive pulses has the opposite orientation. That is, the time between successive pulses keeps increasing before falling back down, rather than decreasing before rising back up. Therefore, the method illustrated in
Another embodiment of a method for determining the number of poles in a brushless DC motor in accordance with the present invention is to measure the time between different numbers of pulses, thereby generating different sets of data, and then determining the data set with the lowest amount of ripple. An example embodiment of this method can be illustrated with reference to
As discussed above, and reiterated here, a tachometer edge or pulse refers not only to an edge or pulse in a position signal from an actual tachometer, but also more generally to anything that signifies the position of the rotor. Thus, the method described above for determining the number of poles in a motor can be implemented not only with an actual tachometer, but also with other methods for determining rotor position such as the current sensing scheme described above with respect to FIG. 8. The methods described herein for determining the number of poles are preferably implemented with a microprocessor or microcontroller located in, for example, control circuitry 24 in FIG. 8.
A problem associated with pulse width modulating the power supply signal to a brushless DC motor is that the tachometer or other position sensor within the motor typically relies on the motor power supply for operation. Thus, the tachometer signal can be corrupted.
Another aspect of the present invention is a method for synthesizing a tachometer signal. In one embodiment of such a method, the number of poles is determined, the period of one rotation is determined, and then the rotation period is divided by the number of poles to determine a synthesized tachometer period. This can be accomplished by control circuitry that synchronizes the synthesized tachometer signal using any suitable technique to initially determine the rotor position. The synthesized tachometer signal can then be used to synchronize pulses in the power supply signal to the rotor position. Preferably, the synthesized tachometer signal is periodically resynchronized using a position sensing scheme such as a tachometer or current monitoring technique. The methods described herein for synchronizing and/or synthesizing a tachometer signal are preferably implemented with a microprocessor or microcontroller located in, for example, control circuitry 24 in FIG. 8.
Having described and illustrated the principles of the invention in a preferred embodiment thereof, it should be apparent that the invention can be modified in arrangement and detail without departing from such principles. Accordingly, such changes and modifications are considered to fall within the scope of the following claims.
This application claims priority from U.S. Provisional Application No. 60/290,397 filed May 10, 2001, which is incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
3691438 | Favre | Sep 1972 | A |
3831073 | Tanikoshi | Aug 1974 | A |
4447771 | Whited | May 1984 | A |
5193146 | Kohno | Mar 1993 | A |
5592058 | Archer et al. | Jan 1997 | A |
5729102 | Gotou et al. | Mar 1998 | A |
5850130 | Fujisaki et al. | Dec 1998 | A |
6049182 | Nakatani et al. | Apr 2000 | A |
6081087 | Iijima et al. | Jun 2000 | A |
6091216 | Takahashi et al. | Jul 2000 | A |
6218748 | Ushiyama et al. | Apr 2001 | B1 |
6388416 | Nakatani et al. | May 2002 | B1 |
6392854 | O'Gorman | May 2002 | B1 |
Number | Date | Country | |
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20030006724 A1 | Jan 2003 | US |
Number | Date | Country | |
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60290397 | May 2001 | US |