1. Field of the Invention
The present invention relates to an optical disk reading device, and in particular, to a control method for reducing the stable rotation speed of an automatic ball balancing system. In particular, the present invention pertains to a method that is applied to the rotor mechanism of an optical disk reading device to reduce the amount of vibration before the rotor mechanism reaches the working rotation speed, so as to effectively improve the service life of the bearing of the rotor.
2. Description of the Prior Art
General optical disk reading devices, such as CD-ROM, DVD-ROM, CD-RW, DVD-RAM, and other optical data reproducing or recording devices, have been widely used in multimedia computer systems and have become an important component among the peripheral devices of computer systems.
The data reading or storing speed of a conventional optical disk drive is expressed as multiplication speed (i.e., 1 multiplication speed=150 kbyte/sec). The magnitude of the multiplication speed is directly related to the spindle motor that drives the optical disk inside the optical disk drive. The faster the spindle motor rotates, the higher the multiplication speed for the reading or storing operation in the optical disk. However, when the spindle motor rotates at high speeds, the centrifugal deviation force generated by unbalance of the optical disk is also increased, which will lead to vibration, noise, and other problems. Also, excessive vibration will lead to an out-of-focus optical reading head and other unstable situations. Consequently, in order to effectively suppress vibration to ensure that the data stored in the optical disk can be read correctly by the optical disk drive, optical disk drive manufacturers have developed a type of automatic ball balancing system that functions to reduce vibration. As described in greater detail below, the automatic ball balancing system has a track on which one or more balls are disposed for movement.
The theory for the balls of the above-mentioned automatic ball balancing system to reach the desired balanced positions is based on the theory of rotor dynamics.
Here, the unstable critical rotation speed wc is the rotation speed at which the balls 2 are stable. As shown in
In the application of the automatic ball balancing system to the rotor mechanism, if the spindle motor is operated under a uniform acceleration to reach the working rotation speed w directly, it is still possible to reduce the unbalance amount of the rotor. However, under this condition, the rotation speed of the motor will be very high when the balls 2 are balanced. This will eventually result in the rotor being accelerated slowly and the force exerted on the rotation shaft being increased, thereby reducing the service life of the rotation shaft and the bearing.
Thus, there still remains a need to reduce the vibration in the automatic ball balancing system of an optical disk drive before the rotor mechanism reaches the working rotation speed so as to effectively improve the service life of the rotation shaft and the bearing.
It is an object of the present invention to provide a control method for reducing the stable rotation speed of an automatic ball balancing system.
It is another objective of the present invention to reduce the stable rotation speed of the automatic ball balancing system to reduce the vibration before the spindle motor reaches the working rotation speed so as to effectively improve the service life of the balls.
In order to accomplish the objects of the present invention, the present invention provides a control method for reducing the stable rotation speed of an automatic ball balancing system. The automatic ball balancing system has a rotor that has an annular track, with at least one ball provided for rotation inside the track. According to the method of the present invention, an optimum rotation speed ws that is between the unstable critical rotation speed wc of a ball and a working rotation speed w is first determined. In the next step, the rotor is accelerated to the optimum rotation speed ws. Next, the acceleration of the rotor is reduced until the balls are stationary relative to the track, and then the rotor is accelerated to the working rotation speed w.
The following detailed description is of the best presently contemplated modes of carrying out the invention. This description is not to be taken in a limiting sense, but is made merely for the purpose of illustrating general principles of embodiments of the invention. The scope of the invention is best defined by the appended claims.
Although the principles of the present invention are described below in connection with a pull-in type of compact disk player, the present invention can be applied to all optical disk reading devices, including but not limited to CD drives, DVD drives, CD/DVD drives, DVD/RW combo drives, car audio drives, etc.
The present invention pertains to a control method for reducing the stable rotation speed ws of an automatic ball balancing system.
M{umlaut over (X)}+C{dot over (X)}+KX=Mre({umlaut over (β)} sin β+{dot over (β)}2 cos β)+mR└({umlaut over (β)}+{umlaut over (φ)})sin(β+φ)+({dot over (β)}+{dot over (φ)})2 cos(β+φ)┘
M{umlaut over (X)}+C{dot over (X)}+KX=Mre({umlaut over (β)} cos ββ+{dot over (β)}2 sin β)+mR└({umlaut over (β)}+{umlaut over (φ)})cos(β+φ)+({dot over (β)}+{dot over (φ)})2 sin(β+φ)┘
{umlaut over (X)} sin(β+φ)−Ÿ cos(β+φ)−R{umlaut over (φ)}=R{umlaut over (β)}±μ(R{dot over (φ)}2+2R{dot over (φ)}{dot over (β)}−r{dot over (β)}2)
where, μ is the movement resistance of the ball.
The aforementioned equations of motion are converted into the polar coordinate form. Also, it is assumed that the angle of the ball with respect to the unbalance amount is π when the ball reaches the stable state, that is, φ=π. When this is substituted into the aforementioned equations under the aforementioned assumption, the following can be obtained:
where, 0≦ψ≦π, and {umlaut over (β)} is the rotating acceleration and {dot over (β)} is the rotation speed,
It is also possible to derive the condition for movement of the balls 13 at a constant rotation speed with respect to the track 12.
If it is given that
is the frequency response of the system, Equation (2) can be converted into the following:
Therefore, {dot over (β)} can be changed so that
When Equation (3) holds, the balls are stable with respect to the track 12. The minimum rotation speed that satisfies Equation (3) is called “the unstable critical rotation speed” wc of the ball. If {umlaut over (β)} is 0, then {dot over (β)} can be decreased by looking at Equation (1). Also, as can be seen from Equations (1) and (3), as long as Equation (3) is valid, it is possible to decrease the stable rotation speed of the balls 13 by reducing {dot over (β)}.
Based on the above, the objective of the present invention is to cause the balls 13 of an automatic ball balancing system to be stationary with respect to the track 12 even when the rotor mechanism is accelerated. In other words, the objective is to balance the balls 13 inside the track 12 so that there is no more vibration.
The control method of the present invention has the following steps. In step 100, the method determines a rotation speed ws that is between the unstable critical rotation speed wc of a ball 13 and a working rotation speed w (that is, wc<ws<w). The rotation speed ws is the desired rotation speed that the present invention would like to obtain. The unstable critical rotation speed wc of the ball is determined by Equation (3) and is larger than the critical rotation speed wn (also called the natural frequency of the suspending system) defined by the rotor dynamics. The value of the critical rotation speed wn is derived from experiments and depends on the characteristics of the system. The working rotation speed w is the maximum rotation speed of the spindle motor 16.
In step 200, the rotor mechanism (spindle motor 16) is accelerated to the rotation speed ws after passing the unstable critical rotation speed wc of the ball. See
In step 300, the acceleration of the rotor mechanism is reduced to allow the balls 13 to reach a stable position (i.e., B″, the acceleration, is reduced to 0). When the acceleration is reduced to zero in this step, the rotation speed ws can be used as the stable rotation speed at which the balls 13 reach the stable position. See
Since there is no longer any imbalance (i.e., the balls 13 do not experience movement relative to the track 12), in the next step, step 400, the rotor mechanism is accelerated again to the working rotation speed w. See
As described above, the present invention provides a new control method that can be applied to single-track or multi-track automatic balancing systems. The present invention provides an effective, stable, and reliable method that can be used to overcome the problems experienced by a conventional automatic ball balancing system. In other words, the method of the present invention can reduce the stable rotation speed at which the balls are balanced so as to correctly read data at high speed and to carry out a smooth operation. More specifically, the control method provided by the present invention for reducing the stable rotation speed of an automatic ball balancing system can effectively reduce the stable rotation speed of the automatic ball balancing system to reduce vibration before the spindle motor reaches the working rotation speed, thereby realizing the objective of effectively improving the service life of the bearing.
While the description above refers to particular embodiments of the present invention, it will be understood that many modifications may be made without departing from the spirit thereof. The accompanying claims are intended to cover such modifications as would fall within the true scope and spirit of the present invention.
Number | Date | Country | Kind |
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91114269 A | Jun 2002 | TW | national |
Number | Name | Date | Kind |
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6155134 | Ikuta et al. | Dec 2000 | A |
6333912 | Sohn | Dec 2001 | B1 |
6348747 | Liao et al. | Feb 2002 | B1 |
Number | Date | Country | |
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20040001422 A1 | Jan 2004 | US |