GB2400721A - Optical disc drive pickup unit feeding apparatus - Google Patents

Abstract

An optical pickup unit feeding apparatus comprises a lead screw 220 and a guide member 230 attached to the optical pickup unit 130. The guide member 230 has one or more contact parts 233 which engage the spiral groove 221 on the lead screw 220. The rotation of the screw 220 causes the guide member 232 to move resulting in the movement of the optical pickup unit 130. The guide member 230 also comprises an elastic member 240 made from a viscoelastic material such as rubber. The elastic member 240 exerts a sufficient force to keep the guide member 230 in contact with the lead screw 220 whilst also acting as a damping member.

Description

240072 1

OPTICAL PICKUP UNIT FEEDING APPARATUS AND

OPTICAL DISC DRIVE USING THE SAME

The present invention relates to an optical disc drive, and, more particularly, to an optical pickup unit feeding apparatus for an optical disc drive, for feeding an optical pickup unit in a radial direction of an optical disc.

Optical disc drives generally record data on, or reproduce data from, disc-shaped media such as CDs, DVDs, or the like. An optical disc drive includes an optical pickup unit feeding apparatus for feeding an optical pickup unit in a radial direction of the optical disc when data is recorded on, or reproduced from, an optical disc.

The optical pickup unit feeding apparatus is generally actuated by a rotary motor. However, since the optical pickup unit has to move from one side of an optical disc to another side along a straight line, the rotary motion of the motor has to be changed into a linear motion. The change of the rotary motion into a linear motion may be performed using a rack gear and a pinion gear or a lead screw.

Figure 1 is a schematic plan view of an optical pickup unit feeding apparatus using a lead screw. Referring to Figure 1, a lead screw 20, on which a spiral groove 21 is formed, is rotated while being attached to a driving motor 50. A guide member 30 is combined with an optical pickup unit 10 and includes a contact part 31, which is combined with the spiral groove 21 of the lead screw 20. A coil spring 40 applies an elastic force to the guide member 30 in a direction along which the contact part 31 is combined with the spiral groove 21.

According to the above-described structure, when the lead screw 20 rotates, the contact part 31 moves along the spiral groove 21, and thus the optical pickup unit 10 slides along a guide shaft 60.

Figure 2 illustrates the relationship between a spring force and a displacement of the coil spring 40. Referring to Figure 2, since the spring force increases in proportion to the displacement, a spring constant kl, i.e., the inclination of the spring force, is constant.

When the displacement of the coil spring 40 is X1, the spring force F1 is first applied to the contact part 31.

Since a rotating force and power consumption of the driving motor 50, which rotates the lead screw 20, increases with an increase in a spring force F1 applied to the contact part 31, it is preferable that the spring force F1 is small. Next, when the lead screw 20 starts rotating, the contact part 31 starts moving while engaging the spiral groove 21. Here, when a reaction force, generated due to inertia of the optical pickup unit 10 and the friction between the optical pickup unit 10 and the guide shaft 60, gets larger than the spring force F1, the contact part 31 is pushed toward the optical pickup unit 10.

If the optical pickup unit feeding apparatus is used for a long period of time, a contact surface between the guide shaft 60 and the optical pickup unit 10 is worn away, or dust piles up on the guide shaft 60. This increases the friction between the guide shaft 60 and the optical pickup unit 10, which further increases the reaction force of the contact part 31, and when the reaction force exceeds a predetermined value F2, the contact part 31 is separated from the spiral groove 21.

Thus, the optical pickup 10 fails to move by a predetermined distance in spite of the rotation of the lead screw 20. This phenomenon is called the mix-feeding phenomenon.

The maximum value of the reaction force, which maintains the engagement between the contact part 31 and the spiral groove 21, becomes F2=Fl+klxd, where d denotes the depth of the spiral groove 21. Accordingly, an increase in the spring force F1 can prevent the mis- feeding phenomenon. However, as discussed above, the power consumption of the driving motor 50 increases with an increase in the spring force F1.

Additionally, noise and vibrations, occurring during the rotation of the driving motor 50, propagate through the lead screw 20 to the contact part 31. Since a damping ability of the coil spring 40 is weak, the coil spring 40 transmits noise and vibration up to the optical pickup unit 10, which has a bad effect on recording/reproduction characteristics of the optical disc drive. Also, noise and vibrations may degrade the quality of the optical disc drive.

According to the present invention there is provided an apparatus and method as set forth in the appended claims. Preferred features of the invention will be apparent from the dependent claims, and the description which follows.

The present invention provides an optical pickup unit feeding apparatus which can prevent vibrations and noise occurring during the rotation of a driving motor from being transmitted to an optical pickup and reduce power consumption of the driving motor for rotating a lead screw, and an optical disc drive using the same.

According to an aspect of the present invention, there is provided an optical pickup unit feeding apparatus for moving an optical pickup unit by rotation of a lead screw with a spiral groove, comprising: a guide member combined with the optical pickup unit, the guide member comprising: one or more contact parts engaging the spiral groove formed on the lead screw, applying a force to the optical pickup unit in response to the rotation of the lead screw, wherein the force moves the optical pickup unit; and an elastic member pushing the contact parts toward the spiral groove, wherein the elastic member is a viscoelastic material for damping the optical pickup unit.

According to another aspect of the present invention, there is also provided an optical disc drive comprising: an optical pickup unit accessing a rotating optical disc; and an optical pickup unit feeding apparatus moving the optical pickup unit in a radial direction of the optical disc by rotation of a lead screw with a spiral groove, wherein the optical pickup unit feeding apparatus comprises: a guide member combined with the optical pickup unit, the guide member comprising: one or more contact parts engaging the spiral groove formed on the lead screw, applying a force to the optical pickup unit in response to the rotation of the lead screw, wherein the force moves the optical pickup unit; and an elastic member pushing the contact parts toward the spiral groove, wherein the elastic member is made of a viscoelastic material for damping the optical pickup unit.

According to another aspect of the present invention there is provided a method of moving an optical pickup unit by rotation of a cylindrical member with a groove in an optical disc drive, the method comprising: providing elastic force on one or ore contact parts engaged with the groove formed on the cylindrical member; and rotating the cylindrical member; wherein the elastic force is provided by an elastic member made of a viscoelastic material for damping the optical pickup unit.

Additional aspects and/or advantages of the invention will be set forth in part in the description which follows and! in part, will be obvious from the description, or may be learned by practice of the invention.

For a better understanding of the invention, and to show how embodiments of the same may be carried into effect, reference will now be made, by way of example, to the accompanying diagrammatic drawings in which: Figure 1 is a schematic plane view of an optical pickup unit feeding apparatus using a lead screw according to the related art; Figure 2 is a graph illustrating the relationship between a spring force and a displacement of a coil spring shown in Figure 1; S Figure 3 is a plane view of an optical disc drive according to an embodiment of the present invention; Figure 4 is a cross-sectional view taken along line I of Figure 3; Figure 5 is a graph illustrating the relationship between a spring force and displacement of an elastic member shown in Figure 3; Figure 6 is a graph comparing Figure 2 and Figure 5; Figure 7 is a graph illustrating an effect of damping vibrations and noise due to the elastic member shown in Figure 3; Figure 8 is a perspective view of an elastic member according to another embodiment of the present invention; Figure 9 is a graph illustrating the relationship between a spring force and a displacement of the elastic member shown in Figure 8; and Figure 10 is a cross-sectional view of an elastic member according to still another embodiment of the present invention.

Figure 3 is a plan view of an optical disc drive according to an embodiment of the present invention, and Figure 4 is a cross-sectional view taken along line I-I of Figure 3. Referring to Figure 3, a spindle motor 120 and an optical pickup unit 130 are installed on a main base 110. The spindle motor 120 rotates an optical disc.

A turntable 121, on which the optical disc is placed, is combined with a rotating shaft of the spindle motor 120.

The optical pickup unit 130 moves along a radial direction of the optical disc that rotates, and includes a pickup base 140 and an optical pickup 150, which is mounted on the pickup base 140 and records data on, or reproduces data from, a recording surface of the optical disc.

The optical pickup unit feeding apparatus includes a guide shaft 210, a lead screw 220, a driving motor 250, a guide member 230, and an elastic member 240. The guide shaft 210 is installed along the radial direction of the optical disc on the main base 110 and supports the pickup base 140 to guide the sliding of the optical pickup unit 130. The lead screw 220 is parallel with the guide shaft 210, and a spiral groove 221 is formed at the outer perimeter of the lead screw 220. The driving motor 250 rotates the lead screw 220.

The guide member 230 includes combining parts 231, which are screwed to the pickup base 140, at least one or more contact parts 233, which engage with the spiral groove 221 of the lead screw 220, and a connecting part 232, which connects the combining parts 231 and the contact parts 233 so that the contact parts 233 move between the pickup base 140 and the lead screw 220. In the present embodiment, the number of contact parts 233 is two for a stable engagement with the lead screw 220. It is preferable that the contact parts 233 are inclined to correspond to the inclination of the spiral groove 221.

In a case where more than two contact parts are included, it is preferable that the contact parts are spaced apart from each other a predetermined distance equal to a pitch of the spiral groove 221 of the lead screw 220. In the present embodiment, the connecting part 232 forms a single body with the combining parts 231 and the contact parts 233. As shown in Figure 4, as the connecting part 232 extends from the combining parts 231, the thickness of the connecting part 232 is reduced. Thus, when the contact parts 233 move as indicated by arrow A, the connecting part 232 bends flexibly, taking various shapes. Here, it is preferable that the guide member 230 is made of a flexible plastic material.

The elastic member 240 allows the contact parts 233 to engage the spiral groove 221, and also forces the contact parts 233 not to separate from the spiral groove 221. For example, the elastic member 240 may be made of a viscoelastic material such as a rubber. The elastic member 240 includes a body 241, which contacts the pickup base 140, and at least one protrusion 242, which protrudes from the body 241 and contacts the rear surface of the contact parts 233. In the present embodiment, the protrusion 242 is spherical. However, a plurality of protrusions having various shapes may be formed in order to adjust the strength of an elastic force applied to the contact parts 233. The protrusion 242 forms a first elastic section to apply an elastic force to the contact parts 233 so that the contact parts 233 elastically engage the spiral groove 221. The body 241 forms a second elastic section, providing force so that the contact parts 233 do not separate from the spiral groove 221.

The operation and effect of the elastic member 240 having the abovedescribed structure will now be described.

Figure 5 is a graph illustrating the relationship between a spring force and a displacement of the elastic member 240 shown in Figures 3 and 4. Referring to Figure 5, the first elastic section, in which the protrusion 242 deforms elastically, corresponds to a value from a displacement zero to a displacement X3. The second elastic section, in which the body 241 deforms elastically, corresponds to a value after the displacement X3. A spring constant of the first elastic section is K2, and is smaller than a spring constant K3 of the second elastic section.

When the optical pickup unit feeding apparatus is completely assembled, the elastic member 240 applies a spring force F3 to the contact parts 233. In order to reduce the power consumption of the driving motor 250, it is preferable that a force that makes the contact parts 233 engage the spiral groove 221 is small. Thus, it is preferable that the protrusion 242 deforms elastically, and that the displacement is nearly equal to, or slightly smaller than, X3.

In this state, when the driving motor 250 rotates the lead screw 220, the contact parts 233 start moving longitudinally along the spiral groove 221, and thus the optical pickup unit 130 starts sliding in the radial direction of the optical disc.

If the optical pickup unit feeding apparatus is used for a long period of time, a contact surface between the guide shaft 210 and the pickup base 140 is worn away, or dust piles up on the guide shaft 210, which results in an increase in friction between the guide shaft 210 and the pickup base 140. This further increases the reaction force of the contact parts 233. If the reaction force becomes larger than the spring force F3, the contact parts 233 are pushed toward the pickup base 140. Due to this, when the displacement becomes greater than X3, the body 241 starts deforming. Then, a spring force generated by the second elastic section of the elastic member 240 is applied to the contact parts 233. Since the spring constant of the second elastic section is greater than the spring constant of the first elastic section, when the same displacement occurs in the first and second elastic sections, a spring force generated by the second elastic section is larger than that of the first elastic section.

Referring to Figure 5, when the displacement is X4, if the second elastic section did not exist and the first elastic section extended up to the displacement X4, the spring force would be F5, which is smaller than the spring force F4 generated by the second elastic section. Thus, the contact parts 233 can be effectively prevented from being separated from the spiral groove 221 by making a second elastic section having a greater spring constant than a first elastic section.

Figure 6 is a graph for comparing Figure 2 and Figure 5. Referring to Figure 6, when the displacement is X3, the spring force F1 of the coil spring 40, shown in Figure 1, having a spring constant kl, is greater than the spring force F3 of the elastic member 240 according to the present embodiment. Also, when the displacement is X4, the spring force F2 of the coil spring 40 is smaller than the spring force F4 of the elastic member 240. That is, in the first elastic section of the optical pickup unit feeding apparatus according to the present embodiment, the driving motor 250 is less loaded than the conventional optical pickup unit feeding apparatus, and the second elastic section applies a stronger spring force to the contact parts 233 to prevent the contact parts 233 from being separated from the spiral groove 221.

Accordingly, as in the present embodiment, if the elastic member 240 has a first elastic section having a small spring constant, and a second elastic section having a higher spring constant than the first elastic section, power consumption of the driving motor 250 can be reduced and the contact parts 233 can be effectively prevented from being separated from the spiral groove 221.

Since the elastic member 240 of the present embodiment may be made of a viscoelastic material, the elastic member 240 has a good damping characteristic. Referring to Figure 7, vibrations and noise generated due to the driving motor 250 is damped from C1 to C2 by the elastic member 240. Thus, an effect of vibrations on the optical pickup unit 130 can be minimized, and data can be recorded/reproduced in a stable manner. Also, since noise can be reduced, the quality of the optical disc drive can be improved.

In Figure 4, the at least one protrusion may not be formed in another embodiment of the present invention, and the body may directly push a contact part toward a lead screw. In this case, vibrations and noise can be reduced by using only one elastic section in an elastic member formed of a viscoelastic material having a good damping characteristic.

Figure 8 is a perspective view of an elastic member according to another embodiment of the present invention, and Figure 9 is a graph illustrating the relationship between a spring force and a displacement of the elastic member shown in Figure 8.

Referring to Figure 8, an elastic member 280 is made of a viscoelastic material and includes a body 241 and at least one protrusion 242, which protrudes from the body 241 and contacts the rear surfaces of the contact parts 233. A cavity 243 is formed through the body 241. The channel 243 forms a third elastic section, and sharply deforms and removes a spring force applied to the contact parts 233 when the displacement of the elastic member 280 reaches a level on which the contact parts 233 are separated from the spiral groove 221. In a case where the motor 250 continues to rotate, although the optical pickup unit 130 reaches both ends of the guide shaft 210, due to a control error, if the contact parts 233 stay engaged with the spiral groove 221 the driving motor 250 may be overloaded, or the contact parts 233 may be damaged.

Thus, in this case, overheating of the driving motor 250 and damage of the contact parts 233 may be prevented by temporarily reducing or removing the spring force pushing the contact parts 233 using the third elastic section so that the contact parts 233 are temporarily separated from the spiral groove 221, and later re-engage with the spiral groove 221.

In the above-described embodiments, an elastic member is made of a viscoelastic material. However, the optical pickup unit feeding apparatus according to the present invention is not limited to this.

Figure 10 is a cross-sectional view of an elastic member according to still another embodiment of the present invention. Referring to Figure 10, a coil spring 300 is used as an elastic member. One end of the coil spring 300 is supported by the pickup base 140 and the other end thereof is supported by the rear surfaces of the contact parts 233. The coil spring 300 has first and second elastic parts 310 and 320, respectively having diameters D1 and D2. A spring constant of the coil spring 300 is inversely proportional to the diameter thereof.

Thus, if the diameter D1 is greater than the diameter D2, a spring constant of the first elastic part 310 becomes smaller than a spring constant of the second elastic part 320. In this structure, the relationship between the spring force and the displacement shown in Figure 5 can be obtained. Therefore, during the initial displacement X3, the first elastic part 310 applies a small force to the contact parts 233 when deforming, so that the load in the driving motor 250 is small, and power consumption of the driving motor 250 is reduced. Also, if the displacement exceeds X3, the second elastic part 320 applies a greater force to the contact parts 233 when deforming, so as to effectively prevent the contact parts 233 from being separated from the spiral groove 221.

As is described above, an optical pickup unit feeding apparatus according to embodiments of the present invention, and an optical disc drive using the same, can achieve the following effects.

Since a small spring force can be applied to a contact part by using a first elastic section, the power consumption of a driving motor can be reduced.

Also, the contact part can be effectively prevented from being separated from a spiral groove due to a second elastic section having a greater spring constant than the first elastic section.

Moreover, when an optical pickup unit operates abnormally due to a control error, the spring force applied to the contact part can be reduced or removed.

Thus, overheating of the driving motor and damage of the contact part can be prevented.

Furthermore, vibrations occurring due to the driving motor can be damped or removed by using a viscoelastic material as an elastic member. Therefore, an effect of vibrations on the optical pickup unit can be minimized, which can improve the quality of the optical disc drive.

Although a few preferred embodiments have been shown and described, it will be appreciated by those skilled in the art that various changes and modifications might be made without departing from the scope of the invention, as defined in the appended claims.

Claims (9)

1. An optical pickup unit feeding apparatus for moving an optical pickup unit by rotation of a lead screw with a spiral groove, comprising: a guide member combined with the optical pickup unit, the guide member comprising: one or more contact parts engaging the spiral groove formed on the lead screw, applying a force to the optical pickup unit in response to the rotation of the lead screw, wherein the force moves the optical pickup unit; and an elastic member pushing the contact parts toward the spiral groove, wherein the elastic member is a viscoelastic material for damping the optical pickup unit.

2. The optical pickup unit feeding apparatus of claim 1, wherein the elastic member comprises: a body forming the elastic member; and at least one protrusion from the body.

3. An optical disc drive comprising: an optical pickup unit accessing a rotating optical disc; and an optical pickup unit feeding apparatus moving the optical pickup unit in a radial direction of the optical disc by rotation of a lead screw with a spiral groove, h wherein the optical pickup unit feeding apparatus comprises: a guide member combined with the optical pickup unit, the guide member comprising: one or more contact parts engaging the spiral groove formed on the lead screw, applying a force to the optical pickup unit in response to the rotation of the lead screw, wherein the force moves the optical pickup unit; and an elastic member pushing the contact parts toward the spiral groove, wherein the elastic member is made of a viscoelastic material for damping the optical pickup unit.

4. The optical disc drive of claim 3, wherein the elastic member comprises: a body forming the elastic member, and at least one protrusion from the body.

5. A method of moving an optical pickup unit by rotation of a cylindrical member with a groove in an optical disc drive, the method comprising: providing elastic force on one or ore contact parts engaged with the groove formed on the cylindrical member; and rotating the cylindrical member; and wherein the elastic force is provided by an elastic member made of a viscoelastic material for damping the optical pickup unit.

6. The method of claim 4, wherein the elastic member elastically engages the contact parts to the groove.

7. An optical pickup feeding apparatus substantially as hereinbefore described with reference to Figures 3 to 10 of the accompanying drawings.

8. An optical disc drive comprising an optical pickup feeding apparatus substantially as hereinbefore described with reference to any of Figures 3 to 10 of the accompanying drawings.

9. A method of moving an optical pickup unit substantially as hereinbefore described with reference to any of Figures 3 to 10 of the accompanying drawings.