KR100333597B1 - Disc drive - Google Patents

Abstract

The present invention relates to a disk drive. The present invention performs the loading and unloading of the disk using the feedwire 155 in the disk driver using the disk (D) as a disk, and the loading, unloading and clamping using a single drive motor 140 This is done automatically. That is, the power of the driving motor 140 is distributed and transmitted to the power transmission path for loading and unloading and the power transmission path for clamping using the multi-stage gear 142. According to the present invention as described above, there is an advantage that the loading / unloading of the disk can be automatically performed as well as clamping by using a single drive motor 140 while making the disk driver light and small.

Description

Disc drive

The present invention relates to a disc drive device, and more particularly, to a disc drive device that enables the loading, unloading and clamping of a disc in a slim device to be performed automatically without user force.

1 and 2 show the structure of a disc drive device according to the prior art. According to this, the lower chassis 1 and the upper chassis 2 are coupled to form an external appearance of the driver, and the lower chassis 1 and the upper chassis 2 are configured to drive a disc.

That is, the tray 6 is provided on the lower chassis 1 so as to be movable in and out of the driver. The tray 6 is provided with a turntable 7 on which the disk D is seated, and a clamper 8 to hold the disk D seated on the turntable 7 so as not to be released during rotation. An optical pickup 9 for recording a signal on the disk D or reproducing the recorded signal is also provided.

Meanwhile, a lead screw (not shown) that is rotated by a power of a sled motor (not shown) is also installed to move the optical pickup 9. In addition, the driving plate 10 is installed to interlock with one end of the lead screw. The driving plate 10 is moved by overstroke of the lead screw. The eject lever 11 is installed at one side of the lower surface of the tray 6 in association with the operation of the driving plate 10.

The eject lever 11 is rotatably installed around the hinge shaft 11h, and one side of the ejection jaw 11s is formed. The locking jaw 11s is caught by the locking protrusion 5 formed on the lower chassis 1.

On the other hand, when the tray 6 is inside the driver, a spring 14 that exerts an elastic force in the direction pushing the tray 6 out of the driver is provided on one side of the tray 6. The spring 14 elastically supports the finger guide 13, and the finger guide 13 is in contact with the finger piece 4 in the lower chassis 1. That is, when the tray 6 is inside the driver, the finger guide 13 is pressed against the finger piece 4 so that the spring 14 is compressed.

In addition, guide shafts 6s and 6s' are provided at both lower sides of the tray 6 to guide the movement of the tray 6 into and out of the driver. The guide shafts 6s and 6s 'guide the movement of the tray 6 while moving along the guide rails 3 and 3' installed on both sides of the lower chassis 1. In addition, when the tray 6 protrudes to the outside of the guide rails 3 and 3 ', the support rails supporting the guide shafts 6s and 6s' are provided in the guide rails 3 and 3'. 3s, 3s') are installed.

In the structure of the conventional disk driver as described above, an operation for loading or unloading the disk D will be described. In order to load or unload the disk D, first, the tray 6 must come out of the driver.

To this end, when the user presses an eject button (not shown), the optical pickup 9 is moved to the outer circumferential side of the disk D. At the moment when the optical pickup 9 completely moves to the outer circumferential side of the disk D, overstroke occurs in the lead screw for moving the optical pickup 9, and the driving plate 10 is caused by the overstroke. This will move.

As the ejector lever 11 rotates counterclockwise around the hinge shaft 11h by the movement of the driving plate 10 as described above, the locking jaw 11s is pulled out of the locking protrusion 5. Come out. Thus, the tray 6 protrudes out of the driver, as shown in FIG. 3, by the elastic force of the spring 14.

In such a state, the user can hold the tray 6 by hand and mount the disk D to the turntable 7 or remove the mounted disk D (see FIG. 4). You can pull it out. Then, after mounting or removing the disk D on the turntable 7, the tray 6 may be pushed into the driver by hand.

At this time, when the tray 6 is completely pushed into the driver, the locking jaw 11s of the eject lever 11 is caught by the locking protrusion 5 so that the tray 6 is inside the lower chassis 1. It is fixed at. Of course, when the tray 6 enters the inside of the driver, the finger guide 13 is pressed by the finger piece 4, and the spring 14 is in a tensioned state.

When the spring 14 is in the tensioned state as described above, the tray 6 has a force to be moved out of the driver by the spring 14. However, the catching jaw 11S is caught by the catching protrusion 5 so that the tray 6 does not move to the outside.

However, the conventional loading apparatus as described above has a problem in that it is inconvenient to use because most operations of the tray 6 for loading and unloading the disk D are manually performed as described above.

That is, when the eject button is pressed, the tray 6 slightly protrudes from the driver, and the user should pull out the tray 6 in this state by hand. Then, after mounting or removing the disk D, the user must manually push the tray 6 again until it is completely inserted into the inside of the driver 1.

The manual removal of the tray 6 to the outside of the driver as described above is an inevitable choice for making the disk driver light and small. In other words, in order to minimize the space occupied by the disk driver, the entire size of the driver is designed to be almost the same as the size of the disk (D).

In order to solve such inconvenience, a configuration for automatically loading and unloading a disk in a light and simple disk driver has been proposed. In this case, a separate driving motor is added to the disk up-down operation for clamping the disk to the turntable. There was a problem in that the manufacturing cost is increased.

Accordingly, it is an object of the present invention to automatically perform loading, unloading and clamping of a disc in a lightweight and compact disc drive device.

Another object of the present invention is to reduce the number of components for loading, unloading and clamping a disk in a light and short disk drive.

1 is a plan view showing a configuration of a disc drive device according to the prior art.

Fig. 2 is a front sectional view showing the structure of a disc drive device according to the prior art.

Figure 3 is an operating state showing that the tray is first drawn out of the set in the disc drive device according to the prior art.

Figure 4 is an operating state showing that the tray is completely drawn out of the set in the disk drive apparatus according to the prior art.

5 is a plan view showing the configuration of a preferred embodiment of a disk drive apparatus according to the present invention.

6 is a front sectional view showing a configuration of a preferred embodiment of a disk drive apparatus according to the present invention.

Fig. 7 is a side sectional view showing the construction of a preferred embodiment of a disc drive device according to the present invention.

Figure 8 is a plan view showing a power transmission path for loading / unloading the disk in a preferred embodiment of the present invention.

9 is a plan view showing a power transmission path for the up and down of the pickup base in a preferred embodiment of the present invention.

10A, 10B, and 10C are operation state diagrams respectively shown in different directions in which an operation for up-down of a pickup base is started in the embodiment of the present invention;

11A and 11B are operation state diagrams showing a state in which the insertion of a disk is completed in the embodiment of the present invention;

12A, 12B, and 12C are operation state diagrams showing a state in which the pickup base is completed in the embodiment of the present invention;

13A, 13B, and 13C are operational state diagrams showing a state in which clamping of a disk is completed in the embodiment of the present invention;

Explanation of symbols on the main parts of the drawings

100: lower chassis 101: guide boss

110: upper chassis 111: guide boss

115,116: detection sensor 120: pickup base

121: turntable 123: pickup unit

125: elevating chassis 126: elevating guide shaft

130,130 ': Disk guide 133,133': Stopper

135,135 ': guide plate 137: connecting spring

138: synchronous gear 140: drive motor

141: worm gear 142: multi-gear gear

142U: Upper Gear 142L: Lower Gear

143: connecting plate 145: connecting gear

146: drive gear 150: drive pulley

151: gear portion 153: driven pulley

155: feed wire 157: tension control spring

160: first connecting gear 161: second connecting gear

162: drive gear 170: elevating drive plate

171,171 ': Information slot 172: Rack gear part

173: disk interlocking projection 174: return spring

175: drive slot 180: elevating rotation lever

181: center of rotation axis 183,183 ': driving projection

190,190 ': Elevator guided lever 191,191': Interlock

193: lifting guide slot 195: cam interlocking boss

200: clamper 210,210 ': clamper holder

211,211 ': Information Boss

According to a feature of the present invention for achieving the above object, the present invention uses a drive motor, a linear member that is driven by the power of the drive motor to be in contact with the side of the disc to transfer the disc, and guides the disc Loading means for loading and unloading the disk while supporting and supporting, Retracting means for retracting the loading means so as not to interfere with the drive of the disk when the loading of the disk is completed, and driven by the power of the drive motor And clamping means for seating and gripping the disk on the turntable.

The loading means includes a support guide means for guiding movement while supporting the disk, a power transmission path for transmitting power of the drive motor, and a drive pulley driven by the power of the drive motor transferred through the power transmission path. It is configured to include a linear member for moving the disk by friction with the side of the disk while being wound and driven between the pulleys.

The surface of the linear member is surface treated to exert a predetermined friction force with the side of the disk.

The power transmission path is a plurality of gears, the gears are provided on one plate, the plate is adapted to exert an elastic force toward the drive pulley, the gear of any one of the gear train and the gear portion of the drive pulley is It is in close contact with elastic force and power is transmitted.

The retracting means is a cam interlocking unit which is moved by the power of the drive motor, and a cam provided in the supporting guide unit and the cam interlocking unit is interlocked with the cam interlocking unit. Selectively move to and center direction.

The clamping means includes a seating means for receiving a driving force of the drive motor to seat the disk on the turntable, a clamper for fixing the disk seated on the turntable on the turntable, and the retracting means while supporting the clamper on both sides. It is configured to include a clamper holder for performing the lifting of the clamper in conjunction with the operation of.

The seating means is connected to the power transmission path for transmitting the power of the drive motor, a moving plate driven by receiving the power transmitted through the power transmission path after the completion of the loading of the disk, the movement of the moving plate It is configured to include a lifting guider for lifting the turntable while moving in the opposite direction to allow the disk to be seated.

An inclined surface is formed at a lower surface of the clamper and an upper end of the clamper holder corresponding to the lower surface of the clamper, respectively, and the elevating of the clamper is performed by interlocking with the inclined surface.

According to the present invention having such a configuration, the disk drive device used in the slimmer device can automatically perform loading, unloading and clamping of the disc using one drive motor, thereby providing convenience to the user. The manufacturing cost can be reduced by reducing the number of parts, and the use of wires for power transmission for loading and unloading of disks can reduce the overall size of the device.

Hereinafter, a preferred embodiment of the disk drive apparatus according to the present invention as described above will be described in detail with reference to the accompanying drawings.

First, the configuration of an embodiment of the present invention will be described with reference to FIG. 5 to FIG. 9.

The exterior of this embodiment is composed of a lower chassis 100 and the upper chassis 110. The lower chassis 100 is bent many times as shown in FIG. 6 to form a space between the upper chassis 110 and the upper chassis 110.

The pickup base 120 is installed on the upper chassis 110. On the pick-up base 120, a turntable 121 on which the disk D is mounted and rotated is installed. The turntable 121 is installed on a spindle motor (not shown) and rotated by the spindle motor. On the pickup base 120, a pickup unit 123 for reproducing the signal recorded on the disk D or recording the signal on the disk D is provided.

Such a pickup base 120 is provided on the lifting chassis 125. The lifting chassis 125 allows the disk D to be seated on the turntable 121 or detached from the turntable 121 while being lifted before and after the disk D is unloaded / loaded. Lift guide shafts 126 and 126 'for lifting the lift chassis 125 are formed at both ends of the lift chassis 125, respectively.

Meanwhile, disc guides 130 and 130 'are provided on the lower surface of the upper chassis 110. The disk guides 130 and 130 'are installed on both sides of the upper and lower sides of the upper chassis 110 to guide both sides of the disk D. The disk guides 130 and 130 'are fixed to the lower surfaces of the guide plates 135 and 135' installed on the lower surface of the upper chassis 110 so as to be movable left and right (based on the drawing).

In addition, a cam 132 for guiding the cam interlocking boss 195 to be described below is formed at one side of the lower surface of the guide plate 135. The cam 132 is interlocked with the cam interlocking boss 195 and the disc guides 130 and 130 'and the guide plates 135 and 135' overcome the elastic force of the connecting spring 137 and both sides of the disc D are in the centrifugal direction. It serves to move to. In addition, stoppers 133 and 133 ′ are formed on one side of the rear end of the guide plates 135 and 135 ′ to regulate the degree of insertion of the disk D.

A plurality of guide slots 136 and 136 'are formed in the guide plates 135 and 135', respectively, and the guide boss 111 in the upper chassis 110 is positioned in the guide slots 136 and 136 '. 135, 135 ') to guide the installation and movement. The guide plates 135 and 135 'are connected to each other by a connecting spring 137. The connecting spring 137 exerts an elastic force in a direction in which the guide plates 135 and 135 'are adjacent to each other. In addition, the guide slots 136 and 136 ′ of the guide plates 135 and 135 ′ have interlocking bosses 211 and 211 ′ of the clamper holders 210 and 210 ′ described below.

Meanwhile, as illustrated in FIG. 5, gear parts 135G and 135'G are formed on the guide plates 135 and 135 ', respectively, and these gear parts 135G and 135'G are formed of a synchronous gear 138. When the one side guide plate 135 is engaged with each other, the other side guide plate 135 'is also simultaneously moved in a direction to be adjacent to each other or to a direction away from each other.

Now, a configuration for transmitting power for loading and unloading the disk D will be described. A driving motor 140 is installed at the rear end of the lower chassis 100. The worm gear 141 is installed on the rotation shaft of the drive motor 140. In addition, a multi-stage gear 142 driven by the worm gear 141 is installed in the lower chassis 100.

An upper gear 142U is formed at an upper portion of the multi-stage gear 142 to transmit power to a configuration for moving the disk D, and a lower gear 142L is formed at a lower portion of the pick-up base 120. It provides power for the configuration. On the other hand, the central shaft 142S of the multi-stage gear 142 is provided with a connection plate 143, as shown in Figure 7 and 8 well.

Attach spring 144 is connected to the free end of the connection plate 143 is installed. The other side of the attach spring 144 is connected to the guide plate 135. And, on the connecting plate 143, a connecting gear 145 is engaged with the upper gear 142U of the multi-stage gear 142. In addition, the driving gear 146 is installed on the connecting plate 143 to be engaged with the other side of the connecting gear 145.

The other side of the drive gear 146 is engaged with the gear portion 151 of the drive pulley 150 installed on the lower surface of the guide plate 135. At this time, the connection plate 143 has a tendency to rotate toward the drive pulley 150 by the attach spring 144, so that the drive gear 146 is the gear portion 151 of the drive pulley 150. Always close to.

The driving pulley 150 is installed in one end of the disk guide 130, and the driven pulley 153 corresponding to the driving pulley 150 is installed in the other end of the disk guide 130.

The feed wire 155 is wound around the driving pulley 150 and the driven pulley 153. The feed wire 155 is in contact with the side of the disk (D) inside the disk guide 130 to move the disk (D). The feed wire 155 is preferably subjected to a surface treatment to have a certain surface roughness in order to maintain a friction force between the disk (D).

In addition, the tension control spring 157 is installed in a predetermined section of the feed wire 155, the feed wire 155 is in close contact with the surface of the pulleys (150, 153) to facilitate power transmission.

Now, a path through which power for raising and lowering the pickup base 120 will be described. First, as shown in FIGS. 7 and 9, a first connecting gear 160 is installed on the lower chassis 100 to mesh with the lower gear 142L of the multi-stage gear 142. In addition, the second connecting gear 161 is engaged with the first connecting gear 160 and is installed on the lower chassis 100. In addition, a driving gear 162 is provided on the lower chassis 100 to mesh with the second connecting gear 161.

The driving gear 162 is engaged with the rack gear part 172 of the lifting driving plate 170 installed on the lower chassis 100 to move the lifting driving plate 170. Guide slots 171, 171 ′ parallel to each other are formed in the elevating driving plate 170, and guide bosses 101 formed on the lower chassis 100 are positioned in the guide slots 171, 171 ′.

Accordingly, the lifting driving plate 170 is supported and moved by the guide slots 171 and 171 'and the guide boss 101. At one end of the elevating driving plate 170, a disc interlocking protrusion 173 is pushed by the movement of the disc D at the end of loading of the disc D. In addition, a return spring 174 connected to the lower chassis 100 is connected to one side of the elevating driving plate 170.

On the other hand, the lifting drive plate 170 is formed with a driving slot 175 consisting of a right angle section. The driving slot 175 is a driven projection 182 of the lifting and lowering lever 180 to be described below.

One side of the lower chassis 100, the elevating rotation lever 180 is installed. The elevating rotation lever 180 is installed to be rotated by a predetermined angle about the rotation center axis 181, and one side thereof is positioned in the driving slot 175 of the elevating drive plate 170 and the elevating plate 170. ), A driven protrusion 182 is formed to rotate the lifting and lowering lever 180 in accordance with the movement. In addition, driving protrusions 183 and 183 'are formed at both ends of the lifting and lowering lever 180, respectively.

On the other hand, as shown in Figure 6, on both sides of the lower chassis 100, the elevating guide (190, 190 ') is provided. The lifting guide levers 190 and 190 'are moved in opposite directions by the lifting rotation lever 180 to create a lifting movement of the pickup base 120.

The elevating guide levers 190 and 190 'are provided with interlocking holes 191 and 191' in which driving protrusions 183 and 183 'are provided at both ends of the elevating rotation lever 180, respectively. In addition, as shown in FIG. 7, the elevating guide slots 190 and 190 ′ guide the elevating guide slots 126 and 126 ′ of the elevating chassis 125 to elevate and elevate the elevating guide 125. 193 is formed. The heights of the sections of the elevating guide slots 193 of the elevating guide levers 190 and 190 'on both sides are formed to be opposite to each other. This is because the lifting guide levers 190 and 190 'are moved in opposite directions.

On the other hand, the cam linking boss 195 is formed on one side of the lifting guide lever 190. The cam interlocking boss 195 guides the cam 132 formed on the disc guide 130.

In addition, clamper holders 210 and 210 'supporting the clamper 200 are installed between the upper chassis 110 and the guide plates 135 and 135'. The clamper 200 serves to hold the disk D so that the disk D seated on the turntable 121 does not fall off during rotation. The clamper holders 210 and 210 'are formed with guide bosses 211 and 211' at one side thereof, respectively, and are positioned in guide slots 136 and 136 'of the guide plates 135 and 135' and interlock with the guide plates 135 and 135 '.

Here, the clamper holders 210 and 210 'are connected to each other by the return springs 213 so that the guide plates 135 and 135' are relatively adjacent to each other by the restoring force of the return springs 213. Such clamper holders 210 and 210 'are to raise and lower the clamper 200 so that the clamper 200 can hold the disk D as necessary.

In the present invention, the lower edge of the clamper 200 and the upper surfaces of the clamper holders 210 and 210 'facing each other are formed to be inclined with each other, as illustrated in FIG. 6, so that the clamper holders 210 and 210' are clamped. Guide the ascent of 200.

In the drawing, reference numeral 115 denotes a detection sensor for detecting the retraction of the disk, and 116 is a detection sensor for detecting the completion of clamping of the disk.

The operation of the embodiment of the present invention having such a configuration will be described in detail below.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disk drive device used in a slimmer device such as a notebook computer. The disk is loaded and unloaded using a wire, and the disk is driven using the power of the drive motor used for loading and unloading the disk. Even clamping can be done automatically.

That is, in the state shown in FIG. 5, when the user inserts the disk D into the disk guides 130 and 130 ′, the disk guides 130 and 130 ′ which have been moved toward the turntable 121 are relatively moved. It will happen. At this time, one side of the left side of the disk D is in contact with the feed wire 155.

When the user inserts the disk D to some extent, the disk guides 130 and 130 'are opened, and the guide plates 135 and 135' are also opened. In this case, the detection sensor 115 is separated from the guide plates 135 and 135 ', thereby detecting the insertion of the disk D. As such, when the insertion of the disk D is detected, the driving motor 140 starts to rotate.

The rotational force of the driving motor 140 is transmitted to the driving gear 146 through the worm gear 141 and the multi-gear gear 142 via the connecting gear 145. Therefore, the feed wire 155 is driven while the driving pulley 150 rotates by the interlocking of the gear unit 151 of the driving pulley 150 engaged with the driving gear 146.

When the feed wire 155 starts to be driven, the disc D moves inside and is loaded by friction between the feed wire 155 and the disc D. As such, as the disk D is moved inwards, the disk guides 130 and 130 'and the guide plates 135 and 135' become wider and wider. Here, the synchronous gears 138 meshed with the gears 135G and 135'G of the guide plates 135 and 135 'are interlocked with each other. At this time, the rack gear unit 172 and the drive gear 162 of the elevating drive plate 170 is not in engagement yet.

In this way, the state where the disk D has almost entered is shown in FIG. Referring to FIG. 10A, the disk D is driven and moved by the feed wire 155, and the disk D is almost adjacent to the top of the turntable 121. Then, one side of the disk (D) is in contact with the disk interlocking projection 174 of the lifting drive plate 170. 10B and 10C, the pickup base 120 has not been raised yet.

In the state of FIG. 10 as described above, when one side of the disk interlocking protrusion 173 and the disk D comes into contact, the elevating driving plate 170 moves by the disk D and the elastic force of the return spring 174. Overcoming this will move in the direction of the arrow A. By this movement, the rack gear part 172 of the elevating driving plate 170 is engaged with the drive gear 162. Therefore, while the driving force of the driving motor 140 is transmitted to the lifting driving plate 170 through the driving gear 162, the lifting driving plate 170 is now moved by the driving force of the driving motor 140. Done.

When the disk D is accurately positioned above the turntable 121 by the movement of the disk D, as shown in FIG. 11A, the stoppers 133 and 133 'located at the rear end of the disk guides 130 and 130'. ) Further movement of the disc D is stopped. At the same time, as the lifting driving plate 170 is moved, the driven protrusion 182 is guided by the driving slot 175 so that the lifting rotating lever 180 starts to rotate clockwise about the rotation center axis 181. do.

When the elevating rotation lever 180 starts to rotate, the elevating guide levers 190 and 190 'are moved by driving protrusions 183 and 183' in the interlocking holes 191 and 191 'of the elevating guide levers 190 and 190'. To start. Therefore, as illustrated in FIG. 11B, the lifting guide shaft 126 of the lifting chassis 125 starts to be guided in the lifting guide slot 193. At this time, the cam 132 of the disc guide 130 and the cam interlocking boss 195 of the lifting guide lever 190 also start to interlock.

As such, the lifting guide shaft 126 is guided along the lifting guide slot 193 and the pick-up base 120 starts to rise. At the same time, the disc guides 130 and 130 'are separated from the side surfaces of the disc D by the cam 132 and the cam interlocking boss 195 to move to the outside.

In this case, the disk guides 130 and 130 'are moved outwards due to the interlocking of the cam interlocking boss 195 and the cam 132 according to the movement of the elevating guider 190. At the same time as the disk (D) is seated on the turntable does not interfere with the rotation of the disk (D). This state is well illustrated in FIGS. 12A, 12B and 12C.

Meanwhile, if the driving force of the driving motor 140 is continuously transmitted in the state of FIG. 12, the clamping of the disk D is completed as shown in FIGS. 13A, 13B, and 13C. That is, the lifting driving plate 170 receives power through the driving gear 162 and continues to move, whereby the lifting rotating lever 180 is rotated. The rotation of the elevating rotation lever 180 creates a continuous movement of the elevating guide lever 190 to guide the elevating guide shaft 126 to the elevating guide slot 193, thereby making it in the state of FIG. 13C. As such, when the elevating guide shaft 126 is in the highest section of the elevating guide slot 193 (relative to the lower chassis 100), the elevating chassis 125 is raised to the highest position and the pickup base The 120 and the turntable 121 installed thereon are raised so that the disk D is seated on the turntable 121.

The disk guides 130 and 130 'are also spaced apart from the side of the disk D as much as possible so as not to interfere with the rotation of the disk D as shown in FIG. 13B. The disk guides 130 and 130 'are moved by the interlocking of the cam 132 and the cam interlocking boss 195. That is, as the cam interlocking boss 195 moves together with the lifting guide lever 190, the cam 132 is moved in the direction of arrow C while being interlocked with the cam interlocking boss 195. This movement, together with the same direction movement of the disc guide 130, produces a movement in the opposite direction of the arrow C of the opposite disc guide 130 '. At this time, the disk guide 130 'is moved by the gear unit 135G and 135'G of the guide plates 135 and 135' and the synchronous gear 138.

By the movement of the guide plates 135 and 135 ', the clamper holders 210 and 210' are operated. That is, as the guide plates 135 and 135 'are moved in the direction of arrow C, the guide bosses 211 and 211' of the clamper holders 210 and 210 'are shown in FIG. 13A, and the guide slots 136 and 136 of the guide plates 135 and 135'. ') Is guided to one end of the side while overcoming the elastic force of the return spring 213, respectively, are moved in the direction of the arrow C. Accordingly, the clamper 200 supported by the clamper holders 210 and 210 'falls, and the disk D mounted on the turntable 121 is firmly mounted on the turntable 121 so that the disk D Clamping is completed. At this time, the sensor 116 detects that the clamping is completed away from the guide plate 135 'as shown in Figure 13a to stop the operation of the drive motor 140.

On the other hand, the clamper holder (210, 210 ') and the portion in which the clamper 200 is interlocked with each other made of the inclined surface is formed when the opposite operation is performed when the clamper holder (210,210') moves in the opposite direction to ride the inclined surface of the clamper ( 200 is mounted on the clamper holder (210, 210 ').

What has been described so far is the operation from the loading of the disc D to the clamping, and the unclamping and unloading of the disc D is done in the reverse of the above operation. At this time, the driving motor 140 is rotated as opposed to when loading, the movement in the opposite direction as described when loading by the driving force of the drive motor 140. In particular, the return spring 213 connecting the clamper holders 210 and 210 ', the connecting spring 137 connecting the guide plates 135 and 135', and the return spring 174 connected to the elevating driving plate 170 are connected to these. The member serves to facilitate the movement in the opposite direction as when loading.

Disc drive device according to the present invention as described in detail above is to use in a slimmer device such as a notebook to seek light and short. To this end, the feed wire driven by the power of the drive motor is rubbed with the side of the disk to load and unload the disk. That is, since the feed wire is relatively thin, the diameter or height of the pulley for driving it is not so large, so that the device can be made light and thin.

In addition, clamping is performed using the power of the drive motor that loads and unloads the disk, so that the loading, unloading and clamping of the disk can be performed automatically, minimizing components while seeking convenience for the user. To reduce manufacturing costs.

Claims (8)

Drive motor, A loading means which uses a linear member which is driven by the power of the drive motor and is in contact with the side of the disk to transfer the disk, and performs loading / unloading of the disk while guiding and supporting the disk; Retraction means for retracting the loading means so as not to interfere with the drive of the disc when the loading of the disc is completed; And a clamping means driven by the power of the drive motor to clamp the disk seated on the turntable. According to claim 1, wherein the loading means is supported by the support guide means for guiding movement while supporting the disk, the power transmission path for transmitting the power of the drive motor, and the power of the drive motor transmitted through the power transmission path And a linear member which is wound between the driven pulley and the driven pulley to be driven and friction with the side of the disk to move the disk. The disk drive apparatus according to claim 2, wherein the surface of the linear member is surface treated to exert a predetermined friction force with the side surface of the disk. 3. The power transmission path according to claim 2, wherein the power transmission path is a plurality of gears, the gears are provided on one plate, and the plate is adapted to exert an elastic force toward the driving pulley. The gear unit of the drive pulley is a disk drive device characterized in that the power transmission is in close contact with the elastic force. The support guide according to claim 1, wherein the retracting means is a cam interlocking unit which is moved by the power of the driving motor, and a cam provided in the supporting guide unit and interlocked with the cam interlocking unit. And a means for selectively moving the means in the centrifugal direction and the center direction of the disc. 2. The clamping device of claim 1, wherein the clamping means includes: a seating means for receiving a driving force of the driving motor to seat the disk on the turntable; a clamper for fixing the disk seated on the turntable on the turntable; and both sides of the clamper. And a clamper holder configured to support lifting and lowering of the clamper in association with the operation of the retracting means. According to claim 6, The seating means is a power transmission path for transmitting the power of the drive motor, and a moving plate driven by receiving the power transmitted through the power transmission path after the completion of the loading of the disk, and the movement And a lift guide lever configured to lift and lower the turntable while interlocking with the movement of the plate to allow the disk to be seated thereon. 7. The disk drive apparatus according to claim 6, wherein an inclined surface is formed at a lower surface of the clamper and an upper end of the clamper holder corresponding to the lower surface of the clamper, and the elevating of the clamper is performed by interlocking the inclined surfaces.