KR100693176B1 - Tray mode sensing apparatus in disk drive - Google Patents

Abstract

A tray mode sensing device of a disk drive is provided to enable a rising cam to directly operate on/off actions of a sensing switch, thus the on/off actions of the sensing switch is conducted in a relatively exact way, consequently an operational mode of the tray is more accurately sensed. A tray moves a disk as moving between unloading and loading positions along a main base(20). A rising cam(30) receives a driving force of a loading motor(22) installed on the main base(20), and moves in a vertical direction of a moving direction of the tray. A sensing switch is installed on the main base(20) corresponding to a moving locus of the rising cam(30). Driving ribs are protruded from the rising cam(30), and selectively turn on/off the sensing switch along with movement of the rising cam(30).

Description

Tray mode sensing apparatus in disk drive}

1 is a plan view showing a main configuration of a disk drive according to the prior art.

Fig. 2 is a plan view showing the main structure of a disk drive employing a preferred embodiment of the tray mode sensing apparatus according to the present invention.

Figure 3 is a partial side cross-sectional view showing the main portion of the embodiment of the present invention.

Figure 4 is a partial side cross-sectional view showing another main configuration of an embodiment of the present invention.

5 is a partial front sectional view showing another main configuration of an embodiment of the present invention.

6 is a plan view showing the main portion of the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

20: main base 20 ': tray

20r: interlocking rib 22: loading motor

24: driven pulley 25: driven pulley

26: belt 27: drive gear

29: Small Gear 30: Lifting Cam

31: first driving rib 32: second driving rib

33: first interlocking portion 35: second interlocking portion

37: Drive Boss 40: Eject Lever

50: sensing switch 50 ': tip substrate

51: first lever 52: second lever

The present invention relates to a disk drive, and more particularly, to a tray mode sensing apparatus of a disk drive to detect the position of the tray for loading and unloading a disk in the disk drive to perform the operation control of the disk drive. .

1 is a plan view showing a main structure of a disc drive according to the prior art. According to this, the pickup base 3 is provided in the main base 1 forming the frame of the disc drive. The rear end of the pickup base 3 is rotatably connected to the rear end of the main base 1. The pick-up base 3 is lifted up and down a predetermined range with respect to the rear end with respect to the main base 1. Along the upper surface of the main base 1 is provided a tray 4 for loading and unloading disks. In the figure, the tray 4 is indicated by a dotted line.

In order to allow the leading end of the pickup base 3 to move up and down, the lifting base 5 is provided at the leading end of the pickup base 3. The lifting base 5 is mounted to the front end of the pickup base 3, and the rear end is connected to the main base 1 so as to rotate about a hinge pin. The lifting base 5 is linked with the lifting cam 7 installed near the tip of the main base 1 to lift the tip of the pickup base 3.

The loading motor 8 is installed at the tip of the main base 1. The loading motor 8 provides power for the movement of the tray 4. The driving force of the loading motor 8 is transmitted to the drive gear 10 through the belt (9). The drive gear 10 is meshed with the tray drive gear 12 installed in the main base 1. The tray driving gear 12 is engaged with the rack gear provided on the lower surface of the tray to transfer the power of the loading motor 8 to the tray 4.

In addition, the tray driving gear 12 moves the lifting cam 7 in the left and right directions (based on the drawing) of the main base 1. To this end, the tray driving gear 12 and the lifting cam 7 are provided with gear teeth engaged with each other.

An eject lever 14 is installed on the front end surface of the main base 1. The eject lever 14 is installed on the main base 1 so as to rotate about the rotation shaft 15. The eject lever 14 is rotated by being operated by a wire or the like outside the disk drive to drive the lifting cam 7 so that the tray can be taken out of the disk drive. The eject lever 14 is supported by the lever spring 16 and can be moved to its original position when the operation force transmitted from the outside is removed.

The sensing switch 18 is installed on the front end surface of the main base 1 corresponding to the movement trajectory of the eject lever 14. The sensing switch 18 senses the position of the tray 4 while being turned on and off according to the position of the eject lever 14. The operation of the disc drive is controlled according to the position of the tray 4 detected as described above. For example, by detecting that the tray 4 is in the unloading position, the operation of the loading motor 8 is stopped.

However, the above-described disc drive according to the prior art has the following problems.

The sensing switch 18 is turned on / off by the eject lever 14. That is, the eject lever 14 is linked and moved together by the movement of the lifting cam 7, and the detection switch 18 is turned on / off by the eject lever 14. Therefore, the on / off operation of the sensing switch 18 may not be performed properly due to tolerances or assembly tolerances of these components themselves.

In addition, the sensing switch 18 is turned on and off by the rotation operation of the eject lever 14, and the movement trajectory of the eject lever 14 is relatively short, and in particular, the eject lever 14 has at least a user tray 4. ) To eject the tray 4 only to the position where it can be ejected by hand. Accordingly, there is a problem in that the tray 4 cannot be accurately sensed until the tray 4 completely exits to the outside, that is, the unloading completion state.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, to ensure that the operation of the sensing switch for detecting the operation state of the tray is made accurately.

Another object of the present invention is to be able to detect the operating state of the tray in more detail.

According to a feature of the present invention for achieving the above object, the present invention provides a tray for moving a disk while moving between an unloading position and a loading position along a main base, and a driving force of a loading motor installed on the main base. Receiving the lifting cam is moved in the vertical direction to the moving direction of the tray, the sensing switch is installed on the main base corresponding to the movement trajectory of the lifting cam, protruding to the lifting cam is formed to move the lifting cam And a driving rib for selectively turning on and off the sensing switch. The sensing switch includes first and second levers, and the lifting cam includes first and second levers for driving the first and second levers. A second driving rib is provided, wherein the first driving rib is formed to have a relatively longer length than the second driving rib. The rib is formed to extend longitudinally in the direction of movement of the lifting cam.

An interlocking rib is formed on the lower surface of the tray to regulate the movement of the elevating cam according to the movement of the tray. To guide.

The first driving rib is designed to turn on the first lever in a state where the tray is loaded and in a moving state, and the second driving rib is designed to turn on the second lever only when the tray is loaded. .

delete

The lifting cam is provided with a driving boss that is guided to the interlocking rib of the tray is guided to move the lifting cam in accordance with the movement of the tray.

According to the tray mode detection apparatus of the disk drive according to the present invention having such a configuration, since the lifting cam directly operates the detection switch for detecting the mode of the tray, the mode can be detected more accurately, and the tray is completely unloaded. Since the lifting cam can move in conjunction with the tray, it can detect the loading state, the unloading state, and the moving state of the tray, so that it can detect and control the operation state of the tray more finely, which increases the operation reliability of the disk drive. There is an advantage.

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

FIG. 2 is a plan view showing the main configuration of a disk drive employing a preferred embodiment of the tray mode sensing apparatus according to the present invention, and FIG. 3 is a partial side cross-sectional view showing the main configuration of the present embodiment. 4 is a partial side cross-sectional view showing another main configuration of the embodiment of the present invention, Figure 5 is a partial front cross-sectional view showing another main configuration of the embodiment of the present invention, Figure 6 is a plan view of the main configuration of the embodiment of the present invention Is shown.

As shown in these figures, the main base 20 forms a skeleton of the disc drive. For convenience, only a portion of the tip of the main base 20 is shown. A pickup base (not shown) is installed on the main base 20 so that the tip thereof can be lifted up and down, and a tray 20 '(see FIG. 6) is movable along the upper surface of the main base 20. do. The pickup base includes a spindle motor providing a driving force for rotating the disk, a turntable on which the disk is seated, and an optical pickup for recording and reproducing signals on the disk. A stopper 21 is provided at one side of the front end surface of the main base 20. The disk seating surface on which the disk is seated is formed on the tray 20 '. The tray 20 'is moved to the loading position and the unloading position with the disc seated. An interlocking rib 20r for interworking with the lifting cam 30 to be described below is formed on the bottom surface of the tray 20 '. The interlocking rib 20r is elongated in the front-rear direction on the lower surface of the tray 20 'and extends inclined outward from the rear end of the tray 20'.

One end of the main base 20 is provided with a loading motor 22. The loading motor 22 provides power to produce movement of the tray 20 'for loading and unloading discs. The driving force of the loading motor 22 is transmitted to the driving gear 27 through the driving pulley 24, the driven pulley 25 and the belt 26. The drive gear 27 is installed coaxially with the driven pulley 25. The tray driving gear 28 is installed in the main base 20 to be engaged with the driving gear 27. The tray driving gear 28 is engaged with a connecting gear (not shown) engaged with the rack gear formed on the lower surface of the tray to transmit the driving force of the loading motor 22 to the tray. The tray driving gear 28 also drives the lifting cam 30 to be described below. For this purpose, the small gear part 29 is provided. Of course, the lifting cam 30 may be driven by using a gear separate from the tray driving gear 28.

The lifting cam 30 is installed on the main base 20. The lifting cam 30 is installed to be movable in a direction orthogonal to the direction in which the tray is loaded and unloaded (left and right directions in the drawing). The lifting cam 30 receives the driving force of the loading motor 22 and moves to the left and right in the drawing while the front end of the pickup base serves to elevate.

A first driving rib 31 and a second driving rib 32 are formed on the lower surface of the lifting cam 30. The driving ribs 31 and 32 serve to selectively press the levers 51 and 52 of the sensing switch 50 to be described below. The driving ribs 31 and 32 protrude from the lower surface of the lifting cam 30. The first driving rib 31 is formed long in the moving direction of the lifting cam 30. Accordingly, the first driving rib 31 presses the first lever 51 of the sensing switch 50 in the loading state and the moving state of the tray 20 '.

The second driving rib 32 is configured to press on the second lever 52 only when the tray 20 'is completely loaded. To this end, the length of the second driving rib 32 is shorter than that of the first driving rib 31.

One end of the elevating cam 30 protrudes from the first interlocking part 33. The first interlocking portion 33 is a portion formed to protrude in a plate shape on the upper surface of one side of the lifting cam 30. The first interlocking portion 33 is interlocked with the eject lever 40 to be described below at the beginning of the emergency eject, or when interlocked with the interlocking protrusion 43 of the eject lever 40 when an input / output operation of the tray is normally performed. Allow the eject lever 40 to rotate.

A second interlocking portion 35 is provided on one side of the upper surface of the elevating cam 30 adjacent to the first interlocking portion 33. The second linking part 35 is formed to protrude on one side of the upper surface of the lifting cam 30 in the present embodiment. At the position where the second linking part 35 is formed, a driving boss 37 for allowing the lifting cam 30 and the tray (not shown) to be interlocked is provided. The driving boss 37 is protruded in the shape of a rod on the upper surface of the lifting cam 30 to be interlocked with the interlocking rib 20r of the tray 20 '.

The eject lever 40 is installed on the front end surface of the main base 20. The lever body 40 'constituting the eject lever 40 is formed in a substantially plate shape. One end of the lever body 40 'is formed with a rotating shaft portion 41. The rotating shaft portion 41 is rotatably inserted into the shaft hole formed in the main base 20.

One end of the lever body 40 'is formed with an interlocking protrusion 43. The linkage protrusion 43 extends from one end of the lever body 40 '. The interlocking protrusion 43 is interlocked with the lifting cam 30 when the disk drive is normally operated. The interlocking protrusion 43 also serves to regulate the range of rotation of the eject lever 40 by hanging on the stopper 21.

The lever body 40 ′ is provided with a first driving finger 45. The first driving finger 45 extends substantially in the same direction as the extending direction of the linkage protrusion 43. The first driving finger 45 is formed at a distance away from the linkage protrusion 43. However, when the first driving finger 45 is based on the rotation shaft part 41, the first driving finger 45 is provided at a position relatively far from the linkage protrusion 43. The first driving finger 45 is interlocked with the first interlocking portion 33 of the elevating cam 30 at the initial stage of the emergency ejection.

A second driving finger 47 is formed on the lever body 40 '. The second driving finger 47 is formed at the extreme end of one side of the lever body 40 ', that is, the opposite side of the interlocking protrusion 43. The second driving finger 47 extends farther from the front end portion than the base portion with respect to the first driving finger 45. This is to allow the linkage between the second driving finger 47 and the second edge eastern part 35 of the lifting cam 30 to occur more smoothly. In particular, the initial movement of the eject lever 40 to the original position by the elevating cam 30 is to occur smoothly. The second driving finger 47 is located farthest from the rotating shaft portion 41 that is the rotation center of the eject lever 40. Therefore, it is linked with the lifting cam 30 in the late stage of the emergency eject.

The lever body 40 'is also provided with a pin linkage 49. The pin interlocking part 49 is a part where the pin actually touches when the user drives the eject lever 40 by inserting a pin such as a wire from the outside. The pin interlocking part 49 is provided at a position opposite to the first and second driving fingers 45 and 47.

On the other hand, on the main base 20, the sensing switch 50 is installed on the trajectory in which the lifting cam 30 is moved. The sensing switch 50 is mounted on the front end substrate 50 ′ provided in the main base 20. The tip substrate 50 'is a part in which a component for driving the loading motor 22 is mounted. The detection switch 50 is provided with a first lever 51 and a second lever 52. The first lever 51 is turned on and off by the first rib 31, and the second lever 52 is turned on and off by the second rib 32.

For reference, two sensing switches each having one lever may be used instead of the sensing switch 50 provided with the first lever 51 and the second lever 52. However, in this case, the number of the sensing switches becomes two, thereby increasing the number of parts.

Hereinafter, the operation of the emergency ejecting device of the disk drive according to the present invention having the above configuration will be described in detail.

In a disk drive, the tray 20 'is a seat for loading and unloading a disk. The tray 20 ′ is loaded and unloaded by the driving force of the loading motor 22. That is, when the loading and unloading signals of the tray 20 'are given, the loading motor 22 is driven. The driving force of the loading motor 22 is transmitted to the tray driving gear 28 through the driving pulley 24, the driven pulley 25, and the belt 26 to drive the tray 20 ′ and the lifting cam 30. Let's do it.

That is, the tray 20 'is moved by the driving force of the loading motor 22, and the lifting cam 30 is also moved. For example, in the unloading operation, the lifting cam 30 moves to the right with respect to FIG. 2, and the pick-up base is lowered. The tray 20 ′ protrudes out of the disk drive by the driving force of the loading motor 22.

At this time, the eject lever 40 is also rotated by the rightward movement in the drawing of the lifting cam 30. The eject lever 40 is rotated clockwise. That is, the eject lever 40 rotates in the clockwise direction by pushing the first interlocking part 33 of the elevating cam 30 to one side of the interlocking protrusion 43.

When the disk is loaded, the lifting cam 30 moves to the left in the drawing, and the first interlocking portion 33 is interlocked with the first driving finger 45. Therefore, when the loading operation of the disk is completed, the eject lever 40 is in a state as shown in FIG. In FIG. 2, the first driving finger 45 and the first interlocking part 33 are in contact with each other.

As the lifting cam 30 is moved by the driving force of the loading motor 22, the levers 51 and 52 of the detection switch 50 are turned on and off by the driving ribs 31 and 32. The mode in which the tray 20 'is operated is detected.

That is, as shown in FIG. 3, the tray 20 ′ has completed loading when the first and second driving ribs 31 and 32 are turned on by pressing the first and second levers 51 and 52. If in a state. That is, when the first and second levers 51 and 52 are simultaneously pressed and turned on, it is detected that the tray 20 'is in a loading completion state.

Next, when the tray 20 'is moved from the loading position to the unloading position by the loading motor 22, the first driving rib 31 moves the first lever 51 as shown in FIG. By pressing on, the second driving rib 32 can no longer press the second lever 52, and the second lever 52 is in an off state. In this case, it is detected that the tray 20 'is between the loading position and the unloading position.

On the other hand, the lifting cam 30 does not continuously move in a direction orthogonal to the moving direction of the tray 20 'when the tray 20' is unloaded. After moving to a certain degree, the driving boss 37 is walked on the interlocking rib 20r provided on the lower surface of the tray 20 'so that it no longer moves.

However, when the tray 20 'comes to the unloading completion position, the end of the interlocking rib 20r is inclined outward so that the driving boss 37 of the elevating cam 30 is the interlocking rib 20r. Is moved along.

As such, when the unloading is completed, the lifting cam 30 is further moved in a direction orthogonal to the moving direction of the tray 20 ', and the first driving rib 31 is the sensing switch 50. ), The first lever 51 is no longer pressed. In this case, the first lever 51 is also turned off, and both the first and second levers 51 and 52 are turned off. In this case, it is detected that the tray 20 'is completely unloaded.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

In the tray mode detecting apparatus of the disk drive according to the present invention as described in detail above, the following effects can be obtained.

In the present invention, the sensing switch is placed on the movement trajectory of the lifting cam driven by the loading motor, and the sensing switch is turned on and off by the driving rib of the lifting cam. Thus, since the lifting cam directly performs the on / off operation of the sensing switch, the on / off operation of the sensing switch can be relatively accurate. Therefore, there is an effect that it is possible to detect and control the operation mode of the tray more accurately.

In the present invention, the operation mode of the tray can be detected by dividing it into a loading, unloading and moving mode. Therefore, the operation state of the tray can be sensed and controlled more finely, thereby improving the operation reliability of the disk drive.

Claims (5)

A tray for moving the disc while moving between the unloading position and the loading position along the main base, A lifting cam which receives the driving force of the loading motor installed on the main base and moves in a direction perpendicular to the moving direction of the tray; A sensing switch installed on the main base corresponding to the movement trajectory of the elevating cam; Is formed to include a drive rib protruding from the lifting cam to selectively turn on and off the detection switch in accordance with the movement of the lifting cam, The sensing switch is provided with first and second levers, and the lifting cam includes first and second driving ribs for driving the first and second levers. The first driving rib has a relatively longer length than the second driving rib, the first driving rib is formed to extend in the direction of movement of the lifting cam, characterized in that the tray mode of the disc drive. The lower surface of the tray is formed with an interlocking rib for regulating the movement of the elevating cam according to the movement of the tray, the end of the interlocking rib is formed to be inclined toward the outside of the tray to unload the elevating cam A tray mode sensing device of a disk drive, characterized by guiding movably upon completion. 3. The method of claim 1, wherein the first driving rib turns on the first lever in a state where the tray is loaded and moves, and the second driving rib is in the second state only when the tray is loaded. A tray mode sensing device of a disc drive, characterized in that its length is designed to turn on the lever. delete 4. The tray mode sensing apparatus of claim 3, wherein the lifting cam is provided with a driving boss that is guided to the interlocking rib of the tray to guide the lifting cam to move according to the movement of the tray.

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