KR100621040B1 - A tray ejecting apparatus for disk drive - Google Patents

Abstract

The present invention relates to an eject device of a disk drive. In the present invention, the solenoid 80 is installed on the main base 70 is installed on the tray 72 is mounted on the disk and moved, the drive piece 82 is provided in and out according to the application of the electrical signal do. An ejection arm 100 for selectively fastening the tray 72 to the main base 70 while rotating within a predetermined range within the tray 72 is provided. A plunger lever 90 is provided to transfer power between the solenoid 80 and the eject arm 100. The body 91 constituting the plunger lever 90 is connected to the driving piece 82. The body 91 has a drive leg 98 is formed so as to extend and bend to one side to transfer power to the eject arm 100. An elastic member 96 is provided to provide an elastic force in a direction in which the driving piece 82 protrudes in a direction opposite to the portion coupled with the driving piece 82. According to the ejection apparatus of the disk drive according to the present invention having such a configuration, the drive piece 82 is accurately inserted into the solenoid 80 during operation to increase the operation reliability, the fewer components, the assembly labor is reduced and the material cost is reduced There is an advantage.

Disc Drive, Tray, Solenoid, Plunger Lever

Description

A tray ejecting apparatus for disk drive

1 is a partially cutaway plan view showing a structure of a disk drive according to the prior art.

2a and 2b is an operation state showing the operation process of the tray ejection apparatus of the disk drive according to the prior art.

Fig. 3 is a plan view showing the main part of a disk drive employing a preferred embodiment of the tray ejection apparatus according to the present invention.

4A, 4B and 4C are operational state diagrams illustrating that the embodiment of the present invention operates.

Explanation of symbols on the main parts of the drawings

70: main base 72: tray

74: drive pin 76: locking pin

80: solenoid 82: drive piece

90: plunger lever 91: body

92: guide pin 94: guide slot

96: elastic member 98: drive leg

98a: connection part 98b: connection part

100: ejector arm 102: central axis

104: driven leg 106: locking jaw

108: torsion spring

The present invention relates to a disk drive, and more particularly to a tray ejecting device of a disk drive for fastening the tray in the main base of the disk drive or ejecting the tray from the main base.

1 is a partially cutaway plan view showing the structure of a disk drive according to the prior art, and FIGS. 2A and 2B are diagrams illustrating an operation of the tray ejection apparatus of the disk drive according to the prior art.

According to this, the tray 4 is installed on the main base 2 constituting the lower appearance of the disc drive so as to be able to enter and exit the inside and outside of the disc drive. On one surface of the tray 4 is formed a disk seating portion 6 in which the disk is located. The cover plate 8 forms a part of the disc seat 6. A pickup window 10 is formed on the cover plate 8. The cover plate 8 is partially cut off and the circle of the notched part is indicated by a dotted line.

The tray 4 is provided with a pickup base 12. The pickup base 12 is provided on the lower surface of the tray 4. The pickup base 12 is provided with a spindle motor (not shown), and the turntable 14 is provided on the rotation shaft of the spindle motor so as to be exposed at the center of the disc seat.

The pickup base 12 is provided on the pick-up base 12 to be movable so that light can be irradiated along the pickup window 10 to a disk seated on the turntable 14. It is supported and moved along a pair of guide shafts 18 installed in the. Reference numeral 19 denotes a push lever that provides an elastic force for ejecting the tray 4.

The solenoid 20 is installed in the tray 4. The solenoid 20 loses its magnetic force to the magnet of the solenoid 20 according to the application of an electrical signal, such that the driving piece 22 fixed therein may protrude out of the solenoid 20. The plunger arm 30 is rotatably provided by a predetermined range in a direction in which the driving piece 22 of the solenoid 20 moves, and the body 31 constituting the plunger arm 30 has the driving piece 22. Will be moved together. That is, when the driving piece 22 makes a linear movement, the plunger arm 30 makes a rotational movement about the rotation shaft 32.

Opposite portions of the body 31 of the plunger arm 30 coupled with the driving piece 22 are connected to the tray 4 by an elastic member 34 having elastic force. The elastic member 34 provides an elastic force in a direction in which the driving piece 22 protrudes outward from the solenoid 20.

A first driving leg 36 is provided parallel to the body 31 of the plunger arm 30. The first driving leg 36 is engaged with the first driven leg 44 of the reset arm 40 to be described below to rotate the reset arm 40. In addition, the second driving leg 38 is formed to extend on the opposite side of the body 31. The second driving leg 38 is engaged with the second driven leg 54 of the eject arm 50 to be described below to rotate the eject arm 50.

In addition, a reset arm 40 is provided at a position corresponding to the first driving leg 36 in the tray 4. The reset arm 40 is rotatably installed in a predetermined range around the central axis 42, and the first driven leg 44 is formed at a position corresponding to the first driving leg 36. In the reset arm 40, the protrusion 46 is formed at a position orthogonal to the first driven leg 44 so as to be caught by the locking protrusion 62 to be described below. When the tray 4 is closed, the protruding portion 46 is caught by the catching protrusion 62 and serves to obtain a driving force for the reset arm 40 to rotate. In addition, a torsion spring 48 is provided to provide an elastic force in a direction in which the first driven leg 44 of the reset arm 40 pushes the first driving leg 36.

An ejection arm 50 is provided at a position corresponding to the second driving leg 38 in the tray 4. The ejection arm 50 is rotatably installed in a predetermined range around the rotation shaft 52, and a second driven leg 54 is formed at a position corresponding to the second driving leg 38. In addition, a locking step 56 is formed at a position orthogonal to the second driven leg 54 in the eject arm 50 so as to be engaged with the locking protrusion 62 to be described below. In addition, an elastic member 58 is provided to provide an elastic force in a direction in which the second driven leg 54 of the eject arm 50 pushes the second driving leg 38.

In addition, a locking protrusion 62 is formed on the main base 2 in a movement stroke section in which the protrusion 46 of the reset arm 40 and the locking jaw 56 of the eject arm 50 move. The locking protrusion 62 is engaged with the protrusion 46 to rotate the reset arm 40, and is engaged with the locking jaw 56 so that the tray 4 is fixed to the main base 2. Do it.

When the user opens the tray 4, once the user applies the eject signal to the main base 2, power is applied to the solenoid 20, and the magnet of the solenoid 20 loses its magnetic force and is driven. The piece 22 is released. Therefore, the driving piece 22 protrudes out of the solenoid 20 by the restoring force of the elastic member 34 of the plunger arm 30 connected to the driving piece 22.

When the driving piece 22 protrudes out of the solenoid 20, the body of the plunger arm 30 rotates clockwise (a) about the rotation shaft 32. Since the plunger arm 30 rotates in the clockwise direction a, the first driving leg 36 and the second driving leg 38 also rotate in the clockwise direction a. The reset arm 40 is rotated in the counterclockwise direction a 'about the central axis 42 by the first driven leg 44 engaged with the first driving leg 36, and the second driving leg is rotated. The ejection arm 50 is rotated about the rotation axis 52 in the counterclockwise direction a '' by the second driven leg 54 engaged with the 38, so that the ejection device is shown in FIG. 2A. It is in the same state. That is, as the locking step 56 is separated from the locking protrusion 62, the tray 4 protrudes forward by the elastic member 19 to be opened.

When the tray 4 is closed, the user pushes the tray 4 into the main base 2 so that the locking protrusion 62 moves the protrusion 46 of the reset arm 40 clockwise (b '). Have them turn. When the reset arm 40 rotates in the clockwise direction b ', the plunger arm 30 engaged with the reset arm 40 rotates in the counterclockwise direction b, and engages with the plunger arm 30. The eject arm 50 rotates in the clockwise direction b '' to engage the locking projection 56 with the locking projection 62. That is, when the tray 4 is fully inserted into the main base 2, the structure of the ejection device is as shown in Fig. 2b.

However, the eject device of the disk drive according to the prior art as described above has the following problems.

That is, when closing the tray 4, the rotational movement of the reset arm 40 transmitted by the movement of the tray 4 is transmitted to the plunger arm 30, the rotational movement transmitted to the plunger arm 30 The drive piece 22 is transferred to the linearly moving drive piece 22. As such, the plunger arm 30 and the driving piece 22 connected to each other are configured to rotate and linearly move, respectively, so that the driving piece 22 cannot linearly move along the correct trajectory.

Therefore, the driving piece 22 may not be correctly inserted into the solenoid 20, and thus, the driving piece 22 is not securely fixed to the inside of the solenoid 20, thereby deteriorating operation reliability.

In addition, the ejection device of the disk drive is composed of a solenoid 20, a plunger arm 30, a reset arm 40, an ejector arm 50, and each elastic member, which is complicated in structure and has many components. There is a problem that the number increases and the material cost increases.

Accordingly, the present invention is to solve the problems of the prior art as described above, an object of the present invention is to provide an ejecting device of a disk drive that can be accurately inserted and fixed to the solenoid.

Another object of the present invention is to provide an ejecting device for a disk drive with a simple structure and few components.

According to a feature of the present invention for achieving the above object, the present invention is installed on a tray that is installed on the main base, the disk is moved, the drive piece that can be entered in and out according to the application of the electrical signal is provided Solenoids; An eject arm mounted on the tray to selectively fasten the tray to the main base while rotating in a predetermined range; And one side is connected to the drive piece of the solenoid and the other side is in contact with the one side of the ejection arm is interlocked and linear movement with the drive piece It is configured to include a plunger lever.

A plunger lever is connected to the drive piece, and a plunger lever is formed with a drive leg bent to extend to one side of the plunger lever so as to transmit power to the ejector arm, and the drive in a direction opposite to the portion coupled with the drive piece. Preferably, the elastic member is provided to provide an elastic force in the direction in which the piece protrudes.

Preferably, a driving pin is formed on the main base to move the plunger lever, and a locking pin is formed on the driving pin to be spaced a predetermined distance apart.

The eject arm is rotatable about a central axis, and a driven leg is provided at one side to engage the driving leg, and a locking jaw is formed to be caught by a locking pin formed on the main base in a direction orthogonal to the driven leg. Preferably, the ejection arm is provided with an elastic member for providing an elastic force so that the locking jaw is rotated in the direction in which the locking jaw is engaged with the locking pin.

A guide pin is formed in the tray, and a guide slot is formed in the plunger lever so that the guide pin is inserted, and the guide pin is inserted into the guide slot to guide the movement of the plunger lever.

According to the ejection apparatus of the disc drive according to the present invention having such a configuration, the plunger lever is linearly moved so that the power is accurately transmitted to the driving piece so that the driving piece is correctly inserted into the solenoid, so that the operation reliability is high, and the number of components is small. There is an advantage in that it is reduced and material costs are reduced.

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

 3 is a plan view showing the main part of a disk drive employing a preferred embodiment of the tray ejection apparatus according to the present invention.

As shown in this figure, the main base 70 forms the outer appearance of the disc drive. The tray 72 is installed on the main base 70 so as to be able to enter and exit the disk drive. On one side of the main base 70, a driving pin 74 for driving the plunger lever 90 to be described below, and a locking pin 76 for selectively engaging the locking jaw 106 of the eject arm 100. Is formed.

The solenoid 80 is installed in the tray 72. Inside the solenoid 80, the drive piece 82 is installed to be accessible. That is, as the electrical signal is applied to the solenoid 80, the magnetic force of the magnet provided in the solenoid 80 is lost, and the locked state of the driving piece 82 is released, so that the driving piece 82 is the solenoid 80. It can be protruded to the outside.

In addition, the tray 72 is provided with a plunger lever 90 to be movable in a predetermined range in a direction in which the driving piece 82 of the solenoid 80 moves. The body constituting the plunger lever 90 is provided. 91 is installed to be connected to the drive piece (82). Thus, the driving piece 82 and the plunger lever 90 are moved together.

In the body 91, a guide slot 94 is formed so that the guide pin 92 formed in the tray 72 can be inserted and guided. The length of the guide slot 94 is formed to be equal to or slightly larger than the movement stroke of the drive piece 82 provided in the solenoid 80. The guide slot 94 and the guide pin 92 serve to allow the plunger lever 90 to stably linearly move. Accordingly, the driving piece 82 and the plunger lever 90 may linearly move together.

Opposite portions of the body 91 connected to the driving piece 82 are connected to the tray 72 by an elastic member 96 such as a coil spring. The elastic member 96 provides an elastic force in a direction in which the driving piece 82 protrudes outward from the solenoid 80.

One side of the body 91 is provided with a driving leg 98 extending in the moving direction of the drive piece 82. That is, the driving lever 98, the connecting portion 98a extending along the side of the solenoid 80 at one side of the body 91 of the plunger lever 90 and the solenoid 80 at the tip of the connecting portion 98a. ) Is composed of an interlocking portion 98b bent to the opposite side. The linkage 98b is in contact with the driven leg 104 of the eject arm 100, which will be described below.

An ejection arm 100 is provided at one side of the tray 72 where the plunger lever 90 is installed. The ejection arm 100 is rotatably installed in a predetermined range around the central axis 102, and a driven leg 104 is formed at a position corresponding to the driving leg 98. In addition, the locking jaw 106 is formed to be caught by the locking pin 76 of the main base 70 at a position orthogonal to the driven leg 104. In addition, a torsion spring 108 is provided to provide an elastic force in the direction in which the driven leg 104 of the ejector arm 100 pushes the driving leg 98. The elastic force of the torsion spring 108 is relatively smaller than the elastic force of the elastic member 96.

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

4A, 4B, and 4C show an operation state diagram illustrating the operation of an embodiment of the present invention. According to this, when a user applies an eject signal onto the main base 70, the tray ( An electrical signal is applied to the solenoid 80 of 72. When an electrical signal is applied to the solenoid 80, the magnet of the solenoid 80 loses its magnetic force, and the driving piece 82 fixed to the solenoid 80 is released. When the driving piece 82 is released, the driving piece 82 protrudes out of the solenoid 80 by the restoring force of the elastic member 96 acting on the plunger lever 90 connected to the driving piece 82. do.

As the driving piece 82 protrudes out of the solenoid 80, the plunger lever 90 is also moved. The plunger lever 90 is moved in the opposite direction of the solenoid 80 by the restoring force of the elastic member 96. Therefore, the plunger lever 90 moves upwards to be in a state as shown in FIG. 4A.

When the plunger lever 90 moves, the driving leg 98 of the plunger lever 90 also moves. When the driving leg 98 is moved, the driven leg 104 of the ejector arm 100 is also engaged with the driving leg 98 to rotate clockwise (a) about the central axis 102. That is, the eject arm 100 rotates clockwise (a) while overcoming the elastic force of the torsion spring 108.

Therefore, as the eject arm 100 rotates in the clockwise direction (a), the locking jaw 106 is separated from the locking pin 76 of the main base 70. The tray 72 is moved by the restoring force of a push lever (not shown) that provides an elastic force that causes the tray 72 to be ejected when the locking step 106 is separated from the locking pin 76. Protrude a certain distance outward. This state is shown in FIG. 4B.

Once the tray 72 protrudes out of the main base 70, the eject arm 100 is rotated counterclockwise (b) with reference to the drawing by the elastic force of the torsion spring 108. Will be. In such a state, the user pulls the tray 72 by hand, draws it out of the disk drive, and exchanges or removes the disk.

On the contrary, when the tray 72 is inserted into the main base 70, the user pushes the tray 72 inwardly of the main base 70 while overcoming the elastic force of the push lever.

When the user pushes the tray 72 further into the main base 70, the driving pin 74 fixed on the main base 70 moves the plunger lever 90 to the solenoid 80. Will be pushed in the direction. When the plunger lever 90 moves, the driving piece 82 connected to the plunger lever 90 is inserted into the solenoid 80 and seated and fixed.

In addition, as shown in Figure 4c, the inclined surface of the tip of the locking projection 106 of the eject arm 100 is pushed along the locking pin 76, the eject arm 100 is clockwise (a) Will be rotated. As the locking pin 76 crosses the tip of the locking jaw 106, the main force of the torsion spring 108 is applied to the ejection arm 100 rotated clockwise (a) by the locking pin 76. While this is working, the locking pin 76 is rotated in the counterclockwise direction (b) again to be engaged with the locking step (106). Thus, the tray 72 is fixed inside the main base 70.

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

In the ejection apparatus of the disk drive according to the present invention as described in detail above, the following effects can be expected.

In the present invention, since both the plunger lever and the driving piece connected to each other are configured to linearly move, the driving force of the plunger lever is accurately transmitted to the driving piece so that the operation of the driving piece is precisely performed, thereby increasing the operation reliability of the solenoid.

In addition, the ejection apparatus of the disk drive is composed of a solenoid, a plunger lever and an eject arm, the structure is simple, there are relatively few components, there is an effect of reducing the assembly labor and material costs.

Claims (5)

A solenoid installed on the main base and installed on a tray on which the disk is mounted and moving, the solenoid having a driving piece that can be moved in and out according to the application of an electrical signal; An eject arm mounted on the tray to selectively fasten the tray to the main base while rotating in a predetermined range; And One side is connected to the drive piece of the solenoid and the other side is in contact with the one side of the ejection arm is interlocked and linear movement with the drive piece And a plunger lever. The tray ejection apparatus of a disk drive, characterized in that it comprises a. The method of claim 1, The plunger lever is connected to the driving piece, and the plunger lever is formed with a driving leg bent to extend to one side of the plunger lever so as to transmit power to the ejector arm, and in the opposite direction to the portion coupled with the driving piece. And a resilient member provided to provide an elastic force in a direction in which the driving piece protrudes. The method of claim 2, And a driving pin formed on the main base to move the plunger lever, and a locking pin formed on the driving pin to be spaced a predetermined distance apart. The method of claim 3, wherein The ejector arm is rotatable about a central axis, and a driven leg is provided at one side to engage the driving leg, and a locking jaw is formed to be caught by a locking pin formed on the main base in a direction orthogonal to the driven leg. And the ejecting arm is provided with an elastic member for providing an elastic force so that the locking jaw rotates in the direction in which the locking jaw is engaged with the locking pin. The method according to any one of claims 1 to 4, A guide pin is formed in the tray, and a guide slot is formed in the plunger lever to insert the guide pin, and the guide pin is inserted into the guide slot to guide the movement of the plunger lever. Eject device.

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