KR19980026575A - Disc ejecting device and its driving cam - Google Patents

Abstract

The present invention is a disc loading device using a loading plate in the drive unit side power to the switching plate in a way to share the power to the ejecting device and to drive the drive unit to configure a new ejecting device that is interlocked with the power, A power switching gear unit including a driven gear intermittently engaging the drive unit and transmitting the power to the other side according to the driving mode, an eject lever unit for operating the holding device while being engaged with the gear unit, and the drive unit power The disk ejecting device comprising a member connecting the gear portion and the eject lever portion to intermittently transmit to the eject lever portion side.

Description

Disc ejecting device and its driving cam

A commonly used disc loading device is a structure for loading / unloading a disc by a tray.

The disc loading method by tray has a tray driver for picking up / unloading a disc and a pick-up driver, and guides the disc according to a selection mode so that there is no meandering or damage during loading, and no large malfunction such as a path deviation occurs when removing the disc.

However, for loading / unloading discs, the tray is operated first and the disc is inserted or removed later, which is inconvenient to operate the tray.

The disc loading mechanism of US Pat. No. 5,038,337 and the disc ejecting structure introduced in No. 5,136,570 install a transverse driving / trans roller 2 inside the disc housing 1 as shown in Figs. A plurality of detection elements 4 and 4a for detecting the position of the disk 3 are provided inward to control the drive unit by reading the position of the disk, and disc loading / unloading can be performed without discriminating the size of the disk. The device compensates for the disadvantages of using a disc loading device that uses a tray for loading / unloading a disc, for example by pushing the disc 4 to the prepared disc port 5 without depending on a member such as a tray. If it is, it is moved to the destination as it is and loaded on the turntable (6).

Even in the case of unloading, the ejection of the disk proceeds by the ejector of the mechanism part 7 in the disk, and the disk is ejected by the rotating frictional force of the driving roller 2 in the next time.

However, the device uses the friction force of the trans roller 2 to move the disk 3 in the loading / unloading mode, thereby damaging the disk 3 by the surface contact friction between the disk 3 and the trans roller 2. There are disadvantages.

Another disc loading device of US Pat. No. 5,255,255 is the same as the direct loading method of Fig. 2 for pushing the disc 3 into the disc port 5, which is a characteristic of the roller driving method, and the loading / unloading method of the disc.

The apparatus is a direct disk loading apparatus having the disk moving path of FIG. 3 and the driving means configured as an example as shown in FIG. 4, wherein the disk loading rollers 8 and 8a have a predetermined moving area inside the disk housing 1 and have a disk. It is dependent on the position of (3) and moves along the path, the main part of which is left and right rollers 8 and 8a in close contact with the side of the disk 3 and the rollers 8 and 8a. Guide rails (9) and (9a) for guiding the movement of the left and right symmetrical drive gear group (11) joined by a plurality of gears to turn each roller (8) (8a) to the rotational force of the loading motor (10) 11a and the position of the disk 3 are detected to control the loading motor 10.

The disc loading in this device turns the loading motor 10 when the disc 3 is inserted, and the loading motor 10 determines the rotational direction of the rollers 8 and 8a to clamp the disc 3 to the turntable.

When the unloading mode is input to the loading motor 10, the loading motor rotates in the opposite direction to the loading direction, and the gears interlocked in both directions move the rollers 8, 8a and rails 9, 9a. The disk 3 is released by the rotational friction of the rollers 9 and 9a in the process of moving along the rollers, and the positions of the rollers 8 and 8a are along the rails 9 and 9a. Variable relative to position

In this case, it is possible to load the disc 3 as it is, without a separate transport mechanism in the loading of the disc. However, the clamping error due to the rapid wear of the roller for repeated use of the disc and the deviation of the disc path from the disc loading is caused. There are disadvantages.

In addition, increasing the double speed of the loading device is important to the organic coupling relationship of the parts that the gears of a large number of gears are difficult to adapt to the conditions of increasing the speed, the probability of error is increased accordingly.

Another disc loading device of FIG. 5 which compensates for the disadvantages of the above devices is a base plate 12 which is the main chassis, a left / right holding device 13L and 13R for guiding the disc, and a disc 3 with the base plate. The clamp assembly 15 clamps the disk 3 in the course of moving the loading plates 14L and 14R divided into left and right to move along the 12 and the loading plates 14L and 14R. It is possible to change the width of the loading plates 14L and 14R for holdering and ejecting, and to configure the drive unit for interlocking the ejection device, so that loading / unloading of the disk 30 is performed without the tray by the plates 14L and 14R. You can proceed.

The device guides the disk 3 into the plane by means of the loading plates 14L and 14R without a tray, eliminating phenomena such as damaging, meandering, etc. of the disk during loading, while significantly reducing the number of gears and centering the disk to the turntable. This results in a high quality loading device with low misclamping.

However, the loading plates 14L and 14R, which are the media for directly moving the disk 3, are repeatedly moved forward and backward along the base plate 12 with a large contact cross section at the base plate 12 side by the drive unit power. In addition, there is a burden of interlocking the ejecting device to the driving part during the exercise, and it has the mechanical feature that it is important to effectively match the other interlocking parts.

For example, in the eject mode, the first operation of the loading plates 14L and 14R is performed, and in the meantime, the drive side power is shared on the ejecting device side, or the drive side power is transferred to the ejecting device. Adjacent devices such as the holding device 13R by the lever 16 have a burden of directly or indirectly interlocking.

The ejecting device includes an ejector lever 1 (16) with a rack (17), a holding device (13R) with a tooth (18) engaged with the gear on the ejector lever (2) 16a side, and the rack (side) with the ejector lever (16). Another ejector lever 2 (16a) meshed with 17) has a strong configuration.

When the interlocking relationship of the ejecting device is seen in the ejecting state of FIG. 6A, in the ejecting mode, the loading plates 14L and 14R move in the C direction, and then the ejector lever 1 16 moves to the gears 19 and 19a. When it is moved in the same C direction by receiving the side rotational force, the other boss 16c of the eject lever 2 16a moves in the same direction as (b) along the cam trajectory 16b on the other side thereof. The gear 20 is rotated in the A direction about the hinge portion 16d to induce the gear 20 to engage with the teeth 18 on the holding device 13R side, and then the gear 20 is moved by the forward force of the eject lever 1 16. By rotating the holding device 13R to release the disc 3. However, as described above, the gear 20 of the eject lever 2 16a, the teeth 18 of the holding device 13R side, and the racks of the eject lever 1 16 are engaged at the same time. There was a problem that could not eject the disk.

In addition, in order to transfer the driving side power to the eject lever 1 (16), which is the main part of the ejecting device, a separate stepping motor is used to form a light and simple loading device that is compatible with the operation of the loading plates 14L and 14R. The problem was how to use the drive side power without using it.

The present invention relates to a power transmission drive cam for connecting a driving unit to an ejecting device by connecting the driving unit power with the loading plate in a disk loading apparatus using a loading plate, and from the cam gear. It is to provide a direct ejecting device without the dead lever of the eject lever from being powered and interlocked to operate the holding device directly.

Figure 1 shows a conventional disk ejecting apparatus, (a) the disk loading state (b) the progress of (a)

2 is a disk ejecting apparatus of FIG.

3 is a view showing an example of another conventional loading device

4 is a disk loading apparatus of FIG.

5 is a view showing an example of another disk loading apparatus

Figure 6 is for explaining the loading plate deadlock state (A) the state before the deadlock when ejecting (B) the state during the deadlock (E) the ejection state of the normal state without the deadlock

7 is a view showing a configuration example of the ejecting apparatus of the present invention

8 shows the ejector lever of FIG. 7, (a) is a plan view (b) is (a) is a bottom view

9 is a plan view of the eject lever holder of FIG.

10 is a detailed view of a disk ejecting device drive cam according to the present invention.

FIG. 11 is a detailed view of portion A of FIG. 10;

12 is a view showing an initial assembly state of the present invention ejecting device

FIG. 13 is a view illustrating an ejecting device unit according to a disk loading in FIG. 12.

14 is a view showing a disk ejection completion state by the ejecting apparatus of the present invention

15 is a disk loading completion state according to an embodiment of the present invention.

16 is a view showing a disk eject completion state according to an embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

21: base plate 22L, 22R: loading plate

23L, 23R: Holding device 24: Drive cam

25: ejector lever 26: loading motor

27: moving gear 28: stay gear

29: group 1 gear 30: group 2 gear

31: driven gear 32: primary gear

33: secondary gear 34: rack

35: eject lever holder 36: track

37: projection 38: cam curve

39: connecting member 40: spring

41: right fixed shaft of the connecting member 42: power loss area

43: contact end 44: expansion space

45: gradient 46: embossing

47: central axis 48: hook

49: stop groove 50: return spring

51: rotating pin 52: elastic plate

The present invention is a base plate 21, holding plate 23L (23R) installed in the loading plate 22L (22R), the loading plate 22L (22R) moving divided by left / right along the base plate 21, In the disk loading apparatus that selectively includes a driving unit and an ejecting device for driving the loading plates 22L and 22R, and a regulating device and a safety device, as shown in FIG. Drive cam 24 to be transmitted to 25, and an ejecting device engaged with the drive cam 24 to linearly move along the loading plates 22L and 22R.

The ejecting apparatus further includes a drive unit, a power switching gear unit intermittently engaged with the drive unit, and transmitting the power to the other side according to the driving mode, an eject lever unit which operates the holding device while being engaged with the gear unit; And a member connecting the gear part and the eject lever part to intermittently transmit the driving part power to the eject lever part side, and the driving cam 24 uses the loading plates 22L and 22R as shown in FIG. The disk loading apparatus is configured to share the driving unit with the ejecting apparatus by connecting to the ejecting apparatus by switching the driving unit power to the disk ejecting apparatus.

The power switching gear part includes a loading motor 26 and a group of gear parts 29 including a stay gear 28 provided with a moving gear 27 which is linked to the loading motor 26 and drives the loading plate 22R. ) And two groups of gear units 30 that match the group of gears 29 according to the disc ejection driving mode.

The power shift gear portion is composed of a drive cam 24 intermittently engaged with a group of gear portions 29, and a driven gear 31 engaged with the drive cam 24, the driven gear 31 being a drive cam. It consists of the primary gear 32 which meshes with 24, and the secondary gear 33 which transmits the power of the said primary gear 32 to the eject lever 25 side.

In addition, the driven gear 31 is connected to the drive cam 24 so that the rotation radius of the primary gear 32 is relatively larger than the rotation radius of the secondary gear 33, and the secondary gear 33 is an eject lever ( 25) Install on the side rack (34).

The ejecting lever part includes an ejector lever 25 having a rack 34 driven by the driven gear 31 and an ejector for fixing the ejector lever 25 to a base plate 21 in a path designating manner. The lever holder 35 is configured to include a holding device regulator in the eject lever holder 935.

The holding device regulator forms a raceway 36 at the tip of the eject lever holder 35 and a protrusion 37 on the holding device 23R side so that the protrusion 37 is inserted into the eject lever holder 35. It is configured to restrict the rotation of the holding device 23R in accordance with the position of the eject lever holder 35.

The connecting member main body 39 fixing the driven gear 31 has a fixed shaft 41 at the right end thereof located on the guide groove 21a of the base plate 21, and a left fixed shaft 31A at the left end thereof. The base plate 21 is installed with the elastic member 40 so as to be in contact with the cam curve 38 on the driving cam 24 side and to closely contact the cam curve 38 on the driving cam 24 side. It is constructed by holding on).

Also, as shown in FIGS. 10 and 11, a driving cam 24 having a cam curve and converting power to share the loading device driving side power to the loading plates 22L and 22R and the ejecting device transmits the driving side power. The gear contact end 43 which starts to transmit the power to the power loss area 42 and the driven gear 31 side which are not received, and the contact end 43 which guides the engagement of the drive part and the driven gear 31. Inward) an embossing 46 is formed to limit the expansion and contraction space 44 and the amount of expansion and displacement, and the tip of the contact end 43 has a gradient 45.

In addition, the power loss area 42 is configured to be 180 degrees out of phase with respect to the central axis 47 is configured to be connected to the drive unit and the power is disconnected by the connecting member 39.

Meanwhile, the eject lever 25 constituting the ejecting device has a rack 34 and several hooks 48 as shown in FIG. 8, and thus is elastically coupled to the stop groove 49 of the eject lever holder 35 of FIG. 9. And is mounted on the base plate 21.

12 is an initial assembly of the ejection device, the eject lever 25 is located below the loading plate 22R. When the eject lever 25 moves downward when the ejection is completed, the power is lost by the drive cam 24. The spring 50 positioned on the right end of the eject lever holder 35 is returned in a condition where there is no one-way moving force, and is also associated with the holding device 23R.

Fig. 13 shows the progress state after the disc loading according to the present invention, and Fig. 13 is the eject completion state.

Fig. 15 is a loading completion state of the disc loading device in which the ejecting device and the drive cam are combined, and Fig. 16 is the ejecting completion state thereof.

An important element constituting the ejecting device of the present invention is a driving cam 24, a driven gear 31, and an eject lever part as shown in FIG. 7, and the driving part is interlocked with the loading motor 26 and the loading motor 26. And the loading plate 22R is operated by the group of gears 29 including the stay gear 28 provided with the moving gear 27 for driving the loading plate 22R.

The gear group 30 of the two groups matched to the group of gears 29 according to the disc ejection driving pattern is engaged in ejection to the driving unit and transmits its power to the ejecting device on the other side according to the driving mode. As the driving cam 24 is engaged with the gear group 29 of the first group, the driven gear 31 is rotated, and the driven gear 31 receives the rotational force through the primary gear 32 to receive the secondary gear 33. Power is transmitted to the eject lever 25 side through.

The eject lever portion engaged with the driven gear 31 via the rack 34 operates the holding device 23R, and the power switching to the eject lever portion rotates according to the cam curve 38 of the drive cam 24. It is executed in the member 39.

That is, the left end side fixed shaft 39A of the connecting member 39 is installed in a state of being caught by the cam 24 side cam curve 38, and the right end side fixed shaft 41 is the guide groove 21a of the base plate 21. When the elastic plate 52 fixed to the loading plate 22R is lowered in the direction of the arrow while pushing the fixing shaft 41 on the right end of the connecting member 39, the connecting member 39 rotates in the D direction. As the left end fixed shaft 31A pushes the jaw portion 53 of the drive cam 24 as shown in FIG. 7, the drive cam 24 rotates counterclockwise while the gear contact end 43 of the drive cam 24 is geared. When the driving cam 24 starts to rotate while being connected to the 54, the gear contact end 43 in a 180 degree phase difference rotates the driven gear 31 to transmit power to the eject lever 25 side. The loading plate 22R continues after the elastic plate 52 of the loading plate 22R moves the right end fixed shaft 41 of the connecting member 39 onto the space of the guide groove 21a of the base plate 21. When the downward direction is lowered, the elastic plate 52 is also lowered to the right end of the fixed shaft 41 of the connecting member 39, when the restraining force is released, the elastic member 40 of the connecting member 39 is pulled so that the connecting member 39 Is restored to the form as shown in FIG.

In this way, the initial position of the right fixing shaft 41 of the connecting member 39 is located above the guide groove 21a of the base plate 21. At this time, there is no upper space of the guide groove 21a, so the loading plate 22R is loaded. If it moves upward, the elastic plate 52 is still in the upper space of the guide groove 21a even when the right fixing shaft 41 is pushed, so that the left fixing shaft 31A of the connecting member 39 is the driving cam 24. Drive jaw 24 does not rotate at the time of loading since the jaw portion 54 of () cannot be pushed.

The eject lever part functions as a regulator of the holding device 23R. When the eject lever 25 is moved forward, as shown in FIG. 16, the track 36 at the tip of the eject lever holder 35 is a holding device ( When the eject lever 35 moves by engaging the protrusion 37 on the 23R side, the displacement is transmitted to the holding device 23R side as it is, and the holding device 23R rotates about the pin 51, thereby rotating the disk. Eject out.

In the state of FIG. 15 in which the loading of the disk is completed, the driving cam 24 is not receiving power from the driving unit side, and the ejecting device unit side is also in a state of no movement.

However, in the eject mode, when the drive cam 24 rotates in the counterclockwise direction of the arrow, the driven gear 31 rotates in the clockwise direction of the arrow, causing the eject lever 25 to pass through the rack 34 of the eject lever 25. Advance.

Fig. 16 shows the ejection state of the disk ejection, and the ejector lever portion pivots out the holding device 23R, and the end-side rack 34 has the driven cam 31 in the power loss area 42 with the drive cam 24; Since the relative side in the 180-degree direction is also powered off, the eject lever 25 is restored to the position as shown in FIG. 7, which is the initial position by the spring 50, and the holding device 23R is also restored.

If there is disk loading in the state of FIG. 7, the above operation is performed again.

As described above, the present invention can connect the driving unit side power to the ejecting apparatus side using the driving cam in the disk loading apparatus using the loading plate and share the same to the ejecting apparatus as one driving unit, which is linked to the ejecting apparatus. It can be connected as it is without holding parts on the holding device side, so that the eject lever and peripheral parts are not dead when ejecting, and accurate ejecting operation is realized.

The present invention reduces the number of parts of the power transmission system by driving the ejecting device through one drive unit in the disk loading device using the first loading plate.

Second, even simple configuration of the ejecting device improves product reliability by reducing the possibility of deadlocks during the operation of the ejecting device.

Third, it contributes to the high quality of the disc loading apparatus using the loading plate.

The present invention is to share a single power to the ejecting device by the method of switching the drive side power to the loading plate in the disk loading apparatus using a loading plate to configure a new ejecting device that is interlocked with this power.

Claims (13)

A driving unit, a power switching gear unit intermittently engaged with the driving unit, and transmitting the power to the counterpart according to the driving mode; An eject lever portion which engages with the gear portion and moves the holding device while moving; And a member connecting the gear part and the eject lever part to intermittently transmit the driving part power to the eject lever part side. The method of claim 1, wherein the driving unit and the loading motor, A gear group of a group consisting of a stay gear provided with a moving gear which drives the loading plate in association with the loading motor; And a group of gears matched to the group of gears according to the disk ejection driving mode. The cam gear according to claim 1 or 2, wherein the power shift gear portion is intermittently engaged with the group of gear portions; And a driven gear meshed with the cam gear. 4. The driven gear according to claim 3, wherein the driven gear includes: a primary gear engaged with the cam gear; And a secondary gear for transmitting the power of the primary gear to the eject lever side. 5. The disk ejecting apparatus according to claim 4, wherein the rotation radius of the primary gear of the driven gear is relatively larger than the rotation radius of the secondary gear. 2. The ejecting lever according to claim 1, further comprising: an ejector lever body having a rack which is driven by the driven gear side; And an eject lever holder configured to fix the eject lever main body in a form of designating a path to the base plate. 7. The disk ejecting device according to claim 6, wherein a holding device regulator is included in the eject lever holder. 8. The holding device regulator according to claim 7, wherein the holding device regulator forms an orbit at the tip of the eject lever holder, and a projection is formed on the holding device side to guide the projection on the orbit so as to control the rotation of the holding device according to the position of the eject lever holder. Disc ejecting device, characterized in that. The connecting member of claim 1, wherein the connecting member fixes the driven gear, one end of the fixed shaft moves along the guide groove of the base plate, and the other end of the connecting shaft is hooked to the cam gear side cam curve; And a disc ejecting device held on the base plate by an elastic member to bring the connecting member into close contact with the cam gear side cam curve. 10. The disk ejecting apparatus according to claim 9, wherein an elastic plate is provided at one side of the base plate so that the elastic plate can rotate the connecting member. In the driving cam having a cam curve to convert the power to the loading device drive unit power to the loading plate and ejecting device, The drive cam has a power loss area for intermittently receiving the drive side power and limitedly transmitting the power to the driven gear side, and a gear contact end thereof, and for contacting the drive unit and the driven gear side to guide the gear engagement. Disc ejecting device drive cam, characterized in that the expansion space extending from the end. 12. The disk ejecting device drive cam according to claim 11, wherein there is an embossing having a gradient at the tip of the contact end and limiting contraction inside the contact end. 12. The disk ejecting device driving cam according to claim 11, wherein the power loss area is set with a phase difference of 180 degrees with respect to a central axis.