JP2009271960A - Detachable actuator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To maintain sequence of insertion and ejection even when a detachable external storage device is drawn out from a detachable actuator before the detachable external storage device is completely inserted. <P>SOLUTION: The detachable actuator includes a storing part storing the detachable external storage device 2, a means engaging and disengaging the detachable external storage device to/from the detachable actuator when the detachable external storage device is inserted, and a push-in/push-out mechanism provided with an eject button 1-a-14 and has a structure wherein the detachable external storage device is ejected by pushing the eject button by a prescribed amount, and the eject button is automatically stored in the detachable actuator when the detachable external storage device is ejected from the storing part by pushing the eject button. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a detachable operation device that can be used in insertion and ejection of an electronic device such as a detachable external storage device. In particular, for example, a detachable operation having a detachable external storage device such as a hard disk, an optical disk, a floppy (registered trademark) disk, etc., which has a lock and eject mechanism and has a low load and excellent operability during detachment. A device is provided.

  In a conventional detachable operation device used for insertion and ejection of a removable external storage device such as a hard disk, the removal of the removable external storage device from the detachable operation device is mechanically performed by operating an eject operation member such as a link. The structure to be discharged is adopted. In such a structure, the discharge load becomes high, and the operability during attachment / detachment has been a problem.

  In these attachment / detachment operation devices, for example, an eject device provided with a so-called push-in / push-out mechanism capable of ejecting a hard disk or the like by pressing an eject button twice may be used. In these apparatuses, if the eject button is not pushed to a predetermined position when ejecting the removable external storage device, the eject button returns to the front, and the user needs to perform the eject operation again. Further, there is a risk that the eject button may be pushed by mistake when the removable external storage device is not inserted. Further, in the conventional detachable operation device, the eject button may come out quickly, and the eject operation may not be smooth.

  If the eject button comes out in front of the removable actuator when the hard disk is inserted into the removable actuator before the hard disk is completely stored in the removable actuator, the user must press the eject button again. Have to do. Also, if the eject button comes out early, it may be mechanically defective because it is returned without being completely inserted.

In many cases, the hard disk or the like is pulled out from the detachable operation device before the hard disk or the like is completely inserted during use. In such a case, a state where the eject button pops out without a hard disk or the like being inserted occurs. If the eject button comes out early, a malfunction occurs when it is returned without being completely inserted. Further, the ejection of the eject button causes the insertion / ejection sequence to be out of order and cause an operational abnormality. If the sequence is out of order, the normal state may not be restored.
JP2002-288777 JP 11-134063 A

  The present invention provides an attachment / detachment operation device that is excellent in operability with a low load at the time of attachment / detachment in an ejection device provided with a lock and ejection mechanism in a removable external storage device such as a hard disk, an optical disk, and a floppy disk. The present invention employs a mechanism that pushes out an eject button after a hard disk or the like is completely inserted, and a mechanism that cannot push the eject button when the eject button does not come out. That is, the automatic storage of the eject button is a feature of the present invention, and is assisted by the spring force stored during insertion to reduce the load required for ejection.

  The invention described in the embodiments of the present specification includes a detachable operation device having means for locking and unlocking the detachable external storage device when the detachable external storage device is inserted into a storage unit. The first and second sliders, each having a rack portion and biased by first and second assist springs, are arranged up and down, and the first and second sliders face each other. The rack portion is linked by a pinion gear disposed between the rack portions, and a spring force is stored in each assist spring when the removable external storage device is inserted, so that the removable external storage device is ejected. Sometimes, after the locking is released, the spring force stored in the assist spring when the removable external storage device is inserted is used as an assist force, and the removable external storage device can be used with a low load. Including the invention according to detachable operating device, characterized in that it made it possible to discharge from the detachable operating device. By providing a discharging mechanism incorporating a spring, the ejecting operation is superior to a mechanism that mechanically discharging, and the amount of discharging movement can be increased.

  Further, when ejecting the detachable external storage device, a third spring in the slider ejecting mechanism of the first slider biased by the spring is used to further increase the amount of movement of the detachable external storage device. Including an invention relating to an attaching / detaching operation device, characterized in that a third slider discharge mechanism biased by is provided.

  Further, when ejecting the removable external storage device, the removable external storage device has means for temporarily fixing the removable external storage device when the removable external storage device is automatically ejected to a predetermined position. The invention concerning the detachable operation device is included. By providing a function for temporarily fixing the removable external storage device at the time of ejection, it is possible to prevent the removable external storage device such as a hard disk from falling off and to leave it in a temporarily fixed state.

  Furthermore, the invention according to the detachable operation device further comprising a speed reducing means that acts so that the detachable external storage device is ejected to a predetermined position at a low speed when ejecting the detachable external storage device. including. Further, the rack portion is engaged with a damper that causes the detachable external storage device to be discharged at a low speed, and the first slider and the third slider have grooves at regular intervals. And an invention relating to an attachment / detachment operation device in which high-viscosity grease is applied to the engaging portion. By providing a mechanism that allows the removable external storage device to be ejected at a low speed to a predetermined position at the time of ejection, safety and a high-class feeling at the time of ejection are obtained.

  The invention described in the embodiments of the present specification is a detachable operation device used for a detachable external storage device, and a storage unit in which the detachable external storage device is stored, and the detachable external storage device A means for locking and releasing the detachable operation device with respect to the detachable external storage device when the detachable external storage device is inserted, and an ejecting mechanism from the storage portion of the detachable external storage device. A push-in / push-out mechanism with a button, and when the eject button is pushed to eject the removable external storage device from the storage unit, the eject button is pushed by a predetermined amount to attach / detach the external storage device. And a mechanism for automatically retracting the eject button into the attachment / detachment operation device at the same time as the battery is discharged. Including the.

  Furthermore, it has a locking means for preventing the eject button from moving in the ejecting direction until the removable external storage device is inserted and locked at a predetermined position in the removable operating device. The invention includes an invention relating to a detachable operation device, and further includes means for releasing the locking by the locking means, and the releasing means stops the locking by the locking means after the removable external storage device is completely inserted. The invention includes an invention relating to an attachment / detachment operation device that is released and enables the eject button to move in a discharging direction. By providing the locking means, it is possible to prevent the eject button from coming out before the removable external storage device is completely stored in the step of inserting the removable external storage device.

  Further, after the eject button is automatically stored in the attachment / detachment operation device, and the attachment / detachment operation device is completely inserted, the stop by the locking means is released, and the ejection button moves in the discharge direction. It includes a detachable actuating device characterized in that a cam groove shape for a push-in / push-out mechanism is formed to enable it.

  According to the present invention, an attachment / detachment operation device having a low load and excellent operability at the time of attachment / detachment is provided. A detachable operation device is formed that is assisted by the spring force that is sometimes stored and reduces the load required for discharging.

  Further, according to the present invention, there is formed a detachable operation device capable of preventing the abnormal ejection of the eject button which causes an operational abnormality by distorting the insertion and ejection sequence of the detachable external storage device.

  In order to automatically store the eject button, which is the object of the present invention, a structure in which the eject button is pressed twice is adopted. In such a structure, when the eject button is pushed for the second time, the eject button is automatically fully accommodated in the attachment / detachment operation device.

  In the prior art, a structure in which the removable external storage device is usually moved by one spring is adopted. However, in the present invention, at least two springs are used to strengthen the spring force, and the removable external storage device is installed. It is moved. When the eject button is pressed by a predetermined amount, the removable external storage device is ejected, and at the same time, the eject button is automatically stored in the removable operation device. The eject button needs to be pressed twice, but the removable external storage device can be ejected the second time without being completely pressed.

  In order to cope with the attachment / detachment operation mechanism having a depth restriction, a horizontal structure is adopted in the configuration described in this embodiment, in contrast to the vertical structure adopted in the conventional apparatus. By adopting the horizontal structure, the depth of the attaching / detaching operation mechanism can be shortened and the number of pins of the connector can be increased. Since it has a horizontally long structure, instead of a structure using a single slider, a structure in which two sliders are arranged at the top and bottom and connected by a pinion gear is adopted.

  A damper enclosing grease or a viscous material engaged with the rack portion of the first slider was used so that the removable external storage device was discharged to a predetermined position at a low speed during ejection. In addition, grooves at regular intervals are provided in the engaging portions 1-a-2-5 and 1-a-6-2 of the first slider and the third slider, and highly viscous grease is applied to the engaging portions. Thus, the removable external storage device was made to discharge at a low speed.

  A slider discharge mechanism incorporating a spring is further provided in the slider discharge mechanism incorporating a spring, the springs are arranged vertically, connected by a pinion, and discharged in a small space.

  FIG. 1 shows a case where the state before the detachable external storage device 2 is inserted into the detachable operation device 1 is examined from below.

  In the specification of the present application, notations indicating directions such as up and down, left and right, and front and rear are described with reference to the attached drawings, and do not necessarily indicate an actual use state of the apparatus.

  The detachable external storage device 2 includes, for example, a hard disk, an optical disk, a floppy disk, a detachable external storage device for an electronic device, and a drive device (not shown) in a flat housing 2-3. An insertion side end 2-4 of the housing 2-3 has an opening (not shown) for exposing a connector for electrical connection with the attachment / detachment operation device 1, and the housing 2-3 has the above-mentioned It has a connector for connection (not shown).

  On the other hand, a connector 1-d that is connected to a connection connector of the detachable external storage device 2 and performs communication or the like is attached to the rear portion of the detachable operation device 1. An example in which a fan 1-e for cooling the detachable external storage device 2 is installed beside the connector 1-d is shown.

  A guide groove 2-5 and a lock groove 2-1 are formed on the side of the removable external storage device 2. The detachable external storage device 2 moves in the detachable operation device 1 with its guide groove portion 2-5 engaging with the projection guide 1-b-4 of the detachable operation device 1. Further, the lock portion 1-a-24-3 (not shown) of the lock plate 1-a-24 provided in the attachment / detachment operation device 1 enters the lock groove portion, and the inserted attachment / detachment type external storage device 2 is attached to the attachment / detachment operation device. Lock to 1. In this embodiment, a connector 1-f in which a plurality of connection pins for electrically connecting the detachable operation device 1 are arranged in two rows is provided on an electronic device main body (not shown) that uses the detachable external storage device 2. ing. Also, a clamp hook 1-g for an electric cable and an attachment part 1-h for attaching the attachment / detachment operation device housing to the electronic device main body are provided at predetermined positions.

  FIG. 2 shows a state in which the removable external storage device 2 is completely inserted into the storage portion of the removable operation device 1. An eject button 1-a-14 is arranged on the front right side. By pressing the eject button 1-a-14 toward the inside of the detachable operation device 1, the detachable external storage device 2 can be ejected from the storage portion of the detachable operation device 1.

  FIG. 3 is an exploded view showing the main components of the detachable actuator 1. A guide frame right side assembly 1-a, a guide frame left side assembly 1-b, a bracket 1-c mainly housing the removable external storage device 2, and a film 1-c-2 for protecting the removable external storage device 2 are provided. It is shown in the figure. In this embodiment, the film 1-c-2 is attached to the insertion port side of the bracket.

  The guide frame right assembly 1-a has a right projection guide (not shown) to be combined with the guide groove 2-5 of the removable external storage device 2 in which the eject and lock mechanism is incorporated. The guide frame left assembly 1-b also has a left projection guide 1-b-4 corresponding to the left lock groove of the removable external storage device. The left and right guide frames 1-a and 1-b are fixed to the bracket 1-c using mounting screws 1-c-1. In this embodiment, a structure in which a film 1-c-2 for protecting the removable external storage device 2 is attached to the upper part of the removable external storage device insertion side 1-c-3 of the bracket 1-c. Have

  FIG. 4 shows components of the guide frame right side assembly 1-a. The right guide frame 1-a-1 has a guide protrusion (not shown) corresponding to the right guide groove 2-5 (see FIG. 1) of the detachable external storage device 2.

  The guide frame right assembly 1-a mainly includes an eject button 1-a-14, a slider A1-a-2 in which a slider C1-a-6 is incorporated, a slider B1-a-4, and an external device connector 1-a. -43, lock plate 1-a-24, push plate 1-a-20, cam plate 1-a-16, pinion gear 1-a-8, damper 1-a-26, stop spring 1 The operation is controlled by -a-27, substrate assembly 1-a-29, and the like.

  The slider A1-a-2 has a discharge hook 1-a-2-1 that operates in contact with the removable external storage device 2. And the rack 1-a-2-6 which operate | moves in combination with the pinion gear 1-a-8 is provided in the upper part. Further, the slider A1-a-2 incorporates an eject spring A1-a-3 that urges the slider A1-a-2 in the discharging direction.

  A slider C1-a-6 is incorporated in the slider A1-a-2. The slider C operates so as to increase the discharge movement amount of the removable external storage device 2 and to decrease the discharge load when the removable external storage device 2 is discharged. Therefore, an eject spring C1-a-7 that urges the slider C in the discharge direction is incorporated in the slider C1-a-6.

  The slider B1-a-4 is provided with a rack 1-a-4-3 for transmitting a pressing force from the eject button 1-a-14 to the pinion gear 1-a-8 when the removable external storage device is ejected. ing. The rack of the slider A1-a-2 is formed upward and the rack of the slider B1-a-4) is formed downward, and is connected via a pinion gear 1-a-8. An eject spring B1-a-5 is incorporated in the slider B1-a-4. The slider B1-a-4 is combined with the eject button 1-a-14 via the push plate 1-a-20.

  The pinion gear 1-a-8 is disposed between the rack 1-a-4-3 of the slider B and the rack 1-a-2-6 of the slider A. The pinion gear 1-a-8 transmits the movement of the slider A1-a-2 to the slider B1-a-4 when the storage device 2 is inserted, and moves the slider B1-a-4 when the storage device 2 is discharged. It is transmitted to A1-a-2. The pinion gear 1-a-8 is fixed to the right guide frame 1-a-1 with a screw 1-a-9 via a washer 1-a-10.

  The eject spring A1-a-3 is locked to the fixing hole 1-a-2-2 of the slider A1-a-2 by a spring pin 1-a-11, and the opposite side is the right guide frame 1-a-1. Are fixed by spring pins 1-a-12 that pass through the fixing holes 1-a-1-1.

  The eject spring B1-a-5 is fixed to the hook portion 1-a-4-1 of the slider B1-a-4, and the opposite side is a fixing hole portion 1-a- of the right guide frame 1-a-1. The spring pin 1-a-13 passed through 1-2 is locked.

  The eject spring C1-a-7 is locked by a parallel pin 1-a-1-14 that passes through a hole 1-a-6-1 that passes through the slider C1-a-6. -1-14 is inserted into the guide slot 1-a-2-3 portion of the slider A1-a-2 to control the linear movement. The opposite side is locked to the hook portion 1-a-2-4 of the slider A1-a-2.

  For this reason, the slider A1-a-2 and the slider C1-a-6 are always urged leftward, the slider B1-a-4 is always urged rightward, and each spring is detachable external storage device 2. It is energized to assist the discharge.

  A cam plate 1-a-16 to which a cam pin 1-a-15, which is a mechanical part for push-in / push-out, is attached by caulking is attached to the eject button 1-a-14 for discharge. The cam plate 1-a-16 is incorporated in a rotationally movable state by a camshaft 1-a-17 press-fitted into the eject button 1-a-14. Further, in order to constantly bias the cam pin 1-a-15 attached to the tip of the cam plate 1-a-16 toward the cam locus (see FIG. 24), the cam spring 1-a-18 is an eject button. It is attached between 1-a-14 and cam plate 1-a-16.

  An eject button compression spring 1-a-19 for always urging the eject button 1-a-14 forward is incorporated between the slider B1-a-4.

The push plate 1-a-20 incorporated in the right guide frame 1-a-1 applies a pushing force from the eject button 1-a-14 via the cam plate 1-a-16 to the slider B1-a during ejection. -4. That is, when the push plate 1-a-20 pushes the eject button, the cam plate 1-a-16 pushes the push plate 1-a-20 linked to the movement of the eject button, and the push plate 1-a-20 The cam pushing portion 1-a-20-3 rotates the cam formed on the lock plate lock control portion 1-a-24-2 of the lock plate 1-a-24 to release the lock on the removable external storage device 2. To do. See Supplementary Explanation FIG. 26. Also, the slider B1-a-4 is urged by the hook portion 1-a-20-1 formed on the push plate 1-a-20, and the pushing force of the eject button is transmitted to the slider B. Refer to Supplementary FIG. 22 Further, a plate compression spring 1-a-21 for always urging the push plate 1-a-20 toward the eject button 1-a-14 is incorporated in the slider B1-a-4. One side is fixed by a spring pin 1-a-22 inserted in a through hole of the slider B1-a-4.

  When the detachable external storage device 2 is inserted into the storage portion of the detachable operation device 1, the lock plate 1-a-24 enters the lock groove 2-1 of the detachable external storage device 2, thereby detachable external storage. The device 2 is locked and fixed to the attachment / detachment operation device 1, and the lock is released by moving away from the lock groove 2-1 at the time of ejection. The lock plate 1-a-24 is rotatably attached by a lock shaft 1-a-23 inserted into a through hole of the right guide frame 1-a-1.

  A lock spring 1-a-25 is provided between the right guide frame 1-a-1 and the lock plate 1-a-24 for always urging the lock plate 1-a-24 in the fixed rotation direction (ie, the locking direction). Built in.

  A damper 1-a-26 is attached to the right guide frame 1-a-1. The damper 1-a-26 engages with the rack 1-a-2-6 of the slider A 1-a-2, restricts the movement of the slider A 1-a-2, and the removable external storage device 2 operates at a low speed during ejection. Acts to drain.

  The stop spring 1-a-27 is attached to the right guide frame 1-a-1. The stop spring 1-a-27 engages with the temporary fixing groove 2-6 of the detachable external storage device 2 so that the detachable external storage device 2 is attached and detached so that the detachable external storage device 2 does not pop out when ejected. Temporarily fixed to the device 1. As shown in FIG. 13, a stop spring 1-a-27) is attached to the right guide frame 1-a-1 to be temporarily fixed when the removable external storage device is automatically ejected to a predetermined position. This is because.

  In this embodiment, the substrate assembly 1-a-29 is installed in the right guide frame 1-a-1. In this embodiment, the board assembly 1-a-29 is mounted with three switches for detecting the insertion state of the removable external storage device 2 and the mechanism state of the removable operation device 1 and an external connection connector. . The slider detection switch detects whether the detachable external storage device 2 is inserted, the lock bar detection switch detects whether the lock plate is locked, and the eject button position detection switch detects the position of the eject button.

  Further, when the removable external storage device 2 is inserted, the ground terminal 1-a-28 is attached to the rear side of the right guide frame 1-a-1 as a ground for GND.

  In addition, a link plate 1-a-30 for drawing the eject button 1-a-14 is press-fitted into the slider B1-a-4.

  FIG. 5 shows components of the guide frame left side assembly 1-b. In this embodiment, the left assembly 1-b is mainly constituted by a left guide frame 1-b-1, a stop spring 1-b-2, and a ground terminal 1-b-3.

  The left guide frame 1-b-1 has a guide projection 1-b-4 (not shown, see FIG. 3) corresponding to the left guide groove (not shown) of the removable external storage device 2. The stop spring 1-b-2 is attached to the left guide frame 1-b-1 to temporarily fix the detachable external storage device 2 so that it does not jump out when ejected. The ground terminal 1-b-3 is mounted behind the left guide frame 1-b-1 for grounding when the removable external storage device 2 is inserted.

Outline of Operation of Eject Device The outline of operation of the eject device is shown below. 6 to 12 show the operating states of the removable external storage device 2 and the removable operation device 1. (A), (b), (c) of FIGS. 6-12 is drawing shown about the same part. For example, referring to FIG. 6, FIG. 6A is a cross-sectional view taken along the line CC ′ of FIG. (B) is sectional drawing of AA 'of Fig.6 (a). FIG. 6C is a side view with the sheet metal removed.

  1) FIG. 6 shows a state where the removable external storage device 2 is ejected from the removable operation device 1. The state of each component will be described.

  1-1) The slider A1-a-2 is pulled leftward in FIG. 6 by the eject spring A1-a-3, and is located at a fixed position at the left end.

  1-2) The slider B1-a-4 is pulled in the right direction in FIG. 6 by the eject spring B1-a-5, and is located at a fixed position on the right end.

  1-3) The slider C1-a-6 incorporated in the slider A1-a-2 is pulled leftward in FIG. 6 by the eject spring C1-a-7, and is located at a fixed position at the left end.

  1-4) The eject button 1-a-14 includes a protrusion 1-a-14-2 (see also FIG. 4) of the eject button 1-a-14 and a link plate 1-a-30 (FIG. 4). Are also engaged and pulled to the right and housed in the right guide frame 1-a-1.

  The link plate (1-a-30) is fixed to the left end of the slider B1-a-4. When the slider B1-a-4 is positioned at the right end position, the link plate (1-a-30) moves the protrusion 1-a-14-2 formed on the eject button 1-a-14 to the right. The eject button 1-a-14 is accommodated in the detachable operation device 1. See FIG.

  1-5) The push plate 1-a-20 is moved to the right in FIG. 6, and the lock plate 1-a-24 is rotated by the lock control unit 1-a-20-2 of the push plate 1-a-20. Is suppressed. That is, the lock portion 1-a-24-3 of the lock plate is positioned on the lower side, and the lock by the lock portion 1-a-24-3 for the removable external storage device 2 is released.

  For example, FIG. 22 shows a coupling relationship between the push plate 1-a-20 and the slider B1-a-4. The hook portion 1-a-20-1 of the push plate 1-a-20 is inserted into the slit portion 1-a-4-2 of the slider B1-a-4.

  The lock plate 1-a-24 of the push plate 1-a-20 is prevented from rotating by the lock control unit 1-a-20-2, and the lock by the lock unit 1-a-24-3 is released. For example, as shown in FIG. A lock controller 1-a-20-2 is placed in a groove 1-a-24-4 formed in the lock plate lock 1-a-24-3.

  2) FIG. 7 shows a state in the middle of insertion after the removable external storage device 2 is inserted into the removable operation device 1. The detachable external storage device 2 is inserted while pushing the discharge hooks of the sliders A1-a-2 and C1-a-6 on the side surfaces.

  2-1) When the detachable external storage device 2 is inserted into the detachable operation device 1, the insertion tip portion 2-7 of the detachable external storage device 2 is the discharge hook 1-a-6-6 of the slider C1-a-6. 4 (see FIG. 16) is pressed, and the removable external storage device 2 and the slider C1-a-6 are moved to the right, which is the insertion direction. The slider C1-a-6 moves in the right direction in FIG. 7 together with the removable external storage device 2 while pulling the eject spring C1-a-7 by the hook portion (spring pin 1-a-14) of the slider C1-a-6. Moving.

  2-2) When the removable external storage device 2 is further inserted and the slider C1-a-6 is moved to the maximum in the right direction, the insertion tip 2-7 of the removable external storage device 2 is then moved to the slider A1-a-. The second discharge hook 1-a-2-1 (see FIG. 16) is pushed and moved further to the right, which is the insertion direction. The slider A1-a-2 moves to the right in FIG. 7 while pulling the eject spring A1-a-3 by the hook portion (spring pin 1-a-11) of the slider A1-a-2.

  2-3) The state of FIG. 7 is in the middle of insertion, and is a state immediately before the slider A1-a-2 contacts the pinion gear 1-a-8.

  3) FIG. 8 shows a state in which the removable external storage device 2 is completely inserted into the removable operation device 1. As shown in FIG. 8, the removable external storage device has a lock groove portion 2-1, and a protrusion 1-a-24-3 of the lock plate that locks the removable external storage device 2 enters this groove portion, where it is attached and detached. The external storage device is locked.

  3-1) When the detachable external storage device 2 is further inserted from the state shown in FIG. 7, the pinion gear 1-a-8 is rotated by the rack portion 1-a-2-6 of the slider A1-a-2, and the rack The slider B1-a-4 is moved to the left via 1-a-4-3. The slider B1-a-4 moves to the left in FIG. 8 while pulling the eject spring B1-a-5.

  3-2) The mating connector 1-d (see FIG. 13) in which the connector 2-a built in the removable external storage device 2 is attached to the removable operation device 1 by the insertion of the removable external storage device 2 It will be in an engaged state.

  3-3) As the slider B1-a-4 moves leftward, the push plate 1-a-20 combined with the slider B1-a-4 moves leftward in the figure. For this reason, the lock control unit 1-a-20-2 (see FIG. 22) of the push plate 1-a-20 also moves to the left. Therefore, the lock control unit 1-a-20-2 is pulled out from the groove 1-a-24-4 of the lock control unit 1-a-24-2. Therefore, the lock plate 1-a-24 can rotate (see FIG. 26) and can rotate counterclockwise. Then, the lock portion 1-a-24-3 of the lock plate 1-a-24 is engaged with the lock groove portion 2-1 of the removable external storage device 2, thereby preventing the removable external storage device 2 from being discharged.

  3-4) When the lock plate 1-a-24 rotates, the lock portion 1-a-14-1 of the eject button 1-a-14 is locked to the lock portion 1-a provided on the right guide frame 1-a-1. From the state engaged with -1-5 (see FIGS. 14 and 15), the end portion 1-a-24-1 of the lock plate urges the lock portion 1-a-14-1 of the eject button to The lock portion 1-a-14-1 is released from the combined state.

By releasing the lock, the eject button 1-a-14 moves forward, and the cam pin 1-a-15 is locked to the cam groove shape 1-a-1-4 provided in the right guide frame 1-a-1. It moves from the position to the cam lock position 1-a-50a and stops. Since the height of a is lower than e, the cam pin 1-a-15 is biased in the cam groove direction by the cam spring 1-a-18, and therefore does not return to the e position. (See Figure 24)
14 and 15 show a state immediately before the lock portion 1-a-14-1 of the eject button is released from the lock engaged with the lock portion 1-a-1-5 of the right guide frame 1-a-1. Shown in

  FIG. 14 is a view showing a state in which the lock portion 1-a-14-1 of the eject button is locked to the lock portion 1-a-1-5 of the guide of the right guide frame 1-a-1.

  The mechanism for releasing the lock will be described with reference to FIG. When the lock plate 1-a-24 rotates counterclockwise about the lock shaft 1-a-23, the end portion 1-a-24-1 of the lock plate 1-a-24 rotates upward. For this reason, the tab 1-a-14-3 provided at the tip of the lock part 1-a-14-1 of the eject button 1-a-14 is pushed upward to lift the lock part 1-a-14-1. For this reason, the locked state engaged with the lock portion 1-a-1-5 (see FIG. 14) of the right guide frame 1-a-1 is released.

  4) FIG. 9 shows step 1 in which the removable external storage device 2 is ejected.

4-1) The eject button 1-a-14 for ejecting the detachable external storage device 2 is provided with a push-in / push-out mechanism. Press about 2mm. When the eject button is pressed for the first time, the lock is released. The cam pin 1-a-15 moves from the lock portion a position to the b position of the cam groove shape 1-a-1-4 provided in the right guide frame 1-a-1. Since the height of b is lower than a, the cam pin 1-a-15 is biased in the cam groove direction by the cam spring 1-a-18, and therefore does not return to the position a. (See Figure 24)
4-2) Next, when the hand is released from the eject button 1-a-14, the eject button 1-a-14 is moved to the maximum protruding position by the eject button compression spring 1-a-19. The cam pin 1-a-15 moves from the b position of the cam groove shape 1-a-1-4 provided in the right guide frame 1-a-1 to the d position beyond the c position where the groove depth is the shallowest. Since the height of the d position is lower than c, it does not return to the c position. (See Figure 24)
The eject button 1-a-14 is formed with a button stopper projection 1-a-14-5, which is moved forward by a groove 1-a-1-16 engaged with the right guide frame 1-a-1. Controls to jump out.

  5) FIG. 10 shows step 2 in which the removable external storage device 2 is ejected.

  5-1) Next, when the eject button 1-a-14 is pushed by a certain amount, the cam plate 1-a- rotatably incorporated in the camshaft 1-a-17 press-fitted into the eject button 1-a-14. 16, the lock control unit 1-a-20-2 of the push plate 1-a-20 is moved rightward in the figure. The lock control unit 1-a-20-2 rotates the lock plate 1-a-24 in the unlocking direction (the lock unit 1-a-24-3 of the lock plate downward in FIG. 10), and is a detachable external storage. The lock is released from the lock groove 2-1 formed on the side wall of the device 2 to be unlocked.

  This will be described in detail below. FIG. 26 shows a state before unlocking. The push plate 1-a-20 is not moved, and the lock plate 1-a-24 is rotated counterclockwise about the lock shaft 1-a-23, so that the storage device 2 is locked. That is, for example, as shown in FIG. 9, the lock portion 1-a-24-3 of the lock plate 1-a-24 enters the lock groove 2-1 on the side wall of the storage device and moves the storage device 2 in the ejection direction. This corresponds to the state of FIG.

  FIG. 27 shows the unlocked state. By pushing the eject button 1-a-14 by a certain amount, the push plate 1-a-20 moves to the left. Therefore, the cam pushing portion 1-a-20-3 of the lock control portion 1-a-20-2 enters the groove portion 1-a-24-4 of the lock plate lock control portion 1-a-24-2. Then, the lock plate 1-a-24 is rotated clockwise. For this reason, the lock portion 1-a-24-3 is released from the lock groove 2-1 of the storage device and is released from the locked state. This corresponds to the state of FIG.

  As shown in FIG. 21, the lateral width of the slit portion 1-a-4-2 of the slider B1-a-4 is larger than the width of the hook portion 1-a-20-1 of the push plate 1-a-20. Since it is long, the movement of the slider B1-a-4 does not start until the lock plate 1-a-24 is completely rotated and unlocking is completed.

  5-2) When the eject button 1-a-14 is further pressed by a certain amount, the hook portion 1-a-20-1 of the push plate 1-a-20 is slit into the slider B1-a-4 as shown in FIG. Since it is inserted in the part 1-a-4-2, the slider B1-a-4 moves in the right direction (in the left direction in FIG. 21). For this reason, the pinion gear 1-a-8 rotates clockwise, and the slider A1-a-2 moves in the left direction in the figure. With the movement of the slider A1-a-2, the removable external storage device 2 is ejected leftward in the figure, and the connector 2-a built in the removable external storage device 2 is attached to the removable operation device 1. Disconnected from the mating connector 1-d.

  6) FIG. 11 shows a step (3) in which the removable external storage device 2 is ejected.

  6-1) When the connector 2-a is detached from the mating connector 1-d, the slider A1-a-2 further moves leftward in the figure by the eject spring A1-a-3, and the discharge hook 1-a-2 The removable external storage device 2 is automatically ejected by -1.

  6-2) The slider B1-a-4 is moved rightward in the drawing by the eject spring B1-a-5. The link plate 1-a-30 press-fitted and fixed to the slider B1-a-4 engages with the convex portion 1-a-14-2 of the eject button 1-a-14, and pushes the eject button 1-a-14. It is stored in the right guide frame 1-a-1.

The position of the cam pin 1-a-15 in this step moves to the e position of the cam groove shape 1-a-1-4. (See Figure 24)
The automatic storage mechanism for the eject button will be described. As shown in FIGS. 10 to 12, the link plate 1-a-30 is engaged with the left end of the slider B <b> 1-a-4. The convex portion 1-a-14-2 of the eject button 1-a-14 is combined with the slit 1-a-30-1 of the link plate 1-a-30. As the slider B1-a-4 moves in the right direction, the link plate 1-a-30 engaged with the slider B also moves in the right direction. The eject button convex portion 1-a-14-2 is combined in the slit 1-a-30-1 of the link plate. The protrusion 1-a-14-2 of the eject button is pushed by the left end 1-a-30-2 in the slit and moves to the right. In this way, the eject button is automatically stored in the apparatus. FIG. 23 shows a coupling state of the eject button 1-a-14, the convex portion 1-a-14-2 of the eject button 1-a-4, the link plate 1-a-30, and the slider B1-a-4.

  Since the sliders A1-a-2 and B1-a-4 incorporate the eject springs 1-a-3 and 1-a-5, the force to push the eject button 1-a-14 is removable even at a low load. The external storage device 2 can be discharged, and by using a combination of sliders, the external storage device 2 can be discharged with a low operation amount.

  7) FIG. 12 and FIG. 13 show a step (4) in which the removable external storage device 2 is ejected.

  7-1) Only the slider A1-a-2 is disengaged from the pinion gear 1-a-8, is urged by the eject spring A1-a-3, and further moves to the left in the figure, and the removable external storage device 2 is further automatically Move to drain.

  7-2) Further, the slider C1-a-6 built in the slider A1-a-2 moves in the left direction in the figure by the urging force of the eject spring C1-a-7. Therefore, the detachable external storage device 2 is discharged to the temporary lock position by being pressed by the slider C1-a-6 discharge hook 1-a-6-4.

  7-3) As shown in FIG. 13, the stop spring 1-a-27 attached to the right guide frame 1-a-1 and the stop attached to the left guide frame 1-b-1 at this position. The spring 1-b-2 is engaged with the temporary fixing groove 2-6 of the detachable external storage device 2 to enter the temporary lock state. FIG. 13 shows a state in which the removable external storage device 2 is temporarily locked. The temporarily-attached removable external storage device 2 can be removed by pulling out by hand.

  In this embodiment, a speed reduction means for controlling the ejection speed of the removable external storage device 2 can be provided. As shown in FIG. 6, the slider A1-a-2 is always engaged with the pinion gear of the damper 1-a-26 having a deceleration characteristic. The damper 1-a-26 decelerates the discharge speed of the removable external storage device 2. Decreasing characteristics can be increased by enclosing grease or viscous material in the damper (1-a-26).

  Further, in order to give the slider C1-a-6 deceleration characteristics, as shown in FIG. 16, the engaging portion 1-a-2-5 with the slider A1-a-2 and the corresponding slider C1-a-6 are provided. The engaging portion 1-a-6-2 can be provided with grooves at regular intervals, and a highly viscous grease can be applied to the engaging portion to add deceleration characteristics.

  FIG. 16 shows a combination relationship between the slider A and the slider b. The combination of the movement amount of the slider A1-a-2 and the movement amount of the slider C1-a-6 is the movement amount of the removable external storage device 2.

  FIG. 17 shows the positional relationship between the end portion 1-a-24-1 of the lock plate 1-a-24 and the lock portion 1-a-14-1 at the tip of the eject button 1-a-14. The end portion 1-a-24-1 rotates upward by the counterclockwise rotation of the lock plate 1-a-24, and the tab 1-a-24-3 at the tip of the eject button 1-a-14 is lifted. Thus, the lock portion 1-a-14-1 can be lifted.

  FIG. 18 shows a state in which the eject button 1-a-14 and the lock plate 1-a-24 are assembled in the right guide frame-assembly 1-a, and the lock portion 1-a-14 of the eject button 1-a-14. -1 shows a state of being locked to the lock portion 1-a-1-5 of the guide frame 1-a-1.

  FIG. 19 shows a state in which the slider C is incorporated in the slider A.

  FIG. 20 shows a state where the eject button 1-a-14, the cam plate 1-a-16, and the cam spring 1-a-18 are incorporated.

  FIG. 21 shows the positional relationship between the eject button 1-a-14, the push plate 1-a-20, and the slider B1-a-4. In particular, it shows how the push plate 1-a-20 is coupled to the slider B1-a-4. A hook portion 1-a-20-1 of a push plate 1-a-20 is movably inserted in a slit portion 1-a-4-2 provided on a side portion of the slider B.

  FIG. 22 is a diagram showing the link relationship among the eject button 1-a-14, push plate 1-a-20, slider B1-a-4, pinion gear 1-a-8, and slider A1-a-2 during ejection. is there.

  The cam pusher 1-a-20-3 opens the lock bar. Push to the left to rotate the lock bar and release the lock.

  FIG. 23 is a diagram showing an engaged state of each spring. The engagement state of each spring will be described with reference to FIG. The eject spring A1-a-3 is fixed to the fixing hole 1-a-2-2 (see FIG. 4) of the slider A1-a-2 by the spring pin 1-a-11 (see FIG. 4), and the opposite side is the right side. It is fixed by a spring pin 1-a-12 (see FIG. 4) passed through a fixing hole 1-a-1-1 (see FIG. 4) of the guide frame 1-a-1. The eject spring B1-a-5 is fixed to the hook portion 1-a-4-1 (see FIG. 4) of the slider B1-a-4, and the opposite side is the fixing hole portion 1 of the right guide frame 1-a-1. It is fixed by a spring pin 1-a-13 passed through -a-1-2. The eject spring C1-a-7 is fixed by a pin 1-a-14 (see FIG. 4) passed through the through hole 1-a-6-1 (see FIG. 4) of the slider C1-a-6, and the opposite side is It is fixed to the hook portion 1-a-2-4 (see FIG. 4) of the slider A1-a-2.

  An eject button compression spring 1-a-19 is incorporated between the eject button 1-a-14 and the slider B1-a-4. The compression spring 1-a-21 (see FIG. 4) is incorporated in the slider B1-a-4, and one side is a spring pin 1-a-22 (inserted into the through hole of the slider B1-a-4). (See FIG. 4). The lock spring 1-a-25 (see FIG. 4) is incorporated between the right guide frame 1-a-1 and the lock plate 1-a-24.

  FIG. 24 is a perspective view of the cam groove shape 1-a-1-4 of the right guide frame 1-a-1. Details of the cam groove shape 1-a-1-4 and the position of the cam pin 1-a-15 moving along the cam groove shape are shown. It is usually called heart cam. The cam pin 1-a-15 is always cam grooved by the other end portion 1-a-18-2 of the cam spring 1-a-18 whose one end 1-a-18-1 is fixed to the eject button 1-a-14. It is biased toward the bottom. For this reason, the front-end | tip part of cam pin 1-a-15 moves along the cam groove bottom part 1-a-1-6 of cam groove shape 1-a-1-4. a to d are attached to the cam plate 1-a-16 and indicate the positions of the cam pins 1-a-15 that move according to the cam groove shape and the biting groove bottom. The height of the cam groove bottom is higher in the order of c> d> e> a> b. Steps 1-a-1-7, 1-a-1-8, 1-a-1-9, 1-a-1-10 are provided between de, ea, and ab, and between bc An inclined portion 1-a-1-11 is provided.

  a indicates the position of the cam pin in a state in which the storage device 2 is inserted. b indicates the movement position of the cam pin when the eject button is pushed by hand to eject the storage device 2 (first time). Next, when the hand is released from the eject button, the eject button is urged by the spring 1-a-19 provided on the eject button, and the eject button jumps out of the attachment / detachment operation device 1. As the eject button moves, the cam pin moves from b to c along the inclined portion 1-a-1-11 and then moves to d. Since b is one step lower than a due to the stepped portion 1-a-1-9, it cannot return from b to a. “c” indicates a moving position of the cam pin 1-a-15 when the eject button 1-a-14 is popped out at the time of ejection. This is the position showing the highest height at the cam groove bottom 1-a-1-6. d indicates the movement position of the cam pin 1-a-15 when the eject button 1-a-14 is projected to the maximum. This corresponds to the state of FIG.

  The storage device 2 is ejected by pressing the eject button 1-a-14 again in the right direction (second time). The cam pin 1-a-15 moves from d to e. Since d is one step lower than c, d does not return to c. e indicates the position of the cam pin 1-a-15 in the process of ejecting the storage device 2. This corresponds to FIG. 11 and FIG.

  32A is a plan view of the cam groove shape 1-a-1-4 of the right guide frame 1-a-1 described above.

  The lower side (b) of FIG. 32 is a plan view of a general cam groove shape.

  The difference in the groove shape in the present invention is that the d position and e position of a general cam shape are on a straight line, but in the present invention, the e position is bent in front of the e position so that the e position is aligned with the lock position a position. is there. This is because the eject button 1-a-14 is automatically stored in the attachment / detachment operation device, and the eject button 1-a-14 is ejected after the stop by the locking means is released after the attachment / detachment operation device is completely inserted. It becomes the cam groove shape necessary to move in the direction.

  That is, in the process of inserting the storage device 2, the eject button 1-a-14 is housed in the detachable operation device and the cam pin 1-a-15 is stopped at the e position. Since the push plate 1-a-20 needs to move leftward together with the slider B1-a-4, in a general cam shape, the push portion 1-a-16-1 of the cam plate 1-a-16 is the push plate. The push plate 1-a-20 is prevented from moving by interfering with a receiving portion 1-a-20 (a bowl-shaped portion in FIG. 27) 1-a-20-5. With this cam groove shape, the cam plate 1-a-16 is rotated while the eject button is housed, thereby avoiding interference with the push plate 1-a-20 and allowing the push plate 1-a-20 to move. .

  As the cam pin 1-a-15 moves, the cam plate 1-a-16 rotates about the cam shaft 1-a-17 as shown in FIGS.

  FIG. 25 shows the positional relationship between the cam groove shape 1-a-1-4 and the cam pin 1-a-15. The eject button 1-a-14 and the cam plate 1-a-16 are shown lifted upward from the actual assembly position. In the actual assembly position, the tip of the cam pin 1-a-15 enters the cam groove shape 1-a-1-4 and operates in a state of being in contact with the cam groove bottom 1-a-1-6.

  26 and 27 are diagrams showing the rotation of the cam plate 1-a-16 and the coupling relationship between the push plate 1-a-20 and the lock plate 1-a-24. FIG. 26 shows a state where the storage device is mounted and locked. The lock plate 1-a-24 rotates counterclockwise about the lock shaft 1-a-23, and the lock portion 1-a-24-3 of the lock plate becomes a lock groove 2-1 (not shown, see FIG. 7). ) Shows the state of entering. The states of FIGS. 8 and 9 correspond. In FIG. 27, the push plate 1-a-20 moves to the left, and the cam pushing portion 1-a-20-3 of the lock control unit 1-a-20-2 is locked to the lock plate lock control unit 1-a-24. 2 into the groove 1-a-24-4, the lock plate 1-a-24 is rotated clockwise around the lock shaft 1-a-23, and the lock 1-a-24-3 is A state where the storage device is released from the lock groove 2-1 (not shown) of the storage device is shown. For example, this corresponds to the state of FIG.

  FIG. 27 shows a state in which the lock by the lock portion 1-a-24-3 of the lock plate is released. FIG. 28 shows the positional relationship between the slit portion 1-a-4-2 of the slider B and the hook portion 1-a-20-1 of the push plate 1-a-20. In an actual use state, as shown in FIG. 21, the hook portion 1-a-20-1 operates while being inserted into the slit portion 1-a-4-2.

  27 and 28 show a state where the push plate 1-a-20 is moved rightward by the cam plate 1-a-16 attached to the eject button when the eject button 1-a-14 is pressed. . Whether the push plate 1-a-20 is pushed by the cam plate 1-a-16 is determined by the rotation of the cam plate 1-a-16.

  After the lock is completely released, the slider is moved by the hook portion 1-a-20-1 of the push plate 1-a-20 inserted into the slit portion 1-a-4-2 of the slider B1-a-4. B is pushed leftward. The slit portion 1-a-4-2 has a length larger than the width of the hook portion 1-a-20-1 so that the slit portion 1-a-4-2 is pushed by the hook portion 1-a-20-1 after the lock is completely released. It is formed.

  29 and 30 show a coupling state between the terminal end portion 1-a-24-1 of the lock plate 1-a-24 and the lock portion 1-a-14-1 of the eject button 1-a-14. FIG. 29 is a cross-sectional view in the state of FIG. 14 or FIG. 17, for example. FIG. 29B shows a state where the lock portion 1-a-14-1 of the eject button 1-a-14 is locked to the lock portion 1-a-1-5 of the right guide frame 1-a-1. 29 (a) shows the arrangement of the lock plate 1-a-24 in this state, and the lock plate end portion 1-a-24-1 and the lock portion 1-a- of the eject button 1-a-14. 14-1 shows the positional relationship of the tabs 1-a-14-3 provided in 14-1. The lock unit 1-a-14 is provided to store the eject button 1-a-14 until the storage device is completely inserted and locked. a-14-1 is locked to prevent the eject button 1-a-14 from going out.

  FIG. 30 shows a state where the lock of the eject button 1-a-14 is released by the rotation of the lock plate 1-a-24. As shown in FIG. 30 (a), the tab 1 fixed to the lock portion 1-a-14-1 of the eject button by rotating the terminal portion 1-a-24-1 of the lock plate counterclockwise. -A-14-3 is moved upward. Therefore, as shown in FIG. 30 (b), the lock portion 1-a-14-1 formed integrally with the tab 1-a-14-3 also moves upward. Therefore, when the lock portion 1-a-14-1 is released away from the lock portion 1-a-1-5 of the right guide frame 1-a-1, the eject button 1-a-14 moves in the right direction. Is possible.

  FIG. 31 shows an embodiment of the substrate assembly 1-a-29. In this embodiment, the removable external storage device 2 detection switch 1-a-40, the lock bar detection switch 1-a-41, the eject button position detection switch 1-a-42, and the external device connection connector 1-a-43. Is installed. Using these switches, the insertion / removal type external storage device 2 is inserted, the eject button 1-a-14 is moved, the operation state of the attachment / detachment operation device 1 (for example, whether the lock is released, whether there is a hard disk, etc.) , Whether the hard disk or the like is completely inserted, etc.). The external device connector 1-a-43 can be used for electrical connection with an external device using the removable external storage device 2.

  The sliders A, B, and C are biased in the discharge direction of the storage device by an eject spring A1-a-3, an eject spring B1-a-5, and an eject spring C1-a-7, respectively. Therefore, the storage device 2 can be taken out from the attachment / detachment operation device 1 with a low load by the assistance of these springs.

  Although the principle of the present invention has been described with reference to specific embodiments, it is clear that the above description is merely an example and does not limit the technical scope of the present invention. A person skilled in the art can freely change the contents described in the above embodiments within the scope of the present invention. Further, modifications and changes belonging to the equivalent scope of the claims are within the scope of the present invention.

It is a perspective view which shows the state before a detachable external memory | storage device is inserted in a detachable actuator in this invention. It is a perspective view which shows the state in which the removable external storage device was completely inserted in the removable operating device in the present invention. It is a component exploded view which shows the main components of the attachment / detachment operation device in the present invention. It is a figure which shows the component of the guide frame right side assembly in this invention. It is a figure which shows the component of the guide frame left side assembly in this invention. It is sectional drawing shown about the state from which the detachable external storage device is discharged | emitted from the detachable actuator in this invention. It is sectional drawing which shows the state in the middle of insertion of a detachable external memory | storage device in this invention in a detachable actuator. It is sectional drawing which shows a state until a detachable external memory | storage device is completely inserted in a detachable actuator in this invention. It is a figure which shows the process 1 by which a detachable external memory | storage device is ejected from a detachable actuator in this invention. It is sectional drawing which shows the process 2 by which a detachable external storage device is ejected from a detachable actuator in this invention. It is sectional drawing which shows the process 3 by which a detachable external memory | storage device is ejected from a detachable actuator in this invention. It is sectional drawing which shows the process 4 by which a detachable external storage device is ejected from a detachable actuator in this invention. It is a figure which shows the cross section of the state temporarily locked in the process 4 in which the detachable external storage device is ejected from the detachable actuator in the present invention. It is sectional drawing which shows the state in which the lock part of the eject button was latched by the lock part of the guide of the right side guide frame in this invention. It is a perspective view which shows the state in which the lock part of the eject button was latched by the lock part of the guide of the right side guide frame in this invention. It is a figure which shows the combination relationship of the slider A and the slider C in this invention. It is a figure which shows the positional relationship of the termination | terminus part of the lock plate in this invention, and the lock part of the front-end | tip of an eject button. It is a perspective view which shows the state in which the eject button and lock plate in this invention were integrated in the right side guide frame assembly. It is a figure which shows the state in which the slider C was integrated in the slider A in this invention. It is a figure which shows the state in which the eject button, cam plate, and cam spring in this invention were integrated. It is a figure which shows the combined state of the slider B in this invention, a push plate, and an eject button. It is a figure which shows the link relationship of the eject button, push plate, slider B, pinion gear, and slider A in this invention. It is a figure which shows the connection state of the eject button in this invention, the convex part of an eject button, a link plate, and the slider. It is a perspective view of the cam groove shape of the right guide frame in the present invention. It is a figure which shows the positional relationship of the cam groove shape and cam pin in this invention. It is a figure which shows the coupling | bonding relationship of the cam plate in this invention, a push plate, and a lock plate. It is a figure which shows the coupling | bonding relationship of the cam plate in this invention, a push plate, and a lock plate. It is a figure which shows the positional relationship of the slit part of the slider B in this invention, and the hook part of a push plate. It is a figure which shows the combined state of the termination | terminus part of the lock plate in this invention, and the lock part of an eject button. It is a figure which shows the combined state of the termination | terminus part of the lock plate in this invention, and the lock part of an eject button. It is a figure which shows the Example of the board | substrate assembly in this invention. The upper side (a) is a plan view of the cam groove shape 1-a-1-4 of the right guide frame 1-a-1 in the present invention. The lower side (b) is a plan view of a general cam groove shape.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Detachable actuator, 2 ... Detachable external storage device, 1-a ... Guide frame right side-assembly, 1-a-1 ... Right guide frame, 1-a-1-1 ... Fixing hole, 1-a- 1-2 ... Fixing hole part, 1-a-1-3 ... Boss part, 1-a-1-4 ... Cam groove shape, 1-a-1-5 ... Lock part, 1-a-6 ... Cam groove Bottom, 1-a-1-7 ... Step, 1-a-1-8 ... Step, 1-a-1-9 ... Step, 1-a-1-10 ... Step, 1-a- 1-11 ... Inclined part, 1-a-1-14 ... Parallel pin, 1-a-1-16 ... Groove part, 1-a-2 ... Slider A, 1-a-2-1 ... Discharge hook, 1- a-2-3 ... guide slot, 1-a-2-4 ... hook part, 1-a-2-6 ... rack, 1-a-2-5 ... engagement part, 1- 2-2-2: fixing hole, 1-a-3 ... eject spring A, 1-a-4 ... slider B, 1-a-4-1 ... hook part, 1-a-4-2 ... slit part, 1 -A-4-3 ... rack, 1-a-5 ... eject spring B, 1-a-6 ... slider C, 1-a-6-1 ... through hole, 1-a-6-2 ... engagement portion , 1-a-6-4 ... discharge hook, 1-a-5 ... eject spring B, 1-a-7 ... eject spring C, 1-a-8 ... pinion gear, 1-a-9 ... screw, 1 -A-10 ... washer, 1-a-11 ... spring pin 1, 1-a-12 ... spring pin 2, 1-a-13 ... spring pin 3, 1-a-14 ... eject button, 1-a- 14-1 ... Lock part, 1-a-14- 2 ... Projection, 1-a-14-3 ... Tab, 1-a-14-5 ... Projection, 1-a-15 ... Cam pin, 1-a-16 ... Cam plate, 1-a-16-1 ... Push portion of the cam plate, 1-a-17 ... Cam shaft, 1-a-18 ... Cam spring, 1-a-18-1 ... One end of the cam spring, 1-a-18-2 ... The other end of the cam spring Part, 1-a-19 ... eject button compression spring, 1-a-20 ... push plate, 1-a-20-1 ... hook part, 1-a-20-2 ... lock control part, 1-a-20 -3 ... Cam pushing part, 1-a-20-5 ... Receiving part, 1-a-21 ... Plate compression spring, 1-a-22 ... Spring pin, 1-a-23 ... Lock shaft, 1-a- 24 ... lock plate, 1-a-24-1 ... Terminating part, 1-a-24-2 ... Lock plate lock control part, 1-a-24-3 ... Lock plate lock part, 1-a-24-4 ... Groove part, 1- a-25 ... lock spring, 1-a-26 ... damper, 1-a-27 ... stop spring, 1-a-28 ... ground terminal, 1-a-29 ... substrate assembly, 1-a-30 ... link plate , 1-a-30-1 ... slit, 1-a-30-2 ... right end, 1-a-40 ... slider detection switch, 1-a-41 ... lock bar detection switch, 1-a-42 ... eject Button position detection switch, 1-a-50 ... Cam lock position, 1-b ... Guide frame left side-Assembly, 1-b-1 ... Left guide frame, 1-b-2 ... Stop Spring, 1-b-3 ... GND terminal, 1-b-4 ... Projection guide, 1-c ... Bracket, 1-c-1 ... Mounting screw, 1-c-2 ... Film, 1-c-3 ... Insertion Side, 1-e ... Cooling fan, 1-f ... Connector, 1-g ... Cable clamp hook, 1-h ... Housing mounting component, 2 ... Storage device, 2-1 ... Lock groove, 2-a ... Mating connector, 2-3 ... housing, 2-4 ... insertion side end, 2-5 ... guide groove, 2-6 ... temporarily fixing groove, 2-7 ... insertion tip

Claims (4)

A detachable actuator used for a detachable external storage device,
A storage unit in which the removable external storage device is stored;
Means for locking and releasing the detachable operation device with respect to the detachable external storage device when the detachable external storage device is inserted; and from the storage section of the detachable external storage device As a discharge mechanism, it has a push-in / push-out mechanism with an eject button,
When the detachable external storage device is ejected from the storage unit by pressing the eject button, the detachable external storage device is ejected by pressing the eject button a predetermined amount, and at the same time, the eject button is moved into the detachable operation device. A detachable operation device characterized in that it has a mechanism that is automatically stored. The locking means for preventing the eject button from moving in the ejecting direction until the removable external storage device is inserted and locked at a predetermined position in the removable operating device. The attachment / detachment operation device according to 1. Further, it has means for releasing the locking by the locking means, and the releasing means releases the stop by the locking means after the detachable external storage device is completely inserted, and the eject button is in the ejection direction. 2. The attachment / detachment operation device according to claim 1, wherein the attachment / detachment operation device can be moved. The eject button is automatically stored in the attachment / detachment operation device, and the stop by the locking means is released after the attachment / detachment operation device is completely inserted, and the ejection button can move in the discharge direction. 2. The attachment / detachment operation device according to claim 1, wherein a cam groove shape for the push-in / push-out mechanism is formed.

Images