JP3606945B2 - Card-type media removal prevention mechanism - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a storage unit for a card-like medium in a read / write device such as a personal computer, particularly an IC card (hereinafter simply referred to as a card), and more specifically to a mechanism for removing a card from the storage unit.
[0002]
[Prior art]
Conventionally, card insertion and removal in a personal computer or the like is generally performed manually, and an operator can insert and remove the card as needed, and also prevents this from happening especially in case of unexpected withdrawal. There is no means to do this.
[0003]
[Problems to be solved by the invention]
However, such a conventional manual card attaching / detaching mechanism is vulnerable to theft, and in particular, the extraction operation can be performed even while the signal in / from the card memory is being put in / out. is there. Therefore, it is preferable to provide a device that cannot be easily pulled out manually. An object of the present invention is to provide a mechanism for electrically performing a card ejecting operation and an electrically protecting operation for disabling removal.
[0004]
[Means for Solving the Problems]
In order to achieve the above object, the configuration of the present invention includes a card storage section, and includes a discharge mechanism that allows the card inserted and mounted in the storage section by manual operation to be pulled out by electric operation. In the read / write device for a card, a protect member that can be opened and closed in conjunction with the ejection mechanism is provided in the vicinity of the opening of the storage portion for inserting and removing the card, and the card can be freely inserted and removed at the open position. In the closed position, the card is prevented from being discharged.
[0006]
the above The discharge mechanism includes a holder having a protrusion that engages with the insertion-side end surface of the card, an extrusion member that operates in conjunction with the holder, and a protrusion that engages only with the extrusion member in the extrusion direction. And electrically driven A shift plate having a rack meshing with the pinion and driven linearly may be configured, and the protection member may be engaged with and controlled by a cam groove provided in the shift plate.
[0007]
Further, the ejecting mechanism engages only in a pushing direction with a holder provided with a projecting portion that engages with the insertion side end surface of the card, and a projection that is pivotally supported by the frame of the storage portion and stands on the holder. , Electrically driven A shift plate that is swung by a sector rack that meshes with the pinion may be configured, and the protection member may be engaged with and controlled by a cam groove provided in the shift plate.
[0008]
In addition, the ejecting mechanism includes a projecting portion that engages with the insertion side end surface of the card, and includes an extruding member pivotally supported by the frame of the storage unit, and a driving projection erected on the extruding member and only in the ejecting direction. Engage, Electrically driven A shift plate that is swung by a sector rack that meshes with the pinion may be configured, and the protection member may be engaged with and controlled by a cam groove provided in the shift plate.
[0009]
The protect member is preferably provided on both sides of the card. Further, switch means for detecting completion of the card mounting, switch means for detecting that the protection means is in the closed position, switch means for detecting completion of the card ejection, and insertion / removal of the card And a switch means for detecting that.
[0010]
[Action]
In the present invention, the card is mounted in the storage unit by manual operation and achieves electrical connection via the connector terminal. The manual operation mechanism part and the electric drive mechanism part are engaged only when the electric drive mechanism part operates in the pushing direction. Therefore, when the electric drive mechanism is not functioning, the card is manually inserted and removed at any time. can do.
[0011]
On the other hand, the protection means suppresses card ejection in the closed position, and the protection means can be opened and closed only electrically. Therefore, once the protect means is closed, the card cannot be removed manually. The card discharge after the protection means is closed can be automatically performed by a series of electrical sequences from the protection means release to the card discharge based on the switch means for detecting each stage of operation.
[0012]
FIG. 11 is a flowchart showing the operation of each switch means. Step 1 is an initial state in which a card is not inserted, a switch (S1) for detecting completion of card insertion, a switch (S2) for detecting closing of the protection means, a switch (S3) for detecting completion of card ejection, and a card All of the switches (S4) that detect that can be inserted and removed are in an inoperative state.
[0013]
In step 2, the card is loaded, S1 is activated, and S2, S3 and S4 remain inactive. In step 3, a signal for closing the protection means is sent from the operation panel, and when the motor is rotated forward, S4 enters an operating state and participates in the motor circuit. S1 maintains the operating state, but S2 and S3 remain inactive. In step 4, when the closing of the protection means is completed, S2 is operated, and the rotation of the motor is stopped. At this time, S1 and S4 continue operating, and S3 remains inactive.
[0014]
In step 5, a signal for discharging the card is sent from the operation panel. The motor is reversed and a jumper circuit setting that ignores the operation of S4 is made. After the motor reverse rotation, S2 becomes inoperative after a time lag of the mechanical transition time. S1 remains active and S3 remains inactive. S4 is inoperative for a period of time, but since the jumper circuit is set, this inactivity is electrically ignored.
[0015]
When card ejection is completed in step 6 and S3 is activated, the motor is switched from reverse rotation to forward rotation, and the jumper circuit in S4 is eliminated. S1 and S3 become inoperative after a time lag of the mechanical transition time. S2 is inactive and S4 is in operation and maintains the motor circuit. If S4 is deactivated in step 7, the motor stops and returns to the initial state of step 1. The symbols ON and OFF shown in the figure indicate mechanical operation and non-operation, and do not indicate connection / disconnection of the electric circuit.
[0016]
【Example】
Embodiments of a card-like medium sampling prevention mechanism according to the present invention will be described below with reference to the drawings. 1 to 3 show the main part of a first embodiment of the card-like medium removal preventing mechanism according to the present invention. FIG. 1 shows a state in which the card 10 is manually inserted into the connector 11 and the connection of the electrical contacts is completed. A holder 12 for receiving the card 10 slides along a guide 13 provided in the card storage unit. Reference numeral 14 denotes a protruding portion which is erected by bending the end of the holder so as to protrude into the holder 12 and engage with the insertion side edge 15 of the card 10.
[0017]
Reference numeral 16 denotes an operating shaft fixed on one side of the holder 12, which is slidably fitted in a long hole 20 provided in one arm 19 of the pushing member 18. The pusher member 18 is rotatable around the support shaft 21, and an operating arm 22 extends on the opposite side of the arm 19. A drive pin 23 is engaged with the operating arm 22 and is erected on the shift plate 24. Reference numeral 25 denotes a linear guide groove formed in the shift plate 24, and the fixing pin 26 is fitted therein, and the shift plate 24 is linearly moved in cooperation with the guides 27 and 28. Reference numeral 29 denotes a linear rack formed on one side of the shift plate 24 and meshes with the pinion 30. The pinion 30 is driven by a motor 31 via a suitable gear train 32.
[0018]
Reference numeral 33 denotes a crank-shaped cam groove which guides an operating pin 35 erected on a main drive protect arm 34 constituting a protect member. The main protection arm 34 is rotatable around the support shaft 36 and is swung by the position of the operating pin 35 in the cam groove 33. When the operating pin 35 is positioned in the inner cam groove 37, the card 10 Is open, and when located in the outer cam groove 38, the claw portion 39 of the main protection arm 34 engages the rear edge shoulder 40 of the card 10 to prevent the card 10 from being removed. (See FIG. 2).
[0019]
Reference numeral 41 denotes a switch (S1). When the actuator 42 is pressed by the operating arm 44 of the L-shaped cam 43, a card 10 mounting completion signal is transmitted. The L-shaped cam 43 is urged clockwise in the drawing by a torsion coil spring (not shown), and the operating arm 44 is always kept at a position away from the actuator 42. When the operating arm 22 of the pushing member pushes the action pin 46 erected on the operating arm 45 of the L-shaped cam 43, the operating arm 44 is rotated to operate the actuator 42.
[0020]
A switch 48 (S2) detects that the protect arm 34 is functioning when the actuator 50 is pushed by the stepped portion 49 of the shift plate 24. Reference numeral 51 denotes a switch (S3), which sends out a card 10 discharge completion signal when the actuator 53 is pushed against the front edge 52 of the shift plate 24. 54 is a switch (S4), and when the actuator 57 is pressed against the operating arm 56 of the open leg L-shaped cam 55, a signal is sent to indicate that the holder 12 and the pusher member 18 interlocked therewith are at the insertion standby position. To do. The open leg L-shaped cam 55 is urged clockwise in the figure by a torsion coil spring (not shown), and the operating arm 56 is always in a position to press the actuator 57. When the operating projection 58 of the shift plate pushes the action pin 60 erected on the operating arm 59, the operating arm 56 is rotated and the actuator 57 is operated.
[0021]
Next, the operation of the card-like medium extraction preventing mechanism according to this embodiment will be described. In the initial state where the card 10 is not inserted, the operating arm 22 of the pushing member is located at a position sufficiently separated from the action pin 46 of the L-shaped cam. Further, the operating projection 58 of the shift plate 24 is engaged with the action pin 60, the open leg L-shaped cam 55 is rotated to the open side of the actuator 57, and a standby signal is sent from the switch (S4) 54 and the motor. 31 is maintained in a stopped state. In addition, the operating pin 35 of the pect arm 34 is guided into the inner cam groove 37 to hold the claw portion 39 in the open position. The holder 12 and the push-out member 18 interlocking with the holder 12 are movable within a predetermined range except that the holder 12 and the pushing member 18 are constrained by friction between the holder 12 and the guide 13.
[0022]
The card 10 is inserted into the holder 12 and pushed into the connector 11 to complete the connection of the electrical contacts. The holder 12 is moved together with the card 10 with the protrusion 14 engaging the insertion edge 15 of the card. At this time, the operating shaft 16 of the holder rotates the pusher member 18 and pushes the action pin 46 of the L-shaped cam to operate the switch (S1) 41 to detect the completion of insertion. At this time, the holder 12 is restrained only by friction between the guide 13 on the side of the holder and the contact pin 61 (see FIG. 3) of the connector inserted into the connection pin hole of the holder 12, so that the card 10 is inserted and removed. Can be done freely.
[0023]
A protect signal is sent from an operation panel (not shown), the contact of the switch (S4) 54 is short-circuited, and the motor 31 is driven. The driving force of the motor 31 is transmitted from the pinion 30 to the rack 29 via the gear train 32, and the shift plate 24 is moved in the direction of arrow P in the figure. First, the operating pin 35 of the protect arm is guided to the outer cam groove 38, and the claw portion 39 rotates to the closed position. At the position shown in FIG. 2, the step portion 49 of the shift plate pushes the actuator 50 to actuate the switch (S2) 48, and sends a signal to detect that the protect arm 34 has functioned to stop the motor 31. In this state, the claw portion 39 of the protect arm 34 is engaged with the rear edge shoulder 40 of the card, so that the card 10 cannot be removed.
[0024]
As a result, the card 10 is extracted electrically, and is achieved by sending a discharge signal from an operation panel (not shown) or by executing a programmed command. That is, the motor 31 is driven in the reverse direction to move the shift plate 24 in the direction of arrow R in the figure. At this time, a jumper circuit is set for the switch (S4) 54. The actuating pin 35 of the protect arm 34 is guided to the inner cam groove 37, and the claw portion 39 is disengaged from the rear edge shoulder 40 of the card and rotates out of the path of the card 10.
[0025]
The shift plate 24 continues as it is, and the drive pin 23 pushes the operating arm 22 of the pushing member to open the switch (S1) 41, and the operating shaft 16 that engages with the long hole 20 is interlocked with the holder 12. Slide toward the discharge direction. In the middle of this movement, the operating projection 58 of the shift plate temporarily pushes the operating pin 60 and the operating arm 56 rotates to operate the switch (S4) 54. By setting the jumper circuit as described above, This operation is electrically ignored and the switch (S4) 54 has no motor stop action. As the holder 12 moves, the protruding portion 14 engages with the insertion edge 15 of the card, and the card 10 is removed from the contact pin 61 of the connector 11 and discharged to a position where it can be easily taken out from the storage portion by manual operation.
[0026]
In the position shown in FIG. 3, the front edge 52 of the shift plate 24 pushes the actuator 53 to operate the switch (S3) 51. The switch (S3) 51 releases the jumper circuit for the switch (S4) 54, and simultaneously reverses the motor 31 to move the shift plate 24 in the direction of arrow P again. The operating projection 58 of the shift plate 24 pushes the operating pin 60 erected on the operating arm 59, and the operating arm 56 of the open leg L-shaped cam 55 rotates to the opening side of the actuator 57, and the switch (S4) 54 The standby signal is sent out and the motor 31 is stopped. At this time, the drive pin 23 of the shift plate 24 is positioned at a standby position where it does not interfere with the rotation of the pushing member 18 at all. The drive pin 23a, the open leg L-shaped cam 55a, the operating projection 58a, and the cam groove 33a in the standby position are shown by a two-dot chain line in FIG.
[0027]
In this embodiment, a follower protect arm 62 is provided on the side facing the main drive protect arm 34, and the relay is guided by a linear groove 63 provided in a device frame (not shown) using the operating pin 35 of the main drive protect arm 34 as a support shaft. The links 65 and 66 connected via the pin 64 cause the same movement as that of the main protection arm 34. At this time, the driven protect arm 62 swings around the support shaft 68 in conjunction with the main drive protect arm 35, and the claw portion 69 functions in the same manner as the claw portion 39 of the main drive protect arm. However, the installation of the follow protect arm 62 depends on the problem of visual emphasis on alertness or aesthetics, and the main protect arm 34 is sufficient as the protect function.
[0028]
Further, in this embodiment, a card discharge mechanism by manual operation is provided so that the card 10 can be removed in an unexpected situation where the electric function is lost due to a power supply trouble such as battery consumption or a circuit failure. That is, the rotating shaft 70 of the pinion 30 is erected on an arm 73 that can be rotated coaxially with the rotating shaft 72 of the gear 71, and the pin 74 erected on the tip of the arm 73 is swung to thereby The engagement of the rack 29 can be released. A torsion coil spring 75 biases the arm 73 in a direction to return the pinion 30 and the rack 29 to the meshing state.
[0029]
Usually, since the pin 74 is locked at a predetermined position by the hook 76, the engagement between the pinion 30 and the rack 29 is normally maintained, and the driving force is transmitted without any trouble. The lever 77 is linearly guided so as to be slidable in the direction of the arrow K, and is biased in the direction opposite to the direction of the arrow K by the return tension coil spring 78. By manually moving the lever 77 in the direction of arrow K against the biasing force of the coil spring 78, the hook 76 is unlocked, and the pin 74 moves to the surface 80 along the slope 79. By this movement of the pin 74, the engagement between the pinion 30 and the rack 29 is released, and the shift plate 24 is not restrained.
[0030]
Since the step portion 81 provided on the lever abuts against the step portion 49 of the shift plate by further pushing the lever 77 and pushes the shift plate 24, the drive pin 23 engages with the operating arm 22 and the push member 18 is moved. The card 10 can be moved together with the holder 12 by the operating shaft 16 in the ejection direction. However, it is considered that only a full-time person can access the lever 77 by a mechanism (not shown).
[0031]
4 to 6 show the main part of a second embodiment of the card-like medium removal preventing mechanism according to the present invention. FIG. 4 shows a state where the card 210 is manually inserted into the connector 211 and the connection of the electrical contacts is completed. A holder 212 for receiving the card 210 slides along a guide 213 provided in the card storage unit. Reference numeral 214 denotes a projecting portion that is erected by bending the end of the holder so as to project into the holder 212 and engage with the insertion side edge 215 of the card 210.
[0032]
Reference numeral 216 denotes an operating shaft fixed on one side of the holder 212, which protrudes into a window 219 provided on the pushing member 218 and can be engaged with one side 220 of the window. The pushing member 218 is rotatable around the support shaft 212. 229 is a fan-shaped rack formed on an arcuate peripheral edge facing the support shaft 221 and meshes with the pinion 230. The pinion 230 is driven by a motor 231 via an appropriate gear train 232, and the pushing member 218 rotates according to the movement of the pinion 230.
[0033]
Reference numerals 223a and 233b denote crank-shaped cam grooves that guide the operating pins 235a and 235b provided upright on the protect arms 234a and 234b constituting the protect member, respectively. The protect arms 234a and 234b are rotatable around the support shafts 236a and 236b, respectively, and are swung by the positions of the operation pins 235a and 235b in the cam grooves 233a and 233b, so that the operation pins 235a and 235b When positioned in the outer cam grooves 238a and 238b, the claw portions 239a and 239b of the protect arms 234a and 234b are positioned on the card 210 when the card 210 is positioned in the outer cam grooves 238a and 238b. Engage with the trailing edge shoulder 240 to prevent removal of the card 210.
[0034]
Reference numeral 241 denotes a switch (S1). When the actuator 242 is pressed by the operating arm 244 of the lever 243, a mounting completion signal for the card 210 is transmitted. When the operating shaft 216 is inserted into a notch 245 provided on the opposite end of the operating arm 234, the lever 243 is interlocked with the movement of the holder 212, and the operating arm is moved to the mounting completion position together with the card 210. 244 operates the actuator 242.
[0035]
Reference numeral 248 denotes a switch (S2). One of the side edges 249 of the pushing member 218 engages with the operating arm 247 of the open leg L-shaped cam 225 to rotate the operating arm 246 and push the actuator 250. It is detected that the protect arms 234a and 234b are functioning. The open leg L-shaped cam 225 is always urged counterclockwise by a torsion coil spring (not shown), and the operating arm 246 is held at a position separated from the actuator 250.
[0036]
Reference numeral 251 denotes a switch (S3), which sends out a card 210 ejection completion signal when the actuator 253 is pushed by the other side 252 of the pushing member 218. Reference numeral 254 denotes a switch (S4) which, when the actuator 257 is released from the operating arm 256 of the open leg L-shaped cam 255, sends a signal indicating that the holder 212 and the pushing member 218 interlocked therewith are at the insertion standby position. To do. The open leg L-shaped cam 255 is urged clockwise in the figure by a torsion coil spring (not shown), and the operating arm 256 is always in a position to press the actuator 257. When the operating pin 258 erected on the pushing member pushes the operating arm 259, the operating arm 256 rotates to release the actuator 257 (see FIG. 4).
[0037]
Next, the operation of the card-like medium extraction preventing mechanism according to this embodiment will be described. In an initial state in which the card 210 is not inserted, the holder 212 is positioned near the card insertion side of the storage unit, the operating shaft 216 is positioned near the opposing side 222 of the engaging side 220 of the window 219, and the lever 243 The actuating arm 244 is held at a position sufficiently separated from the actuator 242. Further, the pusher member 218 engages the operating arm 259 with the operating pin 258, rotates the open leg L-shaped cam 255 to the release side of the actuator 257, sends a standby signal from the switch (S 4) 254, and sends a motor. 231 is kept stopped. Further, the actuating pins 235a and 235b of the protect arm are guided into the inner cam grooves 237a and 237b and hold the claw portions 239a and 239b in the release position. The holder 212 is movable within the range of the window 219 except that it is restrained by friction with the guide 213.
[0038]
The card 210 is inserted into the holder 212 and pushed into the connector 211 to complete the connection of the electrical contacts. The holder 212 is moved together with the card 210 with the protrusion 214 engaging the insertion edge 215 of the card. At this time, the operating shaft 216 of the holder 212 moves to a position in contact with the engagement side 220 of the window 219 of the pushing member 218, and the operating arm 244 of the lever 243 pushes the actuator 242 to operate the switch (S1) 241. Detect insertion completion. At this point, the holder 212 is restrained only by the sliding frictional force between the guide 213 on the side of the holder and the contact pin 261 (see FIG. 6) of the connector inserted into the connection pin hole of the card 210. The card 210 can be inserted / removed freely by the forcing force.
[0039]
By sending a protect signal from an operation panel (not shown) or by a separate program, the contact of the switch (S4) 254 is short-circuited to drive the motor 231. The driving force of the motor 231 is transmitted from the pinion 230 to the rack 229 via the gear train 232, and the pushing member 218 is moved in the direction of arrow P2 in the drawing. First, the operation pins 235a and 235b of the protect arms 234a and 234b are guided to the outer cam grooves 238a and 238b, respectively, and the claw portions 239a and 239b rotate to the closed position.
[0040]
At the position shown in FIG. 5, the side 249 of the pushing member engages with the operating arm 247 of the open leg L-shaped cam 225 to rotate the operating arm 246 and push the actuator 250 to operate the switch (S2) 248. Then, the motor 231 is stopped by sending a signal for detecting that the protect arms 234a and 234b function. In this state, the claw portions 239a and 239b of both protect arms are engaged with the rear edge shoulder 240 of the card, so that the card 210 cannot be removed.
[0041]
As a result, the card 210 is extracted electrically, and is achieved by sending a discharge signal from an operation panel (not shown) or by executing a programmed command. That is, the motor 231 is driven in the reverse direction to rotate the pushing member 218 in the direction of the arrow R2 in the figure. At this time, a jumper circuit is set for the switch (S4) 254. The actuating pins 235a and 235b of the protect arm are guided to the inner cam grooves 237a and 237b, respectively, and the claw portions 239a and 239b are disengaged from the rear edge shoulder portion 240 of the card to rotate out of the path of the card 210. Move.
[0042]
The pushing member 218 continues to rotate, and the engagement side 220 of the window pushes the operating shaft 216 of the holder to slide the holder 212 in the discharging direction, and the lever 243 engaged by the notch 245 is engaged. In conjunction with this, the switch (S1) 241 is opened. In the middle of this movement, the operating pin 258 of the pushing member is engaged with the operating arm 259 and the switch (S4) 254 is operated. However, this operation is electrically ignored due to the setting of the jumper circuit as described above. (S4) 254 has no motor stop action. By the movement of the holder 212, the protrusion 214 of the holder engages with the insertion edge 215 of the card, and the card 210 is pulled out from the contact pin 261 of the connector 211 and discharged to a position where it can be easily taken out from the storage portion by manual operation.
[0043]
At the position shown in FIG. 6, the flange 252 of the pushing member pushes the actuator 253 to operate the switch (S3) 251. The switch (S3) 251 releases the jumper circuit for the switch (S4) 254 and simultaneously reverses the motor 231 to rotate the pushing member 218 again in the arrow P2 direction. The operating pin 258 of the push-out member engages with the operating arm 259, the operating arm 256 of the open leg L-shaped cam 255 rotates to the actuator 257 open side, and a standby signal is sent from the switch (S4) 254 and the motor 231 is stopped. At this time, the pushing member 218 is rotated and maintained to a standby state position (see FIG. 4) where the engagement side 220 of the window 219 does not interfere with the movement of the operating shaft 216 at all.
[0044]
In this embodiment, the number of parts is reduced by providing the push member 218 with the functions of both the push member 18 and the shift plate 24 of the first embodiment. Furthermore, two cam grooves 233a and 233b are provided in the pushing member 218 so that the two protect arms can be directly driven simultaneously. However, for the same reason as described in the first embodiment, there is functionally one protect arm. Obviously, that's fine.
[0045]
In the present embodiment, a card discharge mechanism by manual operation is provided so that the card 210 can be removed in an unexpected situation similar to the first embodiment. That is, the rotating shaft 270 of the pinion 230 is erected on an arm 273 that can rotate coaxially with the rotating shaft 272 of the gear 271, and the meshing of the pinion 230 and the rack 229 is released by swinging the rotating shaft 270. be able to. A torsion coil spring 275 urges the arm 273 in a direction to return the pinion 230 and the rack 229 to the meshing state.
[0046]
Normally, the rotating shaft 270 is locked at a predetermined position by the hook 276, so that the engagement between the pinion 230 and the rack 229 is maintained normally, and the driving force is transmitted without any problem. The lever 277 is linearly guided so as to be slidable in the direction of the arrow K2, and is biased in the direction opposite to the direction of the arrow K2 by the return tension coil spring 278. For example, by holding the small hole 282 provided in the lever 277 with a special tool (not shown) and manually moving the lever 277 in the direction of the arrow K against the biasing force of the coil spring 278, the hook 276 is unlocked, The rotation shaft 270 moves along the slope 279 to the surface 280. By this movement of the rotary shaft 272, the pinion 230 and the rack 229 are disengaged, and the pushing member 218 is not restrained.
[0047]
When the lever 277 is further pushed, the pin 281 erected on the lever 277 engages with the first link 283 and rotates around the fixed shaft 284, and the first link 283 can rotate between the pushing member 218. The pushing member 218 can be rotated via the second link 285 connected to the card, and the operating shaft 216 can be pushed by the engagement side 220 to move the card 210 together with the holder 212 in the discharging direction. However, it is considered that only a full-time person can access the lever 277 by a mechanism (not shown).
[0048]
Next, a third embodiment of the card-like medium sampling prevention mechanism according to the present invention will be described with reference to FIGS. The illustration of the electric drive system is only shown schematically in FIG. 7 in order to avoid complication, and a side view taken along line XX in FIG. 7 is enlarged and shown in FIG. FIG. 8 schematically shows an emergency manual discharge mechanism. FIG. 7 shows a state where the card 310 is manually inserted into the connector 311 and the connection of the electrical contacts is completed. Reference numeral 312 denotes an extruding member that is pivotally supported by a fixed shaft 317 and is rotatable within a predetermined range. The projecting portion 314 that engages with the card 310 engages with the insertion side edge 315 of the card 310. The end is bent and set up.
[0049]
Reference numeral 316 denotes an operating shaft fixed to one end of the pushing member 312. The operating shaft 316 protrudes into a window 319 provided in the shift plate 324 and can be engaged with one side 320 of the window. The shift plate 324 is rotatable around the support shaft 321. Reference numeral 329 denotes a fan-shaped rack formed on an arcuate periphery facing the support shaft 321, and meshes with the pinion 330. The pinion 330 is driven by a motor 331 via an appropriate gear train 332, and the shift plate 324 rotates according to the movement of the pinion 330.
[0050]
Reference numeral 333 denotes a crank-shaped cam groove which guides an operating pin 335 provided upright on a protect arm 334 constituting a protect member. The protect arm 334 is rotatable around the support shaft 336 and is swung by the position of the operating pin 335 in the cam groove 333. When the operating pin 335 is positioned in the inner cam groove 337, the path of the card 310 is Is open and positioned in the outer cam groove 338, the claw portion 339 of the protect arm 334 engages the rear edge shoulder 340 of the card 310 to prevent the card 310 from being removed.
[0051]
Reference numeral 341 denotes a switch (S1). When the actuator 342 is pressed by the edge 344 of the pushing member 312, a mounting completion signal for the card 310 is transmitted. Reference numeral 348 denotes a switch (S2), which detects that the protect arm 334 is functioning when one action piece 349 of the shift plate 324 pushes the actuator 350. Reference numeral 351 denotes a switch (S3). When the actuator 353 is pushed by the other action piece 352 of the shift plate 324, a discharge completion signal of the card 310 is sent out.
[0052]
Reference numeral 354 denotes a switch (S4) which, when the actuator 357 is released from the operating arm 356 of the open leg L-shaped cam 355, sends a signal indicating that the shift plate 324 is in the insertion standby position. The open leg L-shaped cam 355 is urged clockwise in the figure by a torsion coil spring (not shown), and the operating arm 356 is always in a position to press the actuator 357. When the operation operation piece 358 of the shift plate 324 pushes the action pin 360 erected on the operation arm 359 of the open leg L-shaped cam 355, the operation arm 356 rotates and the actuator 357 is operated (see FIG. 7). ).
[0053]
Next, the operation of the card-like medium extraction preventing mechanism according to this embodiment will be described. In the initial state in which the card 310 is not inserted, the pushing member 312 is positioned on the card insertion side of the storage portion in the rotation range, and the operating shaft 316 is located near the opposite side 322 of the engaging side 320 of the window 319. The edge 344 of the pushing member 312 is held at the inoperative position of the switch (S1) 341 by the elastic repulsive force of the actuator 342.
[0054]
In addition, the operation plate 358 of the shift plate 324 is engaged with the operation pin 360 of the operation arm, the open leg L-shaped cam 355 is rotated to the opening side of the actuator 357, and a standby signal is received from the switch (S4) 354. Create and maintain motor 331 in a stopped state. Further, the operating pin 335 of the protect arm 334 is guided into the inner cam groove 337 and holds the claw portion 339 in the open position. Extrusion member 312 is movable within the range of window 319 except that it is affected by the rotational frictional force with fixed shaft 317 and the elastic repulsive force of actuator 342.
[0055]
The card 310 is inserted along the frame guide 313 and pushed into the connector 311 to complete the connection of the electrical contacts. The pushing member 312 is rotated according to the movement of the card 310 with the protrusion 314 engaging with the insertion edge 315 of the card. At this time, the operating shaft 316 of the pushing member moves to a position in contact with the engaging side 320 of the window 319 of the shift plate 324, the edge 344 of the pushing member 312 pushes the actuator 342, and the switch (S1) 341 is actuated, Detect insertion completion. At this time, the pushing member 312 is restrained only by the rotational frictional force with the fixed shaft 317 and the sliding frictional force with the contact pin 361 (see FIG. 9) of the connector inserted into the connection pin hole of the card 310. Therefore, the card 310 can be freely inserted and removed with a forced force by manual operation.
[0056]
By sending a protect signal from an operation panel (not shown) or by a separate program, the contact of the switch (S4) 354 is short-circuited to drive the motor 331. The driving force of the motor 331 is transmitted from the pinion 330 to the rack 329 via the gear train 332, and the shift plate 324 is moved in the direction of arrow P3 in the drawing. First, the operating pin 335 of the protect arm 334 is guided to the outer cam groove 338, and the claw portion 339 rotates to the closed position. In the position of FIG. 8, the action piece 349 of the shift plate 324 pushes the actuator 350 to operate the switch (S2) 348, and sends a signal for detecting that the protect arm 334 has functioned to stop the motor 331. In this state, since the claw portion 339 of the protect arm is engaged with the rear edge shoulder portion 340 of the card, the card 310 cannot be removed.
[0057]
As a result, the card 310 is extracted electrically, and is achieved by sending a discharge signal from an operation panel (not shown) or by executing a programmed command. That is, the motor 331 is driven in the reverse direction to rotate the shift plate 324 in the direction of the arrow R3 in the figure. At this time, a jumper circuit is set for the switch (S4) 354. The actuating pin 335 of the protect arm 334 is guided into the inner cam groove 337, and the claw portion 339 is disengaged from the rear edge shoulder 340 of the card and rotates out of the path of the card 310. The shift plate 324 continues to rotate, and the engagement side 320 of the window pushes the operating shaft 316 of the pushing member to slide the pushing member 312 in the discharging direction and switch (S1). 341 is opened.
[0058]
In the middle of this movement, the operation operating piece 358 of the shift plate 324 engages with the action pin 360 of the operating arm and operates the switch (S4) 354. This operation is electrically controlled by the setting of the jumper circuit as described above. Therefore, the switch (S4) 354 has no motor stop action. On the other hand, the protrusion 314 is engaged with the insertion side edge 315 of the card 310 by the movement of the pushing member 312, and the card 310 is pulled out from the contact pin 361 of the connector 311 and discharged to a position where it can be easily taken out from the storage portion by manual operation. To do.
[0059]
In the position shown in FIG. 9, the action piece 352 of the shift plate 324 pushes the actuator 353 to operate the switch (S3) 351. The switch (S3) 351 releases the jumper circuit for the switch (S4) 354, and at the same time, reverses the motor 331 to rotate the shift plate 324 again in the direction of arrow P3. In the shift plate 324, the operation operation piece 358 is engaged with the operation pin 360 of the operation arm, the open leg L-shaped cam 355 is rotated to the opening side of the actuator 357, and a standby signal is transmitted from the switch (S 4) 354. At the same time, the motor 331 is stopped. At this time, the engagement side 320 of the window of the shift plate 324 is rotated and maintained to a standby position (see FIG. 7) that does not interfere with the movement of the operating shaft 216 at all.
[0060]
In this embodiment, since the holder for the card 310 is omitted, the number of parts is reduced compared to the first embodiment. The protect arm 334 is provided only on one side, but the protect arm 334 can be provided on both sides by any means applied to the first and second embodiments.
[0061]
In the present embodiment, a card ejection mechanism by manual operation is provided so that the card 310 can be removed in an unexpected situation similar to the first and second embodiments. That is, as shown in FIG. 10, the pinion 330 rotates integrally with the rotary shaft 370 and is slidably mounted in the axial direction, and is urged by the compression coil spring 375 in the axial direction (vertical direction in the figure). . In this embodiment, the fitting portion between the rotary shaft 370 and the pinion 330 is formed as a square pole as a slidable stop, but a sliding key or spline can also be applied. A lever 377 having a linear rack 376 on the side edge is linearly guided so as to be slidable in the direction of arrow K3 on the same plane as the shift plate 324, and is attached in a direction opposite to the direction of arrow K3 by a return tension coil spring 378. It is energized.
[0062]
Usually, the pinion 330 is held at a predetermined position by the compression coil spring 375 and keeps the meshing with the fan-shaped rack 329 normally, so that the driving force is transmitted without any problem. On the other hand, both side edges 381 of the long hole 380 provided in the central portion of the lever 377 moving along the rotation axis 370 have a wedge-shaped slope 379 at the tip, and the boss 383 of the pinion 330 and the collar 384 It can be forced to insert in between.
[0063]
For example, by gripping the small hole 382 provided in the lever 377 with a special tool (not shown) and manually moving the lever 377 in the arrow K direction against the biasing force of the coil spring 378, the biasing force of the compression coil spring 375 is resisted. Thus, the pinion 330 is pushed down by the wedge-shaped inclined surface 379 by the thickness of the lever 377. For this reason, the fan-shaped rack 329 of the shift plate 324 is disengaged from the pinion 330 and is engaged with the rack 376 of the lever 377 instead.
[0064]
Therefore, the shift plate 324 can be rotated by further pushing the lever 377, and the operating shaft 316 can be pushed by the engagement side 320 to move the card 310 together with the pushing member 312 in the discharging direction. However, as in the first and second embodiments, it is considered that only a full-time person can access the lever 377 by a mechanism (not shown).
[0065]
Furthermore, the electric drive system shown in FIG. 10 is applied to a double card storage unit. Thus, since the pinion 330 which is the final output stage is arranged at the central portion of the side edge of the storage unit, the electric drive system can be integrated on one side of the storage unit, and a compact configuration is possible. That is, the symbol with the letter A added in the figure is the drive system of the card storage unit 390A provided in the upper part of the figure, and the code with the letter B added in the drawing is the drive system of the card storage part 390B provided in the lower part of the figure. is there. This configuration can be similarly configured for the first and second embodiments.
[0066]
【The invention's effect】
As described above, the card-shaped medium removal prevention mechanism according to the present invention prevents the card-shaped medium inserted into the storage portion from being closed by electric operation and prevents the card-shaped medium from being moved to the outside. It becomes impossible to prevent the contents of the card-like medium from being damaged. Also, theft can be prevented because electrical operation by software is possible. Furthermore, since the discharging is performed electrically, it is not difficult to perform the discharging operation, so that it is possible to suppress damage to the electrical contacts.
[0067]
On the other hand, since the manual insertion operation and the electric discharge operation are engaged only in the pushing direction, manual insertion / removal can be performed without a protection operation. In addition, the electric output pinion is arranged in the central portion of the side edge of the card storage unit, so that it is easy to arrange the electric drive mechanism in the front-rear direction only on one side of the storage unit, and the limited area. Thus, the card storage portion can be configured in a double structure so that two cards can be controlled individually, and a compact configuration is possible.
[Brief description of the drawings]
FIG. 1 is a plan view showing a card mounting state in a first embodiment of a card-like medium removal preventing mechanism according to the present invention.
FIG. 2 is a plan view showing a protector operating state in the first embodiment of the card-like medium removal preventing mechanism according to the present invention;
FIG. 3 is a plan view showing a card ejection state in the first embodiment of the card-like medium removal preventing mechanism according to the present invention.
FIG. 4 is a plan view showing a card mounting state in a second embodiment of the card-like medium removal preventing mechanism according to the present invention.
FIG. 5 is a plan view showing a protector operating state in a second embodiment of the card-like medium removal preventing mechanism according to the present invention.
FIG. 6 is a plan view showing a card ejection state in a second embodiment of the card-like medium removal preventing mechanism according to the present invention.
FIG. 7 is a plan view showing a card mounting state in a third embodiment of the card-like medium removal preventing mechanism according to the present invention.
FIG. 8 is a plan view showing a protector operating state in a third embodiment of the card-like medium removal preventing mechanism according to the present invention.
FIG. 9 is a plan view showing a card ejection state in a third embodiment of the card-like medium removal preventing mechanism according to the present invention.
10 is an enlarged view of a side surface taken along line XX of FIG.
FIG. 11 is a flowchart of a switch for detecting an operation process of a card-like medium extraction preventing mechanism according to the present invention.
[Explanation of symbols]
10 cards
12 Holder
14 Protrusion
16 Operating shaft
18 Extruded member
21 Spindle
23 Drive pin
24 shift plate
29 racks
30 pinion
31 motor
32 Gear train
33 Cam groove
34 Protect Arm
35 Actuation pin
39 claws
41 Card installation detection switch (S1)
48 Protection function detection switch (S2)
51 Card ejection detection switch (S3)
54 Motor stop standby switch (S4)

Claims (5)

A card-like medium read / write device having a card-like medium storage unit, and having a discharge mechanism that allows the card-like medium inserted and mounted in the storage unit by manual operation to be ejected by electric operation. ,
A protection member that can be opened and closed in conjunction with the discharge mechanism is provided in the vicinity of the opening of the storage unit for inserting and removing the card-like medium, and the card-like medium can be freely inserted and removed in the open position and in the closed position. together so as to suppress the discharge of the card-like medium,
The discharge mechanism includes a holder having a protrusion that engages with the insertion-side end surface of the card-like medium, an extrusion member that operates in conjunction with the holder, a protrusion that engages only with the extrusion member in the extrusion direction, and electric The card-shaped medium is prevented from being pulled out by a shift plate that is linearly driven and has a rack that meshes with a driven pinion, and is controlled by engaging the protect member with a cam groove provided in the shift plate. mechanism. A card-like medium read / write device having a card-like medium storage unit, and having a discharge mechanism that allows the card-like medium inserted and mounted in the storage unit by manual operation to be ejected by electric operation. ,
A protection member that can be opened and closed in conjunction with the discharge mechanism is provided in the vicinity of the opening of the storage unit for inserting and removing the card-like medium, and the card-like medium can be freely inserted and removed in the open position and in the closed position. While suppressing the discharge of the card-like medium,
The ejecting mechanism is engaged with a holder provided with a projecting portion engaged with the insertion side end surface of the card-like medium, and a projection that is pivotally supported by the frame of the storage unit and is erected on the holder only in the pushing direction. The card-shaped medium is prevented from being pulled out by a shift plate that is rocked by a fan-shaped rack that meshes with an electrically driven pinion and that is controlled by engaging the protect member with a cam groove provided in the shift plate. mechanism. A card-like medium read / write device having a card-like medium storage unit, and having a discharge mechanism that allows the card-like medium inserted and mounted in the storage unit by manual operation to be ejected by electric operation. ,
A protection member that can be opened and closed in conjunction with the discharge mechanism is provided in the vicinity of the opening of the storage unit for inserting and removing the card-like medium, and the card-like medium can be freely inserted and removed in the open position and in the closed position. While suppressing the discharge of the card-like medium,
The ejecting mechanism includes a projecting portion that engages with the insertion-side end surface of the card-like medium, and includes an extruding member that is pivotally supported by the frame of the storage unit, a drive projection that is erected on the extruding member, and an ejecting direction. A card-like medium comprising a shift plate that is engaged with and engaged with an electrically driven pinion and that is swung by a fan-shaped rack. The card-like medium is controlled by engaging the protect member with a cam groove provided in the shift plate. Extraction prevention mechanism. 4. The card-like medium removal preventing mechanism according to claim 1, wherein the protect member is provided on both sides of the card-like medium. Switch means for detecting completion of loading of the card-like medium; switch means for detecting that the protection means is in a closed position; switch means for detecting completion of ejection of the card-like medium; The card-type medium removal prevention mechanism according to claim 1, further comprising a switch unit that detects that the card is removable.

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