JP4176524B2 - Holder for plate storage media - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a plate-shaped storage medium holder.
[0002]
[Prior art]
In recent years, as various terminal devices such as a digital camera and a mobile phone, a device that reads and / or writes data by inserting a plate-like storage medium such as a memory card is rapidly spreading. As the plate-shaped storage medium, for example, a so-called memory stick, SD card, memory stick duo, and the like are known.
With the diversification of devices used and the increase in memory capacity, plate-shaped storage media having new connection specifications and shapes are being put on the market one after another.
On the other hand, data stored in such a plate-shaped storage medium is often taken into a personal computer by an appropriate data reading means. For example, a PC card slot conforming to the PCMCIA standard may be used. That is, a slot for connecting a plate-shaped storage medium is provided in a PC card adapter compatible with the external shape and connector of the PC card, and the PC card adapter connected to the plate-shaped storage medium is inserted into the PC card slot of the personal computer. Data exchange can be performed in accordance with the PC card interface.
Conventionally, such PC card adapters are manufactured with various mechanical interfaces according to the shape of the plate-shaped storage medium. For example, Patent Document 1 describes a PC card that can be used as a PC card adapter that can manually move an ejector that holds a so-called SIM card so as to be able to advance and retract.
[0003]
[Patent Document 1]
Japanese Patent Laying-Open No. 2002-298092 (page 3-5, FIG. 1-3)
[0004]
[Problems to be solved by the invention]
However, the conventional plate-shaped storage medium holders as described above cannot insert plate-shaped storage media having different shapes from a common opening.
For example, conventionally used plate-shaped storage media having different shapes include plate-shaped storage media 40 and 50 having shapes as shown in FIGS. The feature of the shape will be briefly described.
12A, 12B, and 12C are a rear view, a left side view, and a plan view for explaining the shape of the plate-like storage medium 40, respectively. FIGS. 13A, 13B, and 13C are a plan view, a right side view, and a back view for explaining the shape of the plate-like storage medium 50, respectively.
[0005]
The plate-shaped storage medium 40 has a length × width × thickness of L ₁ × W ₁ × H ₁ The storage medium main body (all not shown) which consists of a circuit board containing memory | storage elements, such as a non-volatile memory, is accommodated in the somewhat elongate substantially rectangular parallelepiped external shape.
And the connection terminal 40a ... which conduct | electrically_connects to a storage medium main body is provided in the state withdrawn inside by the front end surface 40c side of the back surface 40e (reference surface), and the structure inserted and connected to a terminal device etc. from the front end side is comprised. It has been taken. A curved portion 40b is formed in the planar direction on one of the front end corners of the plate-shaped storage medium 40, and a relief groove 40g is provided on the back surface 40e side in the thickness direction. On the rear end side in the adjacent direction of the escape groove 40g, a locking concave portion 40d having a U shape in a plan view is provided from the side portion 40f side. The locking recess 40d is a groove for engaging a protrusion protruding from the side portion 40f to engage the plate-like storage medium 40.
curve On the side portion 40f opposite to the portion 40b, a locking recess 40i is provided in the middle in the longitudinal direction on the back surface 40e side in a U-shape in plan view from the side portion 40f side. The locking recess 40i has a width dimension U when viewed from the side 40f side. ₁ , Its depth dimension is D ₁ It is said that.
The front surface 40h is a flat surface substantially parallel to the back surface 40e. The outer periphery of the plate-like storage medium 40 is made of an insulator or a conductor that is electrically insulated from the connection terminal 40a and the storage medium body, except for the connection terminal 40a.
[0006]
The plate-shaped storage medium 50 has a length × width × thickness of L ₂ × W ₂ × H ₂ A storage medium body (both not shown) made of a circuit board including a storage element such as a nonvolatile memory is housed therein.
The connection terminals 50a... That are electrically connected to the storage medium main body are provided so as to be retracted inward on the front end surface 50c side of the back surface 50e (reference surface), and are connected to the terminal device by being inserted from the front end side. It has been taken. A chamfered portion 50b is formed in the planar direction at one of the front end corners of the plate-shaped storage medium 50, and a locking groove 50g is provided on the back surface 50e side in the thickness direction. Lock groove 50g side Part On the 50f side, a flat locking surface 50i is formed at the tip. Further, a locking recess 50d having a U-shape in plan view from the side 50f side is provided on the rear end side in the adjacent direction of the locking groove 50g. The locking recess 50d is a groove for engaging a protrusion protruding from the side portion 50f side in order to engage the plate-like storage medium 50.
On the side portion 50f opposite to the chamfered portion 50b, a locking recess 50j is formed in a U shape in a plan view from the back surface 50e side, on the distal end surface 50c side in the longitudinal direction, at a position slightly on the tip side from the locking recess 50d. Is provided. The locking recess 50j has a width dimension U when viewed from the side 50f side. ₂ , Its depth dimension is D ₂ It is said that.
The front surface 50h is a flat surface substantially parallel to the back surface 50e. The outer periphery of the plate-like storage medium 50 is an insulator or connection terminal except for the connection terminal 50a. 5 0a and the storage medium body are made of an electrically insulated conductor.
[0007]
The plate-like storage media 40, 50 are each provided with connection terminals 40a ..., 50a ... on the back surface 40e, 50e side, and the curved portion 40b and the locking recess 40d, and the chamfered portion 50b and the locking recess 50d are: It is located in the same left and right direction with respect to the insertion direction.
Each external dimension is L ₁ > L ₂ , W ₁ > W ₂ , H ₁ > H ₂ Therefore, the plate-like storage medium 50 has a size included in the volume occupied by the plate-like storage medium 40. However, in this example, W ₂ Is W ₁ However, it has only a few millimeters.
Further, the connection terminals 40a... And the connection terminals 50a... Have different arrangement pitches and signal assignments between the terminals, and are not mechanically and electrically compatible.
[0008]
Therefore, for example, if an attempt is made to produce a terminal device that can use both of the plate-like storage media 40, 50, a plurality of plate-like storage medium holders must be provided in accordance with each of the terminal devices. There was a problem that it was not possible to reduce the size.
For example, when such a plate-shaped storage medium holder is provided as a PC card adapter, it is necessary to insert a plurality of PC cards, and there is a problem that a valuable PC card slot such as a personal computer is occupied.
Although it can be considered to reduce the installation area by providing the respective plate-shaped storage medium holders in the thickness direction, there is a problem that a space is taken in the thickness direction. In particular, when it is provided in a PC card adapter, it is difficult to mount it on, for example, a PC card Type II having a thickness of 5 mm, and it has to be a PC card Type III having a thickness of 10.5 mm, because the external standard is determined. This has caused a problem that a valuable PC card slot is occupied.
Furthermore, even if a plurality of types of plate-shaped storage media can be arranged with a desired size, a single ejector is used because the external dimensions are different, for example, when an ejector mechanism is used in consideration of the convenience of insertion and removal. It is difficult to use the mechanism, and it is necessary to provide a plurality of complicated eject mechanisms according to each of them.
Further, the technique described in Patent Document 1 does not describe a technique for inserting / removing a plurality of types of plate-like storage media from a common insertion / removal port, and thus has the same problem as described above.
[0009]
The present invention has been made in view of such problems, and even in the case of plate-shaped storage media having different shapes, in particular, shapes with slightly different widths in the insertion / extraction direction, To provide a holder for a plate-like storage medium that can be inserted / removed from a common opening in a positional relationship in which the cross-sections in the insertion / extraction direction overlap, and that can be easily inserted / removed with the same certainty while using a common attachment / detachment mechanism. With the goal.
[0010]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, in the invention according to claim 1, a terminal is provided on one side of the front and back surfaces, and a position in the insertion / removal direction is held in a predetermined range on a side portion with respect to the insertion / removal direction. A holder for a plate-shaped storage medium having a holding groove for receiving and detachably storing a plurality of types of plate-shaped storage media having different outer shapes, wherein the plurality of types of plate-shaped storage media are inserted in the insertion / removal direction. A plate-shaped storage medium storage section that can be stored in respective positions such that the cross sections perpendicular to each other overlap; A movable position restricting member that forms a position restricting surface according to the shape of the plurality of types of plate-shaped storage media by advancing and retreating into the insertion path of the plurality of types of plate-shaped storage media; From the side of the plate-shaped storage medium storage portion, it is provided so as to be able to advance and retreat into each of the holding grooves, and at the time of advancement, each plate-shaped storage medium is held in the plate-shaped storage medium storage portion in a state where it is difficult to pull out, Hold when evacuating groove It is possible to retract to the outside of the holding groove while urging the pressing force to pull out the plate storage medium. And movable in the direction of contacting and separating along the width direction of the plate-shaped storage medium that intersects the side of the plate-shaped storage medium in the insertion / removal direction. A movable engagement portion and a removal operation portion that transmits a pressing force to the movable engagement portion and removes the plate-shaped storage medium are provided.
According to the present invention, a plurality of types of plate-shaped storage media are stored in the plate-shaped storage medium storage portion at respective positions where the cross sections perpendicular to the insertion / removal direction overlap each other, so that the thickness direction dimension is reduced. be able to. Further, the plate-shaped storage medium is held in the plate-shaped storage medium storage unit by moving back and forth in the holding groove, and the plate-shaped storage medium is retreated from the holding groove while urging the pressing force transmitted from the removal operation unit. Since the movable engaging part to be removed is provided, if the plate-shaped storage medium has a holding groove, even if the holding groove has a different depth in the direction perpendicular to the insertion / removal direction, the movable engagement is possible. By moving the part in the depth direction, it can be securely engaged with the holding groove, and by retracting it in the reverse direction at the time of removal, it can be removed while smoothly releasing the engagement with the holding groove. .
[0011]
According to a second aspect of the present invention, in the plate-shaped storage medium holder according to the first aspect, the movable engaging portion has a holding claw provided at an end for engaging with the holding groove; A rotating arm member having an engaging mechanism for engaging with the pulling operation part, a rotating shaft for rotating the holding claw in a direction for pulling the holding claw to the holding surface, and the rotation of the rotating arm member A shaft guide mechanism that allows the shaft to move in a direction that moves toward and away from the side portion in the insertion / removal direction of the plate storage medium, and a direction in which the rotation shaft approaches the side portion of the plate storage medium And an urging means for urging the rotating arm member with an elastic force.
According to the present invention, the rotary arm member can be moved in the direction of contact with and away from the side portion of the plate-like storage medium by the shaft guide mechanism, and the urging means is elastic in the direction in which the rotation shaft approaches the plate-like storage medium. Because the force is urged, the holding claw provided at the end of the rotating arm member will advance the holding claw according to the change even if the depth of the holding groove changes depending on the type of plate storage medium Can be made. As a result, the holding claw can be reliably engaged with the holding groove, and a reliable pressing force can be applied during removal. Further, when the engaging claw is withdrawn from the holding groove to release the engagement at the time of removal, in addition to the movement by the rotation of the rotating arm member, the movement in the direction away from the side by the shaft guide mechanism can be taken into account. As a result, the engagement can be released more smoothly.
[0012]
According to a third aspect of the present invention, in the plate-shaped storage medium holder according to the second aspect, the biasing means also serves as a means for biasing a pressing force for removing the plate-shaped storage medium.
According to the present invention, since the urging means also urges the pressing force for removing the plate-shaped storage medium, the parts can be shared.
[0013]
According to a fourth aspect of the present invention, in the plate-shaped storage medium holder according to any one of the first to third aspects, the plate-shaped storage medium storage is provided. Payment The portion is inserted from a common opening, a plate-shaped storage medium having a relatively large longitudinal width and a plate-shaped storage medium having a relatively small longitudinal width when viewed from the insertion / removal direction, The plate storage medium having the relatively small width is arranged within the longitudinal width of the plate storage medium having the relatively large width.
According to the present invention, since the plate-shaped storage medium having a relatively small longitudinal width is disposed within the longitudinal width of the plate-shaped storage medium having a relatively large longitudinal width when viewed from the insertion / extraction direction, The area can be reduced.
[0014]
According to a fifth aspect of the present invention, in the plate-shaped storage medium holder according to any one of the first to fourth aspects, the connector includes a connector electrically connected to the inserted plate-shaped storage medium. It is set as the structure which can be attached or detached through these connectors with respect to the apparatus which has the other party connector which can be connected.
According to the present invention, since the plate-shaped storage medium holder can be attached to and detached from other devices, a plurality of types of plate-shaped storage media can be electrically connected to the connector. Even a plurality of electrically different types of plate-like storage media can have connection compatibility.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a perspective explanatory view for explaining a plate-shaped storage medium holder 1 according to an embodiment of the present invention. FIG. 2 is an explanatory plan view for explaining the casing 2 forming the base of the plate-shaped storage medium holder 1 of the present embodiment. FIGS. 3A and 3B are a plan explanatory view and a BB cross-sectional view for explaining the plate storage medium housing portion 5 of the plate storage medium holder 1 of the present embodiment. 4A and 4B are schematic plan views and side views for explaining the positional relationship when the plate storage media 50 and 40 are respectively inserted into the plate storage medium holder 1 of the present embodiment. It is explanatory drawing. 5A and 5B are side explanatory views of the state in which the plate-like storage media 50 and 40 are inserted as seen from the A viewing direction of FIG.
[0016]
A plate-shaped storage medium holder 1 according to an embodiment of the present invention will be described.
The plate-shaped storage medium holder 1 of the present embodiment allows a plurality of types having different shapes to be inserted in a conventional plate-shaped storage medium such as a memory card so that the plate-shaped storage medium main body and the connector 7 can be electrically connected. By connecting to an appropriate electric circuit board outside the apparatus via the connector 7, data can be read from and written to the plate storage medium. Specifically, for example, it can be suitably used for a PC card adapter that can be inserted into and removed from a PC card slot compliant with the PCMCIA standard.
In the following, an example in the case of a shape such as the plate-shaped storage medium 40 (first plate-shaped storage medium) and the plate-shaped storage medium 50 (second plate-shaped storage medium) will be described.
[0017]
For ease of explanation, when referring to the relative positional relationship, as shown in FIG. 1, the plate-shaped storage medium holder 1 is disposed in the horizontal direction with the thickness direction set vertically, and the plate It is assumed that the storage media 40 and 50 are inserted into the back side from the opening 11 on the near side, and based on such an arrangement, the vertical direction, the insertion / removal direction, the insertion direction, and the removal / removal are performed within a range that does not cause misunderstanding. Sometimes referred to as direction, back side, near side, and the like. However, this does not limit the arrangement posture in actual use of the holder for the plate-like storage medium of the present invention.
[0018]
As shown in FIG. 1, the schematic configuration of the plate-shaped storage medium holder 1 of the present embodiment includes a casing 2 and a cover 4 that covers the casing 2 from the outside, and an eject button 9 ( And an opening 11 are provided. On the inner side of the casing 2, an ejector portion 3 (movable engagement portion), a plate-shaped storage medium storage portion 5, an electronic circuit portion 6, and a connector 7 are provided. The eject button 9 and the ejector unit 3 serve as an attachment / detachment mechanism for attaching / detaching the plate-like storage media 40, 50.
The outer shape of the plate-shaped storage medium holder 1 is L × W × Thickness L ₃ × W ₃ × H ₃ When the outer shape of the PC card Type II conforming to the PCMCIA standard is used, for example, L ₃ = 85.6 mm, W ₃ = 54 mm, H ₃ = 5 mm.
[0019]
The cover 4 is made of a metal plate that is inserted along the casing 2 to be described later and has the same potential as the ground portion inside the casing 2 and has a shape that satisfies the outer shape of a predetermined standard.
The connector 7 is provided across the width direction on the back side in the insertion / removal direction of the plate-shaped storage medium holder 1, and the plate-shaped storage medium holder 1 can be inserted into an appropriate terminal device or personal computer to be electrically connected. Is. For example, it consists of a female connector that can be inserted into a PC card slot or the like.
When the plate storage medium 40 or 50 is inserted into the plate storage medium holder 1, the electronic circuit unit 6 stores the data stored therein according to a control signal given from the outside of the plate storage medium holder 1. As a data signal based on an appropriate electrical interface at an appropriate timing, it is sent to the connector 7, or on the contrary Part In accordance with these control signals, the circuit board comprises an electric circuit board provided with a data input / output control circuit for writing data in a predetermined format to the plate-like storage medium 40 or 50. And it arrange | positions in the space which makes | forms L shape of planar view between the connector 7 and the plate-shaped storage medium accommodating part 5 mentioned later, and is electrically connected to the board | substrate 8 mentioned later in the connector 7 and the plate-shaped storage medium accommodating part 5, respectively. Connected.
[0020]
As shown in FIG. 2, the casing 2 has a substantially rectangular shape in plan view, and includes a frame body having various structures such as a plate shape, a beam shape, and a shaft shape on the inner side.
A connector mounting portion 2h for mounting the connector 7 is provided on the rear side in the insertion / removal direction, and a circuit board mounting portion 2g divided in an L shape in plan view for mounting the electronic circuit portion 6 is provided on the front side thereof. Is provided.
A storage frame portion 2X is provided between the opening 11 and the circuit board mounting portion 2g in order to form the plate-shaped storage medium storage portion 5.
An ejector mounting portion 2Y for forming the ejector portion 3 is provided in a region adjacent to the storage frame portion 2X in the width direction.
[0021]
Next, the plate-shaped storage medium storage portion 5 will be described together with details of the storage frame portion 2X.
The plate-shaped storage medium storage unit 5 includes a substrate 8, rotating blocks 10A, 10B, and guide plates 20A, 20B attached to the storage frame 2X.
[0022]
The storage frame 2X is provided with a substrate receiving surface 2d for arranging the substrate 8 in the horizontal direction on the upper side. The substrate receiving surface 2d is provided with holes 2p and 2q on the back side and the near side in order to avoid terminals 8a and 8b, which will be described later, in plan view.
Between the insertion / removal directions of the holes 2p and 2q, the substrate receiving surface 2d has a beam shape extending in the width direction. The end surface on the near side in the insertion / removal direction of the beam is a position regulating surface for contacting the front end surface 50c of the plate-like storage medium 50.
The end surface in the width direction of the hole 2q is a left inner restriction surface 2D and a right inner restriction surface 2E for restricting the position of the plate storage medium 50 in the width direction within a range in which the plate storage medium 50 is inserted. The distance between the surfaces in the width direction is W ₂ Slightly larger width w ₂ It is said that.
[0023]
In the vicinity of the back side of the right inner regulating surface 2E, there is provided an erroneous insertion preventing projection 2a that enters the locking groove 50g when the plate-like storage medium 50 is inserted.
On the outer side in the width direction of the left inner regulating surface 2D and the right inner regulating surface 2E, a step is formed on the lower surface side, and the left outer regulating surface 2A for regulating the position of the plate storage medium 40 in the width direction in the width direction. A right outer regulation surface 2B is provided. The distance between the surfaces in the width direction is W ₁ Slightly larger width w ₁ It is said that.
[0024]
The back surface of the substrate receiving surface 2d between the left outer restricting surface 2A and the right outer restricting surface 2B is a first receiving surface 2C that restricts the rear surface 40e of the plate-shaped storage medium 40 to the upper side. The distance between the substrate receiving surface 2d and the first receiving surface 2C is the height H of the plate storage medium 50. ₂ The distance is smaller. For this reason, it is set as the positional relationship which the cross section of the insertion position of the plate-shaped storage media 50 and 40 overlaps in the cross section orthogonal to the insertion / removal direction.
Further, on the back side of the right outer regulating surface 2B of the first receiving surface 2C, an erroneous insertion preventing projection 2c that is matched to the shape of the escape groove 40g is formed downward from the first receiving surface 2C. . The first receiving surface 2C near the lower side of the erroneous insertion preventing protrusion 2c has a step protruding downward to position-control the back side positions of the curved portion 40b and the front end surface 40c of the plate-like storage medium 40. A certain back side locking portion 2b is provided.
[0025]
A rotation block 10A, which will be described later, has a U-shaped wall surface that opens to the inside in the width direction at a predetermined position below the substrate receiving surface 2d on the outer side in the width direction of the left outer regulation surface 2A and the right outer regulation surface 2B. Rotating block storage holes 2e for storing 10B are provided. A rotating shaft 21 extending vertically downward from the back surface of the substrate receiving surface 2d is provided in each rotating block storage hole 2e to rotatably support the rotating blocks 10A and 10B.
[0026]
As shown in FIGS. 3 and 4, the substrate 8 has spring-like terminals 8a bent downward to electrically connect with the connection terminals 40a on the back side of the upper surface 8d of the substrate. Are electrically connected to the connection terminals 50a, and are each provided with spring-like terminals 8b bent downward so as to be electrically connected to each other. Board top surface 8 d Are formed with appropriate circuit patterns for conducting the terminals 8a..., 8b.
The substrate lower surface 8c is a smooth flat surface, and is a position regulating surface that regulates the upper surface of the back surface 50e of the plate-like storage medium 50 while being attached to the substrate receiving surface 2d.
[0027]
The rotation blocks 10A and 10B are block members for restricting the insertion positions of the plate-like storage media 50 and 40 together with the storage frame 2X by being fitted to the rotation shaft 21 so as to be rotatable in the horizontal direction. Yes (see FIG. 5).
Since the rotary blocks 10A and 10B are symmetrical with respect to the insertion / removal direction, the rotary block 10B will be described below with reference to FIG. 6, and the rotary block 10A has the same reference numerals assigned to the corresponding parts. Description is omitted.
6A and 6B are a plan view and a front view for explaining the shape of the rotating block 10B. 6C and 6D are plan explanatory views for explaining the state of the rotating block 10B when the plate-like storage media 50 and 40 are inserted, respectively.
[0028]
The rotating block 10B is formed by providing a spring member 10f, which is a plate-like thin piece having an S shape in a plan view, on a block member that has a substantially rectangular shape in a plan view and a substantially L shape in a front view. Then, a lower surface regulating surface 10a for regulating the position of the front surface 50h of the plate-like storage medium 50 downward is provided on the upper surface of the arm portion 10X that extends in the horizontal direction in a state of being attached to the storage frame portion 2X, and the lower surface regulating surface 10a. Is provided with a side regulating surface 10b for regulating the position of the side portion 50f of the plate-like storage medium 50 in a direction perpendicular to the side. A bearing 10e formed of a circular hole parallel to the side surface regulating surface 10b is provided on the end side of the rotating block 10B in plan view.
[0029]
The side regulating surfaces 10b and 10b are aligned in the width direction with the left inner regulating surface 2D and the right inner regulating surface 2E, respectively, in the mounted state, and the distance between them is the width w. ₂ It is said that. The distance between the lower surface regulating surfaces 10a and 10a and the substrate receiving surface 2d is H. ₂ Slightly greater height h ₂ It is said that.
The substantially L-shaped side surface opposite to the spring portion 10f is formed with an arm portion side surface 10h that is a plane orthogonal to the lower surface regulating surface 10a and the side surface regulating surface 10b. An inclined surface that is a chamfered inclined surface between the arm side surface 10h, the lower surface regulating surface 10a, and the side surface regulating surface 10b so that it can be smoothly inserted even if the insertion position of the plate storage medium 50 is slightly shifted. 10c and 10b are provided.
[0030]
3A and 3B show the attachment state of the rotating blocks 10A and 10B.
In the state where the external force does not act, as shown in FIG. 6C, the arm portion 10X is projected so as to be orthogonal to the insertion / removal direction with the arm portion side surface 10h facing the opening portion 11 side. At this time, the spring portion 10f is lightly pressed by the spring locking surface 2f and biases an elastic force that rotates the arm portion 10X toward the opening 11 side.
When an external force of a predetermined value or more is applied to the arm portion 10X in the insertion direction, as shown in FIG. 6D, the spring portion 10f is bent, and the arm portion 10X rotates to the rotating block storage hole 2e side. It is stored in the rotating block storage hole 2e.
[0031]
As shown in FIG. 3, the guide plates 20A and 20B are plate-like members having a substantially rectangular shape in plan view provided on the lower surface side of the casing 2, and spring receiving surfaces that hold the rotary blocks 10A and 10B from the lower surface side. 20c and a guide surface 20a for regulating the position of the surface 40h of the plate-like storage medium 40 from the lower side.
[0032]
The spring receiving surface 20c is a U-shaped groove in plan view provided in accordance with the position of the rotating block storage hole 2e. The spring receiving surface 20c merges with the rotating block storage hole 2e in the attached state and is concavely formed outward in the width direction. A square groove is formed.
The guide surface 20a is a plate surface protruding in the horizontal direction inside in the width direction, and the distance from the first receiving surface 2C is a height H. ₁ Slightly greater height h ₁ It is said that.
Therefore, as shown in FIGS. 5A and 5B, in the storage frame portion 2X, the plate-shaped storage media 50 and 40 can be inserted with their positions regulated in the width direction and the height direction, respectively. It has become. Further, in a plan view, by restricting the position of the distal end surface 40c, the curved portion 40b, the distal end surface 50c, the locking groove 50g, etc., it is possible to insert them in the positional relationship as shown in FIG. It has become.
[0033]
Next, the ejector portion 3 will be described together with details of the ejector mounting portion 2Y.
FIG. 7 is an exploded perspective view for explaining the ejector portion 3 according to the embodiment of the present invention.
The ejector unit 3 includes an eject button 9, a coil spring 14 (biasing means), a rotating lever 13 (rotating arm member), and a support plate 12 attached to the ejector mounting unit 2Y.
[0034]
The ejector mounting portion 2Y supports a rotating shaft on the ejector support plate portion 2i so that the slide guide 2n including a protrusion for guiding the eject button 9 in the insertion / removal direction and the lower end of the rotary lever 13 can be moved in the width direction. For example, a slide shaft hole 2j (shaft guide mechanism) made of, for example, a long hole and a spring locking pin 2k for locking one end of the coil spring 14 are provided.
The eject button 9 is a rod-shaped member extending in the insertion / removal direction that is supported so as to be movable in the insertion / removal direction, adjacent to the width direction of the opening 11, and includes a button portion 9a on the near side in the insertion / removal direction. The rod portion 9b is extended to the rear side in the insertion / removal direction, and an engagement pin 9c (engagement mechanism) extended vertically upward is provided at the rear end portion thereof.
A slide groove 9d for slidably engaging with the slide guide 2n is provided on the back surface side of the rod portion 9b. In the assembled state, the button portion 9a is engaged with a guide hole 2m (see FIG. 2) that can be fitted in the insertion / removal direction so as to be movable in the insertion / removal direction.
[0035]
The rotary lever 13 is a lever member that is provided with a rotary shaft 13a in the vertical direction and is rotatably supported in a horizontal plane. The rotary lever 13 can be engaged with an engagement pin 9c at one end in the circumferential direction of rotation and in the radial direction of rotation. A slide groove 13c (engagement mechanism) having a U-shape in a plan view is provided. Further, the opposite end is provided with a locking claw 13b (holding claw) that can be engaged in the locking recesses 50j and 40i (holding grooves) of the plate-like storage media 50 and 40 in the horizontal direction.
[0036]
The locking claw 13b has a width u in the insertion / removal direction because the lower side engages with the locking recess 40i. ₁ (U ₁ <U ₁ ) Having a lower end surface 13B having a width u in the insertion / removal direction for the upper side to engage with the locking recess 50j. ₂ (U ₂ <U ₂ ) Having an upper tip surface 13A having a hook-like shape in side view. However, the pressing surface 13C which is the side surface on the near side in the insertion / removal direction is aligned vertically. In the present embodiment, the upper tip surface 13A protrudes by a width d compared to the lower tip surface 13B.
A protrusion 13 d for restricting the rotation of the rotation lever 13 is provided on the front side in the circumferential insertion / removal direction of the rotation lever 13. The protruding portion 13d has an asymmetric shape in the circumferential direction, the locking claw 13b side in the circumferential direction has a gentle inclination, and the sliding groove 13c side in the circumferential direction has a steep inclination or a protrusion. And has a shape that gently engages. Similarly, on the back side in the circumferential insertion / removal direction, there is provided a spring locking pin 13e (not shown) that extends vertically downward to lock the other end of the coil spring 14.
[0037]
The coil spring 14 is for urging an elastic tensile force against the rotating lever 13 so that the locking claw 13b is directed to the front side in the insertion / removal direction and toward the storage frame portion 2X in the width direction.
The support plate 12 sandwiches the eject button 9, the rotation lever 13, and the coil spring 14 with the ejector mounting portion 2Y, and particularly restricts the position of the button portion 9a and the rotation lever 13. For this purpose, a button guide portion 12d is provided on the front side in the insertion / removal direction, and a slide made of, for example, a long hole is used to rotatably support the upper portion of the rotary shaft 13a so as to be movable in the width direction on the slide shaft hole 2j in the center. A shaft hole 12a (shaft guide mechanism) is provided.
Between the slide shaft hole 12a and the button guide portion 12d, there is formed a protrusion 12b that has flexibility in the horizontal plane extending in the width direction and projects in the center in the insertion / removal direction. An elastic beam 12c is provided.
The protruding portion 12b is provided at a position where the protruding portion 13d is lightly locked. When a rotational force exceeding a predetermined load is applied to the rotating lever 13, the elastic beam 12c is bent and the locking is released. ing.
[0038]
Next, the operation of the plate storage medium holder 1 of the present embodiment will be described.
FIGS. 8A, 8B, 9C, and 9D are plan views for sequentially explaining schematic operations of inserting and removing the plate storage medium 40 in and out of the plate storage medium holder 1, respectively. It is a partial explanatory view. 10 (a), 10 (b), 11 (c), and 11 (d) are plan views for sequentially explaining schematic operations for inserting / removing the plate storage medium 50 into / from the plate storage medium holder 1 respectively. It is a partial explanatory view. Since the rotating block 10B always operates symmetrically with the rotating block 10A, the illustration is omitted.
[0039]
First, with reference to FIGS. 8 and 9, the operation of inserting and removing the plate-shaped storage medium 40 will be described.
The plate-shaped storage medium 40 is inserted into the opening 11 with the back surface 40e facing upward. At this time, as shown in FIG. 5B, in the height direction, the front surface 40h and the back surface 40e are restricted by the guide surfaces 20a and 20a (see FIG. 3) and the first receiving surface 2C. In addition, since the width direction is restricted by the left outer restricting surface 2A and the right outer restricting surface 2B, it can be inserted with a predetermined positional accuracy.
As shown in FIG. 8A, when the insertion is advanced, the distal end surface 40c and the curved portion 40b come into contact with the rotating blocks 10A and 10B (the rotating block 10B is not shown, the same applies hereinafter) and press them. The rotating blocks 10A and 10B are rotated left and right respectively. The rotary blocks 10A and 10B retract the arm side surface 10h to a position substantially parallel to the side portions 40f and 40f, and position the side portions 40f and 40f in the width direction together with the left outer restriction surface 2A and the right outer restriction surface 2B. is doing.
[0040]
On the other hand, the rotation lever 13 protrudes from the insertion path of the plate-like storage medium 40. Therefore, the distal end surface 40c abuts against the pressing surface 13C and is inserted into the back side while rotating the locking claw 13b counterclockwise in the figure.
At this time, since the rotary lever 13 is urged by the coil spring 14 in the width direction, the rotation lever 13 is positioned on the plate-shaped storage medium 40 side (the right side in the figure) in the width direction of the slide shaft hole 2j (12a). Yes. At the same time, since the slide groove 13c is also rotated counterclockwise, the eject button 9 is pushed forward in the insertion / removal direction via the engagement pin 9c.
[0041]
When the insertion further proceeds, as shown in FIG. 8B, the rotary lever 13 further rotates, and the pressing surface 13C retreats to the outer side in the width direction of the left outer restricting surface 2A to escape the pressing of the tip end surface 40c. Instead, the lower tip surface 13B comes into contact with the side portion 40f. The coil spring 14 is further stretched and an increasingly large tensile elastic force is applied, and the rotary shaft 13a is strongly pressed against the plate-shaped storage medium 40 side of the slide shaft hole 2j (12a). At this time, the lower front end surface 13B escapes to the upper side of the plate-like storage medium 40.
In the drawing, the rotation shaft 13a is drawn so as to be in contact with the end surface of the slide shaft hole 2j (12a). In that case, the component force in the width direction of the coil spring 14 is transmitted to the side portion 40f via the lower tip surface 13B.
[0042]
On the other hand, with this operation, the eject button 9 is pushed further forward. Further, the protruding portion 13d abuts on the protruding portion 12b and receives rotational resistance from the protruding portion 12b. However, since the insertion force exceeds, the elastic beam 12c is bent and the protruding portion 13d gets over the protruding portion 12b.
[0043]
When the insertion is further advanced, as shown in FIG. 9C, the plate-shaped storage medium 40 comes into contact with the back-side locking portion 2b, reaches a predetermined insertion position on the back-side, and the plate-shaped storage medium 40 The rear end portion is accommodated so as to be substantially within the opening portion 11. At this time, if the left and right sides are reversed, the back side locking portion 2b and the erroneous insertion preventing projection 2c cannot be inserted up to a predetermined position on the back side. I understand that.
At this time, since the locking recess 40i in which a part of the side portion 40f is missing in the width direction is located at the position of the lower tip surface 13B, the lower tip surface 13B rotates in the right direction in the drawing and is locked. It enters into the recess 40i. And 13 C of press surfaces contact | abut to the near wall surface of the latching recessed part 40i. At this time, the lower end surface 13B is in a positional relationship so as to face in a direction substantially parallel to the insertion / removal direction.
Therefore, when the slide shaft hole 2j (12a) is wide on the right side in the width direction, the rotary lever 13 is further pressed to the right side in the figure, and the wall surface in the width direction between the lower tip surface 13B and the locking recess 40i is different from the illustration. It is also possible to engage deeply in the width direction by being in a positional relationship so as to abut.
[0044]
At this time, the protruding portion 13d is in a positional relationship to be locked to the protruding portion 12b from the right side in the figure. Therefore, the rotation lever 13 is in a state in which the rotation is restrained by the locking recess 40 i and the protrusion 12 b.
In such a state, if the plate-shaped storage medium 40 is pulled out and pulled out, first, the rear end of the plate-shaped storage medium 40 is inserted into the opening 11 so that it is grasped by hand. It cannot be pulled out. Secondly, if the rear end is grasped by some means, it can be pulled out as long as the width of the locking recess 40i allows, but beyond that, the locking claw 13b enters the locking recess 40i in a hook shape. Therefore, it cannot be pulled out unless the rotary lever 13 is rotated. Since the rotary lever 13 is locked on the side having a steep slope or a shape that gently engages the protrusion 12b, it can be pulled out unless a relatively large force is applied. Can not.
In this way, the insertion of the plate storage medium 40 is completed, and the insertion state is maintained.
[0045]
Next, in order to remove the plate-shaped storage medium 40, as shown in FIG. 9D, the button portion 9a is pushed into the back side in the insertion / removal direction. That is, the engaging pin 9c is pushed inward, and a pressing force that rotates the rotating lever 13 clockwise is applied. Then, the elastic beam 12c is bent and the protrusion 13d gets over the protrusion 12b and starts rotating.
In parallel with this, the pressing surface 13 </ b> C presses the locking recess 40 i toward the front side in the insertion / removal direction, and urges a pressing force for removing the plate-shaped storage medium 40. At that time, the lower front end surface 13B tries to rotate inside the locking recess 40i, and a pressing force is generated in a direction away from the plate-shaped storage medium 40 in the width direction (left side in the drawing).
[0046]
In such a case, if the lower tip surface 13B enters the inner side of the locking recess 40i to a certain extent, the locking recess 40i and the lower tip surface 13B cannot interfere with each other and cannot be detached. In the conventional mechanism in which the position of the rotary shaft 13a is fixed, the lower end surface 13B has to enter a shallow position with respect to the locking recess 40i.
On the other hand, in the present embodiment, when such a pressing force is applied, the slide shaft hole 2j (12a) can move in the width direction. By retracting in the direction, it can be smoothly detached from the locking recess 40i. Therefore, unlike the prior art, there is no need to reduce the meshing with the locking recess 40i, so there is an advantage that the pressing force of the pressing surface 13C can be reliably transmitted to the locking recess 40i.
At this time, even if the rotation lever 13 moves in the width direction, the engagement pin 9c can move in the slide groove 13c. Therefore, the engagement with the engagement pin 9c is the rotation of the rotation lever 13 and the movement in the width direction. Does not hinder. Also in this point, the operation is smooth.
[0047]
Thus, until the lower front end surface 13B is retracted to the outside of the left outer restricting surface 2A, the plate-like storage medium 40 is urged by the pressing force in the removal direction. In this state, since the plate-shaped storage medium 40 is not in contact with the terminal 8a, it can be easily inserted / removed by holding the portion protruding outward from the opening 11 in the hand.
When the plate-shaped storage medium 40 is removed, the rotary blocks 10A and 10B are moved to positions where the arm portion side surface 10h before insertion is advanced into the insertion path of the plate-shaped storage medium 40 by the action of the spring portion 10f. It is what has been pushed back.
In this way, removal of the plate storage medium 40 is completed. As described above, in the present embodiment, the plate-shaped storage medium 40 can be reliably removed by an easy operation of pushing the button portion 9a.
[0048]
Next, with reference to FIGS. 10 and 11, an operation for inserting and removing the plate-like storage medium 50 will be described. However, since it is performed in substantially the same manner as the insertion / removal operation of the plate-shaped storage medium 40, the points different from the above will be briefly described.
[0049]
The plate-shaped storage medium 50 is inserted from the opening 11 with the back surface 50e facing upward. At this time, as shown in FIG. 5A, in the height direction, the front surface 50h and the back surface 50e are regulated by the lower surface regulating surfaces 10a and 10a and the substrate lower surface 8c, and the width direction is also increased. By being position-regulated by the left inner regulating surface 2D and the right inner regulating surface 2E, it can be inserted with a predetermined positional accuracy.
At this time, in the actual insertion, the plate-shaped storage medium 50 may be inserted with an inclination with respect to the opening portion 11. For example, the corner portion 50m (see FIG. 13) presses the rotating blocks 10A and 10B to There is also a risk of rotating.
In the present embodiment, since the inclined surfaces 10c and 10d provided on the rotary blocks 10A and 10B are provided, the plate-shaped storage medium 50 slides along these inclinations, and as insertion proceeds. It is guided to a predetermined position regulation surface.
[0050]
In the initial stage of insertion, for example, the rotary block 10A, 10B can be easily rotated because it can be inserted while being inclined from the upper side to the lower side with respect to the opening portion 11. However, as the insertion proceeds, the inclination of the plate-like storage medium 50 gradually approaches a horizontal posture as it is regulated by the position regulating surface such as the cover ceiling surface 4a, so that the contact angle with the rotary blocks 10A and 10B becomes small. It becomes easy to slip on the inclined surfaces 10c and 10d. Then, the rotating blocks 10A and 10B are returned to their original positions orthogonal to the insertion direction by the spring portion 10f and can be regulated.
[0051]
In order to perform smoother and more reliable insertion, the elastic force of the spring portion 10f is increased to the extent that the insertion of the plate-like storage medium 40 is not hindered, and further toward the back in the insertion direction of the inclined surfaces 10c and 10d. It is preferable that the slope gradually increases and the shape is easy to slip over even if the corner portion 50m hits. In addition, it is preferable that the inclined surface 10c is widely exposed to the opening 11 side, and it is preferable to reduce the dimension h in FIG. 6 as much as possible.
[0052]
As described above, when the plate-shaped storage medium 50 is inserted, even if the rotary blocks 10A and 10B do not rotate or rotate, the arm portion 10X advances below the insertion path of the plate-shaped storage medium 50 at an early stage of insertion. After that, the position is maintained in the whole insertion / removal process. Therefore, in FIG. 10, 11, illustration of those is abbreviate | omitted.
[0053]
As shown in FIG. 10A, when the insertion is advanced, the tip surface 50c comes into contact with the pressing surface 13C on the upper side of the locking claw 13b, and the locking claw 13b is rotated counterclockwise.
Then, as the insertion proceeds, as shown in FIG. 10B, the rotating lever 13 is further rotated so that the upper end surface 13A comes into contact with the side portion 50f.
Further, as shown in FIG. 11C, the erroneous insertion preventing projection 2a reaches a predetermined insertion position where it enters the locking groove 50g, and the rear end portion of the plate-like storage medium 50 fits in the substantially opening portion 11. Stored.
At this time, the wall surface on the near side of the engaging recesses 40i and 50j in the insertion / removal direction is aligned at substantially the same position, so that when the rotation lever 13 has substantially the same angle as the position where the plate storage medium 40 is inserted. In addition, the upper tip surface 13A enters the locking recess 50j. And 13 C of press surfaces contact | abut to the near wall surface of the latching recessed part 50j. Then, the protrusion 13d is engaged with the protrusion 12b, and the rotation of the rotation lever 13 is suppressed.
In this way, the insertion of the plate storage medium 50 is completed, and the insertion state is maintained.
[0054]
Next, in order to remove the plate-shaped storage medium 50, as shown in FIG. 11D, the button surface 9C is pushed into the back side in the insertion / removal direction so that the pressing surface 13C is moved to the plate-shaped storage medium. The upper end surface 13A is retracted in a direction away from the plate-shaped storage medium 50 in the width direction.
In this way, the plate-like storage medium 50 can be removed.
[0055]
As described above, according to the plate-shaped storage medium holder according to the embodiment of the present invention, the width, thickness, and depth dimensions of the plate-shaped storage medium 40 and the plate-shaped storage medium 40 are different from each other. An ejector unit that inserts the plate-shaped storage medium 50 having a shape included in the occupied volume from a common opening and holds the insertion state in an undrawn state, and has a mechanism common to all the plate-shaped storage media 3 can be easily removed by pushing in the eject button 9 that is linked to 3.
At that time, the openings are formed so that the cross-sections perpendicular to the insertion / removal direction overlap each other, so that the cross-section perpendicular to the insertion / removal direction can be made relatively small and can be thinned. It can be a holder.
Further, in the ejector portion 3, by rotating and supporting the rotary lever 13 so as to be movable in the width direction, the locking claw 13b can be engaged relatively deeply into the locking recesses 40i and 50j. Regardless, it is possible to move away smoothly from it, and to maintain the insertion state stably and improve the operability of removal.
[0056]
In the above description, the positions of the locking recesses 50j and 40i are described as being substantially overlapped in the width direction in the insertion / removal direction. However, the positions of the upper tip surface 13A and the lower tip surface 13B are appropriately changed. Then, even if the positions of the locking recesses 50j and 40i in the insertion / removal direction width direction are different, the same operation can be performed. Therefore, the present invention can also be used when the shape of the holding groove, the insertion position in the width direction, and the like are different.
[0057]
In the above description, the upper tip surface 13A and the lower tip surface 13B are described as being provided with steps in the vertical direction. However, when the shape of the holding groove penetrates in the thickness direction. Can also employ a holding claw having no step in the vertical direction by aligning the vertical positions of the holding grooves.
[0058]
In the above description, the plate storage medium 40, 50 has been described as an example of the plate storage medium in the above description. However, this is an example, and these and dimensions are within the scope of the technical idea of the present invention. Needless to say, the relationship may be different.
[0059]
In the above description, the rotary block is a movable position restricting member that moves forward and backward in the insertion path of the plate storage medium to form a position restricting surface according to the shape of the plate storage medium, and is held movably. Therefore, it has been described that the elastic force is urged by the spring portion integrated with the rotating block. Then, there is an advantage that the device can be manufactured at a low cost with a small number of parts.
On the other hand, it is good also as a structure which removes the shape of a spring part and attaches the elastic member which can urge an elastic force similarly to a spring part to a rotation block. As the elastic member, for example, a metal torsion coil spring or a leaf spring can be preferably used. For example, the rotating block is made of synthetic resin, and these elastic members can be locked, caulked, or press-fitted. If it does so, even if the rotation frequency of a rotation block is high, there exists an advantage that the reliable apparatus which has high durability can be comprised.
[0060]
【The invention's effect】
As described above, according to the first aspect of the present invention, even in the case of a plate-shaped storage medium having a different shape, in particular, a shape having a slightly different width in the insertion / extraction direction, each insertion / extraction is overlapped in the vertical direction. Since the cross-sections in the direction can be inserted and removed from the common opening in a positional relationship, the movable dimension can be reduced in the thickness direction and moved forward and backward in the holding groove on the side of the plate storage medium By providing the portion, even if the depth of the holding groove and the position in the depth direction are different, it is possible to reliably and easily hold and remove the plate-shaped storage medium with a common attachment / detachment mechanism.
[0061]
In the invention according to claim 2, even if the holding claw provided at the end of the rotary arm member changes the depth of the holding groove depending on the type of the plate-shaped storage medium, the holding claw advances according to the change. Therefore, a reliable pressing force can be applied to the plate-shaped storage medium when it is removed, and the movement of the rotary arm member and the movement away from the side by the shaft guide mechanism can be performed simultaneously. Thus, the engagement can be released smoothly. As a result, the insertion / removal operation can be performed reliably and smoothly, and the operability can be improved.
[0062]
According to the third aspect of the invention, since the parts can be shared, there is an effect that the apparatus can be made inexpensive.
[0063]
In the invention according to claim 4, since the occupied area in the width direction can be reduced, there is an effect that the size can be further reduced.
[0064]
In the invention according to claim 5, a plurality of types of plate-like storage media that are mechanically and electrically different can be obtained by providing a connector and making the plate-like storage medium holder detachable from other devices. On the other hand, there is an effect that it is possible to provide a versatile connection adapter having connection compatibility.
[Brief description of the drawings]
FIG. 1 is an explanatory perspective view for explaining a plate-shaped storage medium holder according to an embodiment of the present invention.
FIG. 2 is an explanatory plan view for explaining a casing that forms the base of the holder for the plate-like storage medium of the present embodiment.
FIG. 3 is an explanatory plan view and a BB cross-sectional view for explaining a plate-shaped storage medium storage portion of the plate-shaped storage medium holder of the present embodiment.
FIG. 4 is a schematic explanatory view in a plan view and a side view for explaining a positional relationship when plate-shaped storage media having different shapes are respectively inserted into the plate-shaped storage medium holder of the present embodiment.
FIG. 5 is an explanatory side view showing a state in which plate-shaped storage media having different shapes are inserted as viewed from the direction A shown in FIG. 1;
FIGS. 6A and 6B are a plan view and a front view for explaining the shape of the rotating block according to the embodiment of the invention. FIGS.
FIG. 7 is an exploded perspective view for explaining a movable engagement portion according to the embodiment of the present invention.
FIG. 8 is a partial explanatory view in plan view for explaining a schematic operation of inserting and removing one of the plate storage media into the plate storage medium holder according to the embodiment of the present invention.
FIG. 9 is a partial explanatory view in plan view for explaining the schematic operation similarly following FIG. 8;
FIG. 10 is a partial explanatory view in plan view for explaining a schematic operation for inserting and removing the other plate storage medium from the plate storage medium holder according to the embodiment of the present invention.
11 is a partial explanatory view in plan view for explaining the schematic operation similarly following FIG. 10; FIG.
FIGS. 12A and 12B are a back view, a left side view, and a plan view for explaining an example of a conventionally used plate-shaped storage medium.
FIG. 13 is a plan view, a right side view, and a back view for explaining another example of the plate-like storage medium.
[Explanation of symbols]
1 Holder for plate-shaped storage media
2j, 12a Slide shaft hole (shaft guide mechanism)
3 Ejector part (movable engagement part)
4 Cover
5 Plate-shaped storage medium storage
7 Connector
8 Board
9 Eject button (withdrawal operation part)
9c Engagement pin (engagement mechanism)
11 opening
12b Projection
13 Rotating lever (Rotating arm member)
13a Rotating shaft
13b Locking claw (holding claw)
13c Slide groove (engagement mechanism)
13d protrusion
13A Upper tip surface
13B Lower end surface
13C pressing surface
14 Coil spring (elastic member)
20A, 20B Guide plate
40 Plate storage medium (first plate storage medium)
40i, 50j Locking recess
50 Plate-shaped storage medium (second plate-shaped storage medium)

Claims (5)

Plural types of plate-shaped memory having terminals on one side of the front and back surfaces, holding grooves for holding the position in the insertion / removal direction in a predetermined range on the side portion with respect to the insertion / removal direction, and different external shapes A plate-shaped storage medium holder for detachably storing a medium,
A plurality of types of plate-shaped storage media, a plate-shaped storage medium storage unit capable of storing the plurality of types of plate-shaped storage media at respective positions such that cross sections perpendicular to the insertion / removal direction overlap each other;
A movable position restricting member that is provided in the plate- shaped storage medium storage unit and that moves forward and backward in the insertion path of the plurality of types of plate-shaped storage media to form a position-regulating surface according to the shape of the plurality of types of plate-shaped storage media. When,
From the side of the plate-shaped storage medium storage unit, it is provided so as to be able to advance and retreat into the respective holding groove, and when moving forward, the plate-shaped storage medium is held in the plate-shaped storage medium storage unit in a state where it is difficult to pull out. When retreating, it is possible to retreat to the outside of the holding groove while urging the holding groove with a pressing force for removing the plate storage medium, and to the side of the plate storage medium in the insertion / removal direction. A movable engagement portion movable in a direction of approaching and separating along the width direction of the plate-shaped storage medium that intersects the insertion / removal direction;
A plate-shaped storage medium holder comprising: an extraction operation unit that transmits a pressing force to the movable engagement unit to extract and extract the plate-shaped storage medium. The plate-shaped storage medium holder according to claim 1,
The movable engagement portion is
A holding claw provided at an end portion for engaging with the holding groove, an engagement mechanism for engaging with the removal operation portion, and a direction for removing the holding claw from the holding surface A rotating arm member having a rotating shaft to be rotated,
An axis guide mechanism that allows the rotation axis of the rotary arm member to move in a direction in which the rotation axis of the rotary storage member comes into contact with or separates from the side in the insertion / removal direction of the plate-like storage medium
A holder for a plate-shaped storage medium, comprising: an urging means for urging the rotating arm member with an elastic force in a direction in which the rotation shaft approaches the side portion of the plate-shaped storage medium. The holder for a plate-like storage medium according to claim 2,
The holder for a plate-shaped storage medium, wherein the biasing means also serves as a means for biasing a pressing force for removing the plate-shaped storage medium. In the holder for plate-shaped storage media in any one of Claims 1-3,
The plate-like storage medium retract and section,
A plate-shaped storage medium having a relatively large longitudinal width and a plate-shaped storage medium having a relatively small longitudinal width as viewed from the insertion / removal direction are inserted from a common opening,
A plate-shaped storage medium holder, wherein the plate-shaped storage medium having a relatively small width is disposed within the longitudinal width of the plate-shaped storage medium having a relatively large width. In the plate-shaped storage medium holder according to any one of claims 1 to 4,
A connector electrically connected to each of the inserted plate-shaped storage media, and a device having a mating connector connectable to the connector is detachable via the connector. Holder for plate-like storage medium.

Images