KR101125273B1 - Expandable and collapsible peripheral device - Google Patents

Abstract

Expandable and collapsible peripherals and methods of manufacturing the same are disclosed. When in the extended state, the length of the peripheral conforms to the ExpressCard standard. When in the folded state, the peripheral's form factor is approximately equal to the form factor of the CompactFlash card. The peripheral device of the present invention may operate in accordance with standards other than the ExpressCard standard, and may have an extended state and a folded state size independent of the ExpressCard and / or CompactFlash card.

Peripheral, Host, ExpressCard Standard, CompactFlash Card

Description

Expandable and Collapsible Peripherals {EXPANDABLE AND COLLAPSIBLE PERIPHERAL DEVICE}

Embodiments of the present invention relate to an expandable and collapsible peripheral device and a method of manufacturing the peripheral device.

As the demand for portable electronics increases, the demand for mass storage devices also increases. Nonvolatile semiconductor memory devices, such as flash memory storage cards, are widely used to meet the ever-increasing demands associated with digital information storage and exchange. Their portability, versatility, and robust design, along with their high reliability and mass storage capabilities, make these memory devices suitable for a variety of electronic devices, including digital cameras, digital music players, video game consoles, PDAs, and mobile phones. Ideal to be used.

One of the most popular flash memory device is a compact flash ^{(CompactFlash?)} Memory cards produced by SanDisk Corporation, located in Milpitas (milpitas) the State of California. The compact memory card is used in various fields and has been adopted as a de facto standard in the professional and consumer video market. There are many reasons why a compact memory card has been adopted as the de facto standard, but the form factor of a compact memory card is of significant importance, including its large storage capacity and its low cost per megabyte. It turned out to be a factor. A card size of 43 mm x 36 mm is large enough to be easily handled and small enough to be conveniently carried and used in current high resolution digital cameras. Professionals and consumers are accustomed to this size of memory cards and are convenient to use.

Several years ago, Personal Computer Memory Card International Association: member of the (PCMCIA Personal Computer Memory Card International Association ) have developed the ExpressCard peripherals for the new standard for PC ^cards? Compared with past PC Cards, ExpressCards use simple connectors and do not use traditional PC Card controllers by connecting directly to PCI-Express and USB ports within the host device. As a result, the transmission speed is faster, the performance is improved, and the price is lower for the card slot implementation in the host system than the conventional PC card.

Given these points, there is a technical and business reason for the continued popularity of the ExpressCard standard. Standard ExpressCards come in two sizes: ExpressCard / 34 is 75 mm x 34 mm and ExpressCard / 54 is 75 mm x 54 mm. All of these are quite large compared to CompactFlash cards. Consumers and professionals who are familiar with the CompactFlash form factor are lukewarm in adopting the ExpressCard standard. Thus, it would be desirable to provide a peripheral that can be used in accordance with the ExpressCard standard while having the size, appearance, and feel of a CompactFlash card.

Briefly describing the present invention, the present invention relates to an expandable and collapsible peripheral device and a method of manufacturing the peripheral device. According to one embodiment, the length of the peripheral device of the present invention in the expanded state conforms to the ExpressCard standard, and the form factor of the present invention in the folded state is about the same as the form factor of the CompactFlash card. The peripheral device of the present invention includes an outer cover in which a hollow inner space is formed, in which the semiconductor card and the actuation system are accommodated. A connector for transferring signals between the card and the host device to which the peripheral device is connected is provided at the front end of the peripheral device of the present invention.

The actuation system generally includes a mechanical release, a bias mechanism and a locking mechanism. Generally, the deflector deflects the peripheral device into an expanded state. In one embodiment, the deflector may comprise a pair of springs wrapped around the telescoping rod. The spring has a compressive force and has a first end that is biased against the card and a second end that is biased against the rear end of the lid to bias the components against each other. In one embodiment, the deflector is loaded so that when the mechanical release device is actuated, the peripheral device of the present invention quickly snaps and moves completely from the folded state to the expanded state. Other mechanical arrangements for biasing the lid and card against each other can also be considered.

A mechanical release device is provided to keep the peripheral device folded against the biasing force of the deflector. In embodiments, the mechanical release device may be securely attached to the cover and may include a clasp to engage a lip formed in the front portion of the card. When the mechanical release device is pressed downwards, the latch releases the lip so that the card can be deflected by the deflector and moved away from the lid. Other mechanical arrangements are also conceivable that can removably secure the lid and card together.

In embodiments, the mechanical release device may be manually operated by the user of the peripheral device, or may be automatically activated when the peripheral device is inserted into a slot of the host device. In an automatically expanding embodiment, the device is provided within a peripheral device and / or host device so that the device is only expanded when used in an elongate slot sized to accommodate the expanded peripheral device (such as, for example, an ExpressCard slot). do. In one embodiment, the upper surface of the slot is in contact with the mechanical release device when the peripheral device is inserted so that the mechanical release device can be automatically activated when the peripheral device is inserted into the elongated slot. By providing a channel to receive the mechanical release device when the peripheral device is inserted into the host device slot, the same peripheral device can be inserted into the compact host device slot without expansion. Thus, within the compact device slot, no part of the slot is in contact with the mechanical release device and the peripheral device remains folded. Other mechanical devices may be contemplated that extend the peripherals when used in an elongated slot and allow the peripherals to be folded when used in a compact slot.

Once the peripheral device is expanded, a lock can be provided that allows the peripheral device to remain in its extended state while being pressed to mate with the host device slot. In one embodiment, the locking device may include a pair of levers capable of rotating around each pin mounted in the cover. Each lever may comprise a first end provided along the side of the card and a second end having a button. A spring may be wrapped around the pins to bias the first end against the side of the card.

When in the folded state, the locking device ensures that the expansion of the card does not interfere with the lid. However, if the card extends past the first end of the lever, the first end of the lever rotates inward, blocking the first end from preventing the card from returning to the folded state. As the first end rotates inward, the buttons at the opposite end rotate outwardly and project through an opening formed in the lid. After the peripheral device is ejected from the host device slot, the buttons may be pressed inward so that the first end is away from the card. This operation allows the user to manually slide the lid back over the card against the biasing force of the deflector until the mechanical release device in the folded state again locks the peripheral. In the expanded state, other mechanical devices can also be considered that can secure the peripheral device in a releasable manner.

The peripheral device of the present invention may operate within an ExpressCard slot, and in the expanded state, the peripheral device may be about 75 mm long and about 34 mm wide. In the above embodiment, the peripheral device can operate with another conventional ExpressCard. However, when not in use in the ExpressCard slot, the peripheral device may be folded, with a length of about 40 mm to 45 mm and a width of about 34 mm. This size is about the same as a typical CompactFlash card. Thus, users who are accustomed to the size, look and feel of a typical CompactFlash card can continue to use peripherals that match the size of their digital camera, video camera or other devices. At the same time, you can enjoy the benefits of the ExpressCard interface. The peripheral device of the present invention may operate in accordance with standards other than the ExpressCard standard, and may have an expanded state and a folded state size independent of the ExpressCard and / or CompactFlash card.

1 is a plan view of a peripheral device in a folded state in accordance with one embodiment of the present invention.

2 is a front view of a peripheral device according to an embodiment of the present invention.

3 is a side view of a peripheral device in a folded state in accordance with one embodiment of the present invention.

4 is a top view of a peripheral device in an expanded state in accordance with one embodiment of the present invention.

5 is a plan view of the interior of a peripheral device in a folded state in accordance with one embodiment of the present invention.

6 is a plan view of the interior of a peripheral device in an expanded state in accordance with one embodiment of the present invention.

7 is a perspective view of a peripheral device inserted into an elongated host device slot according to one embodiment of the invention.

8 is a perspective view of a peripheral device inserted into a compact host device slot according to one embodiment of the invention.

9 is a plan view of the interior of a peripheral device in a folded state according to another embodiment of the present invention.

10 is a plan view of the interior of a peripheral device in an expanded state in accordance with another embodiment of the present invention.

Embodiment

Embodiments of the present invention relating to expandable and collapsible peripherals and methods of manufacturing the same are described with reference to FIGS. It is to be understood that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided to assist those skilled in the art in a more complete understanding of the invention. Indeed, the present invention is intended to cover equivalent, modified, and modulated ranges of these embodiments, and these equivalent, modified, and modulated ranges fall within the scope and spirit of the present invention as defined in the claims of the present invention. Belong. In addition, in the detailed description of the present invention, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, it will be apparent to one skilled in the art that the present invention may be practiced without these specific details.

1 to 3 show the peripheral device 100 in its folded state. The device 100 may include a front end 102 and a rear end 104, as shown in the figure. 1 shows an outer cover 106 that serves as an enclosure for the card and actuation system as described below. The lid 106 may be formed of metal, plastic or various other materials and may include walls that define a hollow space surrounding the card and the actuation system. The rear end 104 may have a finger grip 108 at the top and / or bottom of the cover. By holding the cover 106 and the peripheral device 100 through the finger grip, the peripheral device can be inserted and removed. In an embodiment of the invention, finger grip 108 may be omitted.

2 shows the connector 110 formed at the front end 102 of the peripheral device. The connector 110 is for transferring signals between the host device and the card to which the peripheral device 100 is connected. Connector 110 may be a 26-pin, beam-on-blade type connector used in the ExpressCard standard, and other types of connectors may be contemplated.

As can be seen from FIGS. 1 to 4, the peripheral device 100 also includes a mechanical release device 112 that allows the peripheral device 100 to move in the expanded state shown in FIG. 4 in a folded state. can do. This will be described in detail below. The mechanical release device 112 is shown positioned adjacent to the front end 102 at the top surface of the peripheral device 100, but as described below, in other embodiments, one side edge or both side edges may be used. And / or adjacent the rear end 104.

In the expanded state shown in FIG. 4, the card 114 is shown extending from the lid in the lid 106. Card 114 may be a variety of semiconductor devices including integrated circuits, and may include such semiconductor devices. In one embodiment, the card 114 may be, for example, a flash memory module that reads data from and / or inputs data from a host device to which a peripheral device is connected via the connector 110. In another embodiment of the present invention, it should be understood that the card 114 may be various other semiconductor devices. The semiconductor elements of the card 114 (such as the semiconductor die 126 and the passive components 128 shown in phantom in FIGS. 5 and 6) may be enclosed in a card protection housing 116 as shown in FIG. 4. Can be. Card housing 116 may be, for example, a plastic cover molded around semiconductor elements, or may be another type of cover. Since current semiconductor devices can store and process large amounts of data in a small form factor, the card 114 is formed in the lid 106, leaving free space for the actuation system as described below. It can occupy only part of the space it is in.

Although not shown in the figures, each of the front portion of the lid 106 and the rear portion of the card housing 116 (adjacent to each other in the expanded state shown in FIG. 4) has the card 114 completely out of the lid 106. It may be formed of lips engaged with each other so as not to separate. Those skilled in the art will know another mechanism to ensure that card 114 is not completely removed from lid 106 when peripheral 100 is in the extended state.

5 and 6, an embodiment showing a process of moving between the folded state and the expanded state of the peripheral device 100 will be described. The actuation system may generally include a mechanical release device 112, a deflection device 120, and a locking device 122, each of which is described in detail below. The deflector 120 and the lock 122 are shown to occupy most of the virtual line, which is enclosed within the cover 106. Hereinafter, various embodiments of each of the mechanical release device 112, deflector 120 and lock 122 will be described, although those skilled in the art will appreciate that the peripheral device 100 can be moved and maintained between the extended and folded states. You may also be aware of other mechanisms for doing so.

In general, the deflector 120 may deflect the peripheral device 100 in an expanded state. The deflector 120 shown in FIGS. 5 and 6 includes a pair of springs surrounding the telescoping rod. The rod has an opposite end attached to the rear end of the lid 106 and the rear end of the card housing 116. The spring is mounted under compression and has a first end biased relative to the card housing 116 and a second end biased relative to the rear end of the lid 106. The length of the spring and the spring constant of the spring may vary depending on the embodiment. However, in one embodiment, the deflection device 120 applies a load when the mechanical release device is actuated, as described below, so that the peripheral device 100 is quickly snapped and fully extended from the folded state. Let's move. The load may be sufficient for the user to feel or hear that the peripheral device 100 is extended to an expanded state, or may be enough to hear while feeling, and the user grips on the peripheral device 100 in an inflated state. It might be big enough to miss it.

Although two springs and rods are shown, in another embodiment only one or more may be provided. In yet another embodiment, the springs and rods may be closer to or farther from the side of the lid 106. Although a pair of helical springs are shown wrapped around the telescoping rod, another known deflector 120 that, when the mechanical release device 112 is actuated, causes the peripheral device to move from the folded state to the expanded state. Should be understood.

The mechanical release device 112 maintains the peripheral device 100 in a folded state against a deflection force by the deflection device 120. In an embodiment, the mechanical release device 112 may be attached to the lid 106 and is formed in a lip formed in the front of the card 114 (in the card housing 116 or in the card housing 116). And clasps 130 (FIG. 3) capable of fastening, which are formed within components attached to them. When the mechanical release device is pushed down, as the latch 130 releases the lip, the card 114 is subjected to the biasing force of the deflector 120 to be released from the cover 106 to an expanded state.

In an embodiment, the mechanical release device 112 may be manually operated by the user of the peripheral device 100, or may be automatically activated by inserting the peripheral device 100 into the host device. As described above, in the automatic expansion embodiment, the mechanisms are provided in the peripheral device 100 and / or the host device so that the peripheral device has a slot size that accommodates the expanded peripheral device (as in the embodiment within the ExpressCard slot range). ) To be expanded when used.

In embodiments in which the mechanical release device 112 is operated manually, when the mechanical release device 112 is located near the front end 102 of the device, the mechanical release device 112 causes the peripheral device to enter the host device slot. Prior to loading, the user can actuate the mechanical release device 112 by pressing it. However, as described above, the mechanical release device need not be located near the front end 102. Those skilled in the art will appreciate that the mechanical release device may be located at various points on the peripheral device 100 to function to fasten the cover 106 to the card 114.

For example, the mechanical release device may be located adjacent to the rear end 104. In such embodiments, the mechanical release device 112 may be activated by the user pressing the mechanical release device during or prior to inserting the peripheral device into the host device slot. In an embodiment, the mechanical release device may be located on the side of the cover 106, on the bottom surface of the cover 106, or on the rear surface of the cover 106 at the rear end 104. Although only one mechanical release device is shown, it may also be located at an opposite point on the lid 106 such that the mechanical release device can be manually operated with the same and opposing force. In addition, although the mechanical release device is described as including a clasp 130 that engages a lip on the card 114, various other clasp devices may be used to release the engagement when the mechanical release device is in operation. It should be understood that it may.

As mentioned above, the mechanical release device 112 may operate automatically. In this embodiment, the peripheral device should be automatically expanded only when used as an elongated peripheral and used as an expandable peripheral, and not when used as a folding peripheral in a compact sized slot. As described below, a trigger device that automatically expands or does not expand the peripheral device may be provided in the host device slot or in the peripheral 100 itself.

7 and 8 illustrate embodiments in which a trigger device is provided in the host device slot that automatically expands or does not expand the peripheral. In particular, FIG. 7 shows an elongated slot 150. Slot 150 may be an ExpressCard slot, but in other embodiments may not be an ExpressCard slot. In this embodiment, the mechanical release device 112 is inclined upward from the front to the rear so that the rear portion of the mechanical release device 112 protrudes above other portions of the peripheral device 100. The relative size of the slot 150 and the peripheral device 100 is such that when the peripheral device 100 is inserted into the slot 150, the inclined portion of the mechanical release device 112 engages the surface 152 of the slot 150. Is provided. As the peripheral device 100 is continuously inserted, the surface 152 urges the inclined portion of the mechanical release device 112 so that the peripheral device is extended in an expanded state. In FIG. 7, the front edge of the surface 152 is illustrated as fastening and squeezing the mechanical release device 112, but the height of the front portion of the slot 150 is slightly larger and gradually narrowed toward the rear portion. It should be understood that it may. When using this form, the front end 102 of the device will enter the slot 150 a little while the mechanical release device 112 will be fastened by the surface 152.

The peripheral device may be used in a compact slot in another form, such as slot 156 shown in FIG. Slot 156 may be a slot in an imaging device such as a digital camera or a video camera, and in other embodiments, slot 156 may be a slot in various other host devices. Slot 156 is formed with a channel 158 that is aligned to receive mechanical release device 112 as peripheral device 100 is inserted into slot 156. Slot 156 and channel 158 are sized such that they do not engage mechanical release 112 during insertion of peripheral device 100. Thus, the mechanical release device 112 is not actuated and the peripheral device remains folded. Those skilled in the art will appreciate another form of slot 156. For example, instead of the channel 158, the height of the slot 156 may extend throughout the slot width, such that when inserting a peripheral device, no portion of the mechanical release device 112 may engage with the slot. . Such an embodiment may operate with a guide that allows the connector 110 to be in the proper position in terms of mating with the connector in the slot 156.

As discussed above, the mechanical release device 112 may be located at another point on the cover 106. Slot 156 is one that corresponds to the position (s) of mechanical release device (s) 112 such that in such embodiments the mechanical release device 112 is not engaged when the peripheral device is inserted into slot 156. Or more channels 158.

Another embodiment in which some other device is provided in the peripheral device 100 and / or host device slots as the trigger extends or does not expand the peripheral device, although physically identical to the elongated and compact slots. Can be considered. For example, the mechanical release device 112 and the deflection device 120 can be replaced with an electrical device that can be at least partially provided in the interior space defined by the cover 106. For example, the drive system includes a small motor that rotates a lead screw, gear train or motion transfer system. The motor can be operated by inserting a peripheral device into an elongated slot (e.g., by installing an electrical contact on the peripheral device that connects to the host device power source when the peripheral device is inserted). In operation, the drive system can operate the peripheral device in an extended state.

Still other embodiments may be envisioned where solenoids may be used in the lid 106. The solenoid may drive the peripheral device in an extended state or at least operate a mechanical release device to cause the deflector to move the peripheral device in an extended state. In yet other embodiments, metal balls, pins or switches may be located within the lid 106. The ball / pin / switch may move between a first position that prevents the operation of the mechanical release device 112 and a second position that does not prevent the operation of the mechanical release device 112. In such embodiments, the host device slot may include a magnet that places the ball / pin / switch in the desired first or second position when the peripheral device is inserted into the slot. Those skilled in the art will appreciate that there are other types of trigger devices that selectively expand or do not expand peripheral 100.

In the case where the peripheral device automatically expands in accordance with the above-described embodiment, the peripheral device can be fully extended before the connector 110 in the front end 102 reaches the connector in the host device slot that mates with these connectors. In other embodiments, this may not work.

9 and 10 show another embodiment in which the mechanical release device 112 and the deflection device 120 are replaced with slide buttons 160. In this embodiment, the slide button is held in a slot 162 formed within the cover 106 surface and one end of the slide button may be attached to the card 114. As can be seen from FIG. 10, when locked by the locking device 122 as described above, the slide button 160 can be operated to extend the card 114 away from the lid 106.

In another embodiment, instead of the peripherals expanding, the peripherals 100 may be formed to accommodate separate and independent extension pieces (not shown). In this embodiment, the lid 106, the mechanical release device 112 and the deflector 120 may all be omitted. Instead, when used in a compact slot, the card 114 may be used by itself, and when used in an elongated slot, an extension piece may be assembled on the rear end of the card 114 opposite the connector 110. The card 114 and the expansion piece may be sized to fit properly in the elongate slot.

5 and 6, a locking device 122 is provided for securing the peripheral device 100 to the expanded state after the peripheral device 100 is in the expanded state. In particular, after the peripheral device 100 is expanded, the user needs to apply sufficient force on the rear end 104 in order for the connector 110 to properly mate with the corresponding connector in the host device slot. The force exerted by the user may be greater than the force required for proper registration. The lock 122 is provided to allow the peripheral device 100 to remain in an extended state under such a force.

In the embodiment shown in FIGS. 5 and 6, the locking device 122 may include a pair of levers 170 capable of rotating around each pin 172 mounted within the lid 106. Each lever 170 includes a first end 174 provided along one side of the card housing 116 and a second end having a button 176. A spring (not shown) may wrap around the pin 172 to bias the first end 174 laterally to the card housing 116. As can be seen from FIG. 5, when in the folded state, the locking device does not interfere with the expansion of the card 114 relative to the lid 106. However, once card 114 extends past end 174 of lever 170, the lever rotates inward, and end 174 prevents card 114 from returning to the folded state.

As the end 174 rotates inward, the button 176 rotates outward and protrudes through an opening provided in the lid 106. After the peripheral device is ejected from the host device slot, the button 176 is manually pushed inward to move the end 174 out of the card 114. By this operation, the user manually holds the cover 106 against the biasing force of the deflector 120 until the mechanical release device 112 secures the peripheral device 100 in the folded state. You can slide from the top. Instead of the button 176 protruding from the side of the cover 106, the rear end of the lever 170 may extend out of the rear end 104 of the peripheral device 100. In such embodiments, to release the lock, the protrusions can be manually moved inwards towards each other, thereby allowing the peripheral device to be folded away by removing the opposite end 174 from the card 114.

Those skilled in the art will appreciate that there are many other devices in which the peripheral device 100 can be secured in an expanded state, and in the case where the peripheral device 100 is to be folded, the device can move out of the locked position.

In the above embodiments, the peripheral device 100 may be provided in accordance with the ExpressCard standard. In other words, the peripheral device 100 may operate within an ExpressCard slot, and in the expanded state, the peripheral device 100 may be about 75 mm long and about 34 mm wide. The thickness of the device may be between 3 mm and 8 mm and may be 5 mm. In such embodiments, the peripheral device 100 may operate with other conventional ExpressCards. However, when not in use in the ExpressCard slot, the peripheral device 100 may be folded, with a length of about 40 mm to 45 mm and a width of about 34 mm. This size is about the same as a typical CompactFlash card. Thus, users who are accustomed to conventional CompactFlash card sizes can continue to use peripherals that match the size of their digital cameras, video cameras or other devices. At the same time, you can enjoy the benefits of the ExpressCard interface.

Accordingly, embodiments of the present invention provide for compatibility between the ExpressCard standard and the look and feel of CompactFlash cards. However, the peripheral device of the present invention may operate in accordance with standards other than the ExpressCard standard, and may have an extended state and a folded state size independent of the ExpressCard and / or CompactFlash card.

In the above embodiments, the expansion of the peripheral device 100 was made by adding a real estate over the rear end of the device, ie the opposite end of the end 102 comprising the connector 110. This is desirable if no other electrical connections or other parts need to be added to the rear end of the device when expanding the peripheral device. However, in another embodiment, it is also contemplated that a fixed component is added to the front end 102 of the peripheral device. In such embodiments, portions extending between the connector 110 and mating connectors in the host device slot may be added. To ensure proper signal transfer between the peripheral device and the host device, the extension includes a first connector that mates with the connector 110 and a second connector that mates with a connector in the host device slot.

The foregoing detailed description of the invention has been presented to explain and describe the invention. The scope of the invention should not be viewed as being limited to the exact same form as the form disclosed above. In light of the above teachings, many variations and modulations may be made. In order to best explain the principles and practical uses of the invention, the foregoing embodiments are selected to enable those skilled in the art to make various modifications to adapt the invention to various embodiments and to be particularly suited to the particular application. The claims of the present invention are defined in the claims.

Claims (16)

A peripheral device comprising an enclosure defining a hollow interior space and a card having an integrated circuit in communication with one or more host devices, the peripheral device having the card located in the interior space defined by the enclosure. As a manufacturing method, From a first position relative to the card in the enclosure, where the enclosure and the card are assembled in a first slot having a first depth, the enclosure and the card are assembled in a second slot having a second depth different from the first depth. And (a) mounting the enclosure to the card such that the length of engagement of the enclosure and the card changes as the enclosure and card move from the first position to the second position. Characterized in that the peripheral device manufacturing method. The method of claim 1, further comprising the step (b) of deflecting the enclosure to a second position relative to the card. 3. The method of claim 2, further comprising the step (c) of releasably holding the enclosure in a first position relative to the card. 2. The method of claim 1, wherein mounting (a) the enclosure to the card comprises slidably mounting the enclosure to the card. The method of claim 1, further comprising: (d) configuring the enclosure to automatically move from a first position relative to the card to a second position when inserting the peripheral device into a host device slot. Peripheral device manufacturing method. A nonvolatile memory peripheral that can operate within one or more host devices. A card having an integrated circuit; A lid coupled slidingly to the card, the lid having four sides surrounding the four sides of the card, the lid and the card having a first length and having a first depth within the slot Moveable between a first position in which the lid and card can be assembled, and a second position in which the lid and card have a second length different from the first length and can be assembled in a slot having a second depth With cover; An actuation system at least partially coupled between the card and the cover such that the cover moves between the first and second positions. Peripheral device comprising a. 7. The peripheral device of claim 6, wherein the first length conforms to an ExpressCard standard. 8. A peripheral device according to claim 7, wherein said second length is approximately the size of a CompactFlash card. 7. A peripheral device according to claim 6, wherein said first length is approximately 75 mm. 10. The peripheral device of claim 9, wherein said second length is approximately 40 mm to 45 mm. 7. A peripheral device according to claim 6, further comprising an actuation system for moving said peripheral device from a first position to a second position. 12. The peripheral device of claim 11, wherein the actuation system comprises one or more springs biasing the lid relative to the card to a second position. 12. The peripheral device of claim 11, wherein the actuation system includes a mechanical release device that releasably holds the lid in a first position relative to the card. 12. A peripheral device according to claim 11, wherein the actuation system comprises a locking device for releasably securing the cover to the card in a first position. 12. The peripheral device of claim 11, wherein said second length is approximately 75 mm. 16. The peripheral device of claim 15, wherein said first length is approximately 40 mm to 45 mm.

Images