Source: http://www.google.com/patents/US7611056?dq=7245279
Timestamp: 2015-04-21 12:41:07
Document Index: 794128512

Matched Legal Cases: ['Application No. 2005', 'Application No. 06219371', 'Application No. 00971781', 'Application No. 2005', 'Application No. 2006', 'Application No. 2003']

Patent US7611056 - IC card connector - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inAdvanced Patent SearchPatentsWhen inserting a MEMORY STICK MS, the tip portion of the MEMORY STICK MS rotates and detrudes the contact pressing plate, so that contact portions of contact terminals 14 ai for a SD card SD are pressed down by a rim of slits 20 ai of the contact pressing plate 20 up to a position where the contact portions...http://www.google.com/patents/US7611056?utm_source=gb-gplus-sharePatent US7611056 - IC card connectorAdvanced Patent SearchPublication numberUS7611056 B2Publication typeGrantApplication numberUS 11/393,860Publication dateNov 3, 2009Filing dateMar 31, 2006Priority dateApr 1, 2005Fee statusPaidAlso published asCN1848541A, CN100517879C, US20060219785Publication number11393860, 393860, US 7611056 B2, US 7611056B2, US-B2-7611056, US7611056 B2, US7611056B2InventorsShigeru SatoOriginal AssigneeYamaichi Electronics Co., Ltd.Export CitationBiBTeX, EndNote, RefManPatent Citations (89), Non-Patent Citations (6), Referenced by (4), Classifications (8), Legal Events (2) External Links: USPTO, USPTO Assignment, EspacenetIC card connector
US 7611056 B2Abstract
When inserting a MEMORY STICK MS, the tip portion of the MEMORY STICK MS rotates and detrudes the contact pressing plate, so that contact portions of contact terminals 14 ai for a SD card SD are pressed down by a rim of slits 20 ai of the contact pressing plate 20 up to a position where the contact portions do not interfere with the MEMORY STICK MS.
1. An IC card connector to be used in common for first and second IC cards of different dimensions via a common card inserting opening, comprising:
a card accommodation portion including a front section for accommodating said first IC card and a rear section formed at a position farther from said card inserting opening than the front section so as to partially overlap with the front section for accommodating said dimensionally different second IC card;
a group of front contact terminals and a group of a rear contact terminals disposed in the front section and the rear section respectively, for electrical connection with said first IC card and said second IC card respectively;
a locking/unlocking mechanism fixed to the IC card connector, and
a contact pressing plate which selectively presses the group of contact portions of the front contact terminals to rotate away from the first or second IC card;
wherein when the first IC card is inserted, the locking/unlocking mechanism retains the contact pressing plate in a first position wherein the contact pressing plate can rotate, but not slide, and
when the second IC card is inserted, the contact pressing plate can slide between the first position and a second position, and
when the contact pressing plate is in the second position, the contact pressing plate can rotate.
2. An IC card connector, comprising:
a multiple card accommodation including a first section for removably accommodating via a common card inserting opening a first IC card out of a plurality of IC cards of mutually different shapes, a second section for accommodating a second IC card, formed at a position farther from the card inserting opening than the first section in a line therewith and partially overlapping therewith, and a third section for accommodating a third IC card, formed at a position still farther from the card inserting opening than the first and the second sections, in a line therewith and partially overlapping therewith;
a group of first contact terminals, a group of second contact terminals and a group of third contact terminals sequentially disposed in a loading/unloading direction of the IC card so as to correspond to the first section, the second section and the third section respectively, for electrical connection with the first IC card, the second IC card and the third IC card respectively;
a contact pressing plate disposed midway between said group of the first contact terminals and the group of second contact terminals, said contact pressing plate being rotatable so as to press the group of contact portions of the second contact terminals down to a predetermined position or to release the group of contact portions from the predetermined position, said contact pressing plate further being slidable between a first position and a second position according to insertion or removal operation of the second IC card or the third IC card; and
a locking/unlocking mechanism fixed to the IC card connector capable of retaining the contact pressing plate at the first position, wherein
the contact pressing plate can rotate when in the first and second positions.
3. An IC card connector, comprising:
a locking/unlocking mechanism that retains said contact pressing plate selectively in a predetermined attitude; and
a contact pressing plate slidably and rotational movably disposed midway between said group of the first contact terminals and the group of second contact terminals, so as to press the group of contact portions of the second contact terminals down to a predetermined position or to release the group of contact portions from the predetermined position according to insertion or removal operation of the second IC card or the third IC card, wherein
the locking/unlocking mechanism comprises a locking/unlocking member disposed adjacent to the second section of said multiple card accommodation, having an end portion that selectively keeps an engaged state of retaining said contact pressing plate or a disengaged state of releasing said contact pressing plate according to insertion or removal operation of the second IC card and the third IC card, and a biasing member that biases said contact pressing plate in the disengaged state so as to keep the engaged state.
4. The IC card connector according to claim 3, wherein, when the second IC card is larger in width than that of the third IC card, upon mounting of the second IC card on the second section said locking/unlocking member keeps the disengaged state to cause said contact pressing plate to rotate and slide, thereby allowing the second IC card to be mounted on the second section.
5. The IC card connector according to claim 3, wherein, when the second IC card is larger in width than that of the third IC card, upon mounting of the third IC card on the third section said locking/unlocking member keeps the disengaged state to cause said contact pressing plate to rotate, thereby allowing the third IC card to be mounted on the third section.
6. An IC card connector to be used in common for first and second IC cards having different dimensions via a common card inserting opening, comprising:
a card accommodation portion including a first section for accommodating said first IC card and a second section for accommodating said second dimensionally different IC card;
a group of first contact terminals and a group of a second contact terminals disposed in the first section and the second section respectively;
a contact pressing plate that selectively presses the group of first contact terminals to rotate away from the first or second IC card, the contact pressing plate being slidable between a first position and a second position,
wherein when the locking/unlocking mechanism retains the contact pressing plate in the first position, the contact pressing plate can rotate, but not slide, and
when the contact pressing plate is in the second position, the contact pressing plate can rotate and slide.
7. An IC card connector as defined in claim 6, wherein said locking/unlocking mechanism includes a first portion fixed to said card connector and a second portion for selectively engaging said contact pressing plate.
8. An IC card connector as defined in claim 7, wherein said second portion of said locking/unlocking mechanism comprises a bent portion configured to engage with a recess formed in said contact pressing plate.
9. An IC card connector as defined in claim 7, wherein said first portion of said locking/unlocking mechanism is fixed to a side wall of said card accommodation portion.
10. An IC card connector as defined in claim 7, wherein said locking/unlocking mechanism includes a third portion, said third portion comprising a curved portion connecting said first portion to said second portion.
This application claims priority from Japanese Patent Application No. 2005-106769 filed Apr. 1, 2005, which is incorporated hereinto by reference.
The present invention relates to an IC card connector that electrically connects several different kinds of IC cards respectively, to be removably inserted in a multiple card accommodation.
In electronic apparatuses recently developed, in general, various functions are expanded thereto by mounting an IC card, such as an MMC� (MULTI MEDIA CARD), an SD (secure digital) card, or a MEMORY STICK�, with a built-in CPU or a memory IC via an IC card connector.
Also, in the IC card connector, for example, as disclosed in Japanese Patent Application Laid-open No. 2004-193111, there is a proposal in that a multiple card accommodation having a slot to be used in common for loading/unloading each IC cards, is provided on the common plane in order to use a plurality of IC cards of mutually different shapes which are mounted in the same electronic apparatus (Ref. FIG. 45 accompanying the cited document).
In such an IC card connector having the multiple card accommodation, each card accommodation portions are sequentially formed in a line along the loading/unloading direction of the IC card. In each of card accommodation portions are respectively provided a group of a contact terminal corresponding to the contact pad of the IC cards. In such a structure, it is necessary to permit smooth insertion and removal of the IC cards while preventing the IC card from causing damage to a group of other unused contact terminal upon inserting or removing each IC cards through the slot used in common.
For example, as disclosed in Japanese Patent Application Laid-open No. 2004-095234, there is a proposal in that an IC card connector includes a sliding member which bears down on the contact portions of the group of contact terminals up to a position where the contact portions do not make contact with the contact pad of the IC card in order to avoid damage to the contact terminal due to contact with an IC card in a set of contact terminals disposed on the side closer to the common slot upon inserting or removing each IC cards. The sliding member disposed at the set of contact terminals side, is slidably disposed along loading/unloading direction of the IC card, and has an oblique cutaway portion at its tip portion for biasing an end of the contact portions of each contact terminals downward in contact therewith.
Also, as disclosed in Japanese Patent No. 02784346, there is a proposal in that an IC card connector includes a sliding member movably disposed between the contact portions of the contact terminals and the contact pad forming surface of the IC card being inserted or removed in order to avoid damage to the a group of contact terminals resulting from the insertion or removal of the IC card. The sliding member is provided with an opening to be selectively exposed so as to permit the contact pad of the IC card to contact the contact portions of the corresponding contact terminal, upon being moved together with the inserted IC card over a predetermined distance toward the contact portions of the group of contact terminals.
As disclosed in Japanese Patent No. 02784346, since the contact portions of the contact terminal always touch on a surface opposing the contact portions of the contact terminals in the sliding member which is movably disposed between the contact portions of the contact terminal and the contact pad forming surface of the IC card to be mounted and demounted, the contact portions of the contact terminal may wear because of the contact with the surface of the sliding member when the sliding member is repeatedly made to reciprocate.
Furthermore, as disclosed in Japanese Patent Application Laid-open No. 2004-095234 as above, it is necessary to ensure a sufficient travel amount of the sliding member when the sliding member slidably disposed along loading/unloading direction of the IC card, has an oblique cutaway portion at its tip portion for biasing an end of the contact portions of each contact terminals downward in contact therewith. More specifically, since the contact portions of the contact terminal are pressed by the tip portion of the sliding member, it is necessary for installing such a sliding member to ensure, between two contact terminals, a dimension that a stroke of the sliding member according to a amount of movement of an ejector member of a card ejecting mechanism and the entire length of the sliding member make.
However, especially when three or more different a group of contact terminals corresponding to each of the IC cards are sequentially provided in a line along loading/unloading direction of the IC card, supposing it adopts the above sliding member, an overall length of the card connector is relatively longer in order to ensure the necessary arrangement size of the sliding member, which is against the requirement of miniaturization in dimensions of the card connector.
In view of the foregoing problems, it is an object of the present invention to provide an IC card connector that electrically connects several different kinds of IC cards respectively, to be removably inserted in a multiple card accommodation, which can minimize damage to an unused contact terminal by collision of the IC card upon insertion or removal of the IC card, in addition can downsize the IC card connector.
To achieve the foregoing object, the present invention provides an IC card connector to be used in common for a plurality of IC cards of mutually different shapes via a common card inserting opening comprising: a card accommodation portion including a front section for accommodating one IC card and a rear section formed at a position farther from the card inserting opening than the front section so as to partially overlap with the front section for accommodating the other IC card; a group of front contact terminals and a group of a rear contact terminals disposed in the front section and the rear section respectively, for electrical connection with the one IC card and the other IC card respectively; and a contact pressing plate which is disposed such that an end portion thereof facing the card inserting opening is movably provided between the first section and a space, in the rear section, overlapping with the front section in a thickness direction of the one and the other IC card, and which selectively presses the group of contact portions of the front contact terminals down up to a predetermined position; wherein said contact pressing plate presses the group of contact portions of the front contact terminals down to a predetermined position according to insertion of the one IC card or the other IC card to be accommodated in said front section and rear section, thus to make the one IC card accommodated in the front section electrically connectible with the group of contact portions of the front contact terminals or to make the other IC card accommodated in the rear section electrically connectible with the rear contact terminals, or releases the a group of contact portions from the predetermined position according to ejecting operation of the one IC card or the other IC card accommodated in the front section and the rear section.
The present invention also provides an IC card connector comprising a multiple card accommodation including a first section for removably accommodating via a common card inserting opening a first IC card out of a plurality of IC cards of mutually different shapes, a second section for accommodating a second IC card, formed at a position farther from the card inserting opening than the first section in a line therewith and partially overlapping therewith, and a third section for accommodating a third IC card, formed at a position still farther from the card inserting opening than the first and the second sections, in a line therewith and partially overlapping therewith; a group of first contact terminals, a group of second contact terminals and a group of third contact terminals sequentially disposed in the loading/unloading direction of the IC card so as to correspond to the first section, the second section and the third section respectively, for electrical connection with the first IC card, the second IC card and the third IC card respectively; and a contact pressing plate slidably and rotational movably disposed midway between said group of the first contact terminals and the group of second contact terminals, so as to press the group of contact portions of the second contact terminals down to a predetermined position or to release the group of contact portions from the predetermined position according to insertion or removal operation of the second IC card or the third IC card.
As is apparent from the foregoing description, in the IC card connector according to the present invention, the contact pressing plate presses the group of contact portions of the front contact terminals down to a predetermined position upon insertion operation of the one IC card or the other IC card, thereby making the one IC card electrically connectible with the group of contact portions of the front contact terminals or to make the other IC card electrically connectible with the rear contact terminals. Accordingly, the group of contact portions of the front contact terminals are kept from contacting the other IC card when inserting or removing the other IC card, which allows minimizing a damage to an unused contact terminal by collision of the IC card upon insertion or removal. Moreover, the contact pressing plate is disposed such that an end portion thereof facing the card slot can move between the front section and a space, in the rear section, overlapping with the front section in a thickness direction of the front and the rear IC card, which permits making the IC card connector smaller in dimensions.
FIG. 1 is a plan view showing an important portion of an embodiment of an IC card connector according to the present invention;
FIG. 2 is a plan view showing an outer appearance of an embodiment of the IC card connector according to the present invention;
FIG. 3 is a front view of the IC card connector of an embodiment shown in FIG. 2, seen from the side with a card slot;
FIG. 4 is a side view of the IC card connector of an embodiment shown in FIG. 2;
FIG. 5 is a cross-sectional view of the IC card connector of an embodiment shown in FIG. 2;
FIG. 6 is a cross-sectional view taken along the line VI-VI of FIG. 1;
FIG. 7 is an enlarged partial block diagram showing a structure of a contact pressing plate and a locking/unlocking hardware employed in the IC card connector of an embodiment shown in FIG. 2;
FIG. 8 is an exploded perspective view showing a structure of an ejector, the contact pressing plate and the locking/unlocking hardware employed in the IC card connector of an embodiment shown in FIG. 2;
FIG. 9 is a plan view made available for explaining an operation of the IC card connector of an embodiment shown in FIG. 2;
FIG. 11 is a plan view showing the IC card connector of an embodiment shown in FIG. 2 with a MEMORY STICK mounted thereto;
FIG. 12 is a front view of the state of FIG. 11, seen from the side with the card slot;
FIG. 13 is an enlarged partial block diagram showing a structure of the contact pressing plate and the locking/unlocking hardware under the state shown in FIG. 11;
FIG. 14 is a cross-sectional view made available for explaining an operation of the IC card connector of an embodiment shown in FIG. 2 with the MEMORY STICK mounted thereto;
FIG. 15 is another cross-sectional view made available for explaining an operation of the IC card connector of an embodiment shown in FIG. 2 with the MEMORY STICK mounted thereto;
FIG. 16 is a plan view showing the IC card connector of an embodiment shown in FIG. 2, with an SD card mounted thereto;
FIG. 17 is a cross-sectional view taken along the line XVII-XVII of FIG. 16;
FIG. 18 is an enlarged partial plan view showing a structure of the contact pressing plate and the locking/unlocking hardware under the state shown in FIG. 16;
FIG. 19 is a plan view made available for explaining an operation of the IC card connector of an embodiment in FIG. 2 with the SD card mounted thereto;
FIG. 20 is a front view of the IC card connector under the state shown in FIG. 19, seen from the side with the card slot;
FIG. 21 is a cross-sectional view taken along the line XXI-XXI of FIG. 19;
FIG. 22 is an enlarged partial plan view showing a structure of the contact pressing plate and the locking/unlocking hardware under the state shown in FIG. 19;
FIG. 23 is a plan view showing the IC card connector of an embodiment shown in FIG. 2, with an XD card mounted thereto;
FIG. 24 is a front view showing the IC card connector of an embodiment shown in FIG. 23, seen from the side with the card slot;
FIG. 25 is a cross-sectional view taken along the line XXV-XXV of FIG. 23; and
FIG. 26 is an enlarged partial plan view showing a structure of the contact pressing plate and the locking/unlocking hardware under the state shown in FIG. 23.
FIGS. 2 and 3 respectively depict an outer appearance of an embodiment of an IC card connector according to the present invention.
The IC card connector shown in FIG. 2 is designed to be implemented on a wiring board (not shown) in an electronic apparatus such as a printer, a mobile phone, a PDA or a digital camera. One of four types of IC cards, namely a MEMORY STICK� corresponding to the third IC card, an SD (secure digital) card corresponding to the second IC card, an MMC� (MULTI MEDIA CARD), and an xD-PICTURE CARD� (hereinafter, referred to as XD card) corresponding to the first IC card, can be selectively mounted on the IC card connector as described later.
The IC card connector serves to electrically connect an electrode portion of each IC cards removably mounted to a card accommodation thereof, for example in a direction indicated by an arrow in FIG. 2, with a connection terminal of a signal input and output substrate disposed inside the given electronic apparatus.
The MEMORY STICK MS (Ref. FIG. 14) is narrower in width than that of the SD card SD as described later, but has a larger dimension in the longitudinal direction than that of the SD card SD. The SD card SD (Ref. FIG. 16) is provided with a plurality of contact pads formed on one of the surfaces at a front edge with one of the corners chamfered, so as to correspond to an array of contact terminals as described later. On the both sides thereof, a notch portion is formed so as to oppose each other. In one of the notch portions, a write-protect button is movably disposed. The MMC� card, not shown, is of an identical width and entire length to those of the SD card SD, except for thickness of the card and number of the contact pads. The MMC card is slightly thinner than that of the SD card SD and has fewer contact pads than those of the SD card SD.
The XD card XD (Ref. FIG. 23) is provided with a plurality of contact pads located on one of the surfaces so as to correspond to an array of contact terminals as described later, and a notch portion on one of the sides thereof. The XD card XD is slightly larger in width than that of the SD card SD. The XD card is considerably shorter and thinner than the entire length and thickness of the SD card SD.
The IC card connector includes a base member 10 on which a plurality of contact terminals is aligned, for electrical connection with the MEMORY STICK MS, the SD card SD, the MMC card and the XD card XD to be mounted to the IC card connector, and a cover member 12 that defines the card accommodation in cooperation with the base member 10.
The cover member 12, which has a portal cross-section, is made of a thin metal plate. The cover member 12 includes engaging holes 12La, 12Lb, 12Lc and 12Ld on one of the side faces, to be engaged with nibs on the base member 10 as described later, as shown in FIG. 4. Such engaging holes are also provided at the respective opposite positions on the other side face (not shown) of the cover member 12, to be engaged with nibs on the base member 10.
Accordingly, the engaging holes 12La, 12Lb, 12Lc and 12Ld and those on the opposite side of the cover member 12 are respectively engaged with the nibs of the base member 10, so that the cover member 12 is fixed to the base member 10.
The card accommodation portion in the base member 10 is integrally formed of a molding resin, for example. The card accommodation portion is provided with an opening on an upper portion, part of a lower portion and an end portion opposite the contact terminal fixing portion as described later, as shown in FIGS. 1 and 5. Accordingly, by covering entire base member 10 with the cover member 12 as above, a card slot 8CS (Ref. FIG. 5) to be used in common for selectively inserting one of the MEMORY STICK MS, the SD card SD, the MMC card and the XD card XD is formed on an end portion of the card accommodation portion 8.
The card accommodation portion 8 serves as a multiple card accommodation including a first section formed closest to the card slot 8CS for accommodating the XD card XD, a second section disposed so as to partially overlap with the first section for accommodating the SD card SD or the MMC card, and a third section extended so as to partially overlap with the first and the second section, for accommodating the MEMORY STICK MS.
In other words, the first to the third sections are formed in a row along the loading/unloading direction of each cards, partially overlapping with one another. Accordingly, the common card slot 8CS defined in the first section is formed by the inner periphery surface of a pair of sidewalls 10WR and 10WL that include a pair of guide walls 10G3 for guiding the sides of the MEMORY STICK MS, the cover member 12 and the bottom portion of the base member 10, as shown in FIG. 3.
The first and the second section of the card accommodation portion is formed by the cover member 12, the sidewalls 10WR and 10WL forming the side portions, and a bottom portion that connects the sidewalls 10WR and 10WL. The third section of the card accommodation portion is formed by the cover member 12, the sidewalls 10WR and 10WL as above, the bottom portion, and the contact terminal fixing wall 10WB.
As shown in FIG. 1, the sidewalls 10WR and 10WL are provided with the nibs 10Ra, 10Rb, 10Rc, 10Rd, 10La, 10Lb, 10Lc, and 10Ld respectively, on the outer surface thereof. At an end portion of the sidewalls 10WR and 10WL, the nibs 10Eb, 10Ea are also formed respectively. On the outer surface of the contact terminal fixing wall 10WB, the nibs 10Ed, 10Ec are formed.
The contact terminal fixing wall 10WB forming the third section of the base member 10 is provided with a plurality of contact terminals 18 ai (i=1 to 10) as shown in FIGS. 1 and 5. The contact terminals 18 ai are aligned at a predetermined interval between one another, generally parallel to the sidewalls 10WR and 10WL.
The contact terminals 18 ai, the third group of contact terminals, include elastic contact portion of an elastic material to be touched against the contact pad (electrode) of the MEMORY STICK MS for electrical connection, soldered terminal portions fixed to an electrode portion of a wiring board by soldering for electrical connection, and a fixing portion fixed to the base member 10 for mutually connecting the contact portions and the soldered terminal portions.
The fixing portion of the contact terminals 18 ai, made of a thin metal plate such as phosphor bronze for a spring, is press-fitted into a groove formed on the bottom portion continued from the contact terminal fixing wall 10WB from a side opposite the side through which the MEMORY STICK MS is inserted, via a through hole formed on the contact terminal fixing wall 10WB, thus to be fixed to the base member 10.
The first section of the card accommodation portion is provided with a plurality of contact terminals 16 ai (i=1 to 20). The contact terminals 16 ai are aligned at a predetermined interval between one another, generally parallel to the sidewalls 10WR and 10WL. The contact terminals 16 ai are spaced from the contact terminals 18 ai by a predetermined distance.
The contact terminals 16 ai, a group of first contact terminals, include elastic contact portions to be touched against the contact pad (electrode) of the XD card XD for electrical connection, soldered terminal portions fixed to an electrode portion of a wiring board by soldering for electrical connection, and a fixing portion fixed to the base member 10 for mutually connecting the contact portions and the soldered terminal portions.
The fixing portion of the contact terminals 16 ai, made of a thin metal plate such as phosphor bronze for a spring, for example, is press-fitted into a groove formed on the bottom portion of the base member 10 from the side through which the XD card XD is inserted, thus to be fixed to the base member 10. The soldered terminal portions of the contact terminals 16 ai are projected from an end portion of the bottom portion toward the card slot 8CS. The height of the contact portions from the bottom portion is slightly lower than grooves 10G1 and 10G2 formed below the guide wall 10G3 in the sidewalls 10WR and 10WL. This causes the contact portions of the contact terminals 16 ai to be not capable of being hit and damaged by the front edge of the MEMORY STICK MS, SD card SD or the MMC card guided by the grooves 10G1 and 10G2, when mounting those cards accommodated in the second or the third section.
The second section of the multiple card accommodation is provided with a plurality of contact terminals 14 ai (i=1 to 9), aligned along width direction and generally parallel to one another. The contact terminals 14 ai are provided at a middle position between the contact terminals 18 ai and the contact terminals 16 ai. At a position below the contact portions of the contact terminals 14 ai, an opening is formed on a bottom portion of the base member 10 so as to cause the contact portions to pass therethrough.
The contact terminals 14 ai, a group of second contact terminals, include the elastically deformable contact portions to be touched against the contact pad (electrode) of the SD card SD or the MMC card for electrical connection, soldered terminal portions fixed to an electrode portion of a wiring board by soldering for electrical connection, and a fixing portion fixed to the base member 10 for interconnecting the contact portions and the soldered terminal portions. The fixing portion of the contact terminals l4 ai, made of a thin metal plate such as phosphor bronze for a spring for example, is press-fitted into a groove formed on the bottom portion of the base member 10 from the side through which the SD card SD is inserted, thus to be fixed to the base member 10. The soldered terminal portions are projected outward beyond the contact terminal fixing wall 10WB, so as to be aligned with the soldered terminal portions of the contact terminals 18 ai in a line. The tip portions of the contact portions are projected into the path throughwhich the MEMORY STICK MS and the SD card SD pass, when one of these cards is not inserted, as shown in FIG. 5.
In addition, with a middle portion of the contact portion of each contact terminal 14 ai, a periphery of slits 20 ai (i=1 to 9) of a contact pressing plate 20 as described later is engaged.
Referring to FIG. 8, the contact pressing plate 20 is provided with a supporting shaft 20S at the respective end portions of both sides. The supporting shafts 20S are slidably and rotational movably engaged with a guide groove (not shown) provided on each of the opposing inner surfaces of the sidewalls 10WR and 10WL. Thus, according to FIG. 5, the contact pressing plate 20 is rotational movably supported in a counterclockwise direction for pressing the contact portions of the contact terminals 14 ai toward the lower opening, as well as in a clockwise direction for releasing the contact portions of the contact terminals 14 ai, while making a sliding motion.
The contact pressing plate 20 has the slits 20 ai (i=1 to 9) aligned along a width direction so as to correspond to the contact portions of the contact terminals 14 ai. Into each slit 20 ai, as shown in FIG. 5, the tip portion of each contact portion of the contact terminals 14 ai is inserted from below, so as to intersect with the contact pressing plate 20. Accordingly, the contact pressing plate 20 is supported by the contact terminals 14 ai in a posture inclined by a predetermined angle so that an end portion thereof intrudes into the path that the SD card SD and so on pass through, as shown in FIG. 5.
Around the respective slits 20 ai, guide walls 20CS are formed for guiding the SD card SD, as shown in FIG. 8. The guide walls 20CS are respectively engaged with a plurality of grooves formed on the SD card SD. Between the adjacent guide walls 20CS, a gap is formed. Such gaps are movably engaged with partition walls of the inserted SD card SD. Referring to FIG. 7, a spring catcher 20K formed integrally with on one of the side portions of the contact pressing plate 20, the spring catcher including a recess 20 g with which an end portion of a locking/unlocking hardware 26 is selectively engaged. The recess 20 g passes through along thickness direction of the contact pressing plate 20. Namely, when the end portion of the locking/unlocking hardware 26 is engaged with the periphery of the recess 20 g, the contact pressing plate 20 is retained under a locked state, as shown in FIGS. 5 and 6. Note that a surface of the spring catcher 20K opposing the ejector 22 as described later is touched against a projecting piece 22P of the ejector 22.
Referring back to FIG. 1, the sidewall 10WL is provided with a detecting contact unit 21 that detects the write-protect button of the SD card SD as above.
Inside the sidewall 10WR, an ejecting mechanism is provided. The ejecting mechanism serves to retain the XD card XD, the SD card SD, the MMC card, or the MEMORY STICK MS in the first section of the card accommodation portion 8, the second section and the third section thereof respectively, and to selectively eject each cards out of the card accommodation portion 8.
As shown in FIGS. 1 and 8, the ejecting mechanism comprises an ejector 22 which is supported so as to relatively move with respect to the base member 10 according to loading/unloading operation of each card, allowing the ejector 22 to selectively retain one of those IC cards; a coil spring (not shown) interposed between the inner periphery of the base member 10 and an end portion of the ejector 22, for biasing the ejector 22 toward the discharging direction of the SD card SD and so on; and an ejector controller portion to be used in common for the IC cards, for selectively controlling the holding or release of the ejector 22 with respect to the base member 10, according to the loading/unloading operation of the SD card SD and so on.
The ejector 22 is made of a resin material, for example, and supported by the inner periphery of the sidewall 10WR, slidably on the base member 10 along loading/unloading direction of the SD card SD and so on.
Also as shown in FIG. 8, the ejector 22 includes a touching surface 22E on an end portion thereof, with which a part of the tip portion of the inserted MEMORY STICK MS is engaged. The ejector 22 also has on the other end portion a groove 22 ga for guiding the XD card XD, and groove 22 gb for guiding the SD card SD. A step portion 22 a is formed on one of the sides of groove 22 ga, the step portion for engagement with a part of the tip portion of the XD card XD. Between the touching surface 22E and the step portion 22 a, a projecting piece 22P is provided to be touched against the outer periphery of the spring catcher 20K as above. Adjacent to the projecting piece 22P, a touching surface 22 b is formed for engagement with a part of the tip portion of the SD card SD. Accordingly, the ejector 22 is made to move toward the contact terminal fixing wall 10WB, when one of the MEMORY STICK MS, the XD card XD and the SD card SD is inserted with a part of the tip portion thereof touched against the touching surface 22E, the step portion 22 a, and the touching surface 22 b respectively.
The ejector controller portion includes, as shown in FIGS. 8 and 9, a generally heart-shaped cam (heart cam) 22CA integrally formed on the upper surface of the ejector 22 opposing the cover member 12, a lever guide groove 22CM constituted of a plurality of step portions formed around the heart cam 22CA, a generally reverse channel-shaped cam lever 24 with a first end portion connected to a hole on the sidewall 10WR and a second end portion disposed so as to slide along the lever guide groove 22CM, and a pressing spring (not shown) of the cover member 12.
The pressing spring serves to bias the cam lever 24 so that the bent tip portion thereof slides on the guiding surface in the lever guide groove 22CM.
The heart cam 22CA, made of a resin, includes a generally V-shaped cam surface to be selectively engaged with the second end portion of the cam lever 24.
The lever guide groove 22CM includes a first guide groove formed close to one of the sides of the heart cam 22CA so as to linearly extend along the sidewall 10WR, a second guide groove obliquely extending along the other side of the heart cam 22CA toward the sidewall 10WR so as to branch from the first guide groove, and then extending in parallel to the first guide groove, and a third guide groove that connects a portion between an end portion of the first guide groove and an end portion of the second guide groove and opposing the cam surface.
Accordingly, when the second end portion of the cam lever follows up the motion of the ejector 22 so as to be guided sequentially along the first guide groove, the third guide groove and the second guide groove, the ejector 22 is sequentially caused to inwardly advance, to be retained and to be discharged accompanied with the IC card.
Below the ejector 22, the locking/unlocking hardware 26 is provided. The locking/unlocking hardware 26 includes a fixed portion 26F fixed to the sidewall 10WR at an end portion, and a bent portion 26K selectively engaged with the periphery of the recess 20 g of the spring catcher 20K as above at the other end portion which is elastically deformable, and a curved portion 26B connecting the fixed portion 26F and the bent portion 26K. As shown in FIG. 7, the bent portion 26K of the locking/unlocking hardware 26 is engaged with the periphery of the recess 20 g of the contact pressing plate 20 (locked state) when none of the IC cards are inserted, and disengaged from the periphery of the recess 20 g (unlocked state) as shown in FIG. 18, once the SD card SD or another is inserted.
Under such a configuration, when inserting the MEMORY STICK MS, as shown in FIGS. 11 and 12, first, the tip portion of the MEMORY STICK MS is guided along the guide wall 10G3 after passing through the card slot 8CS, thus to pass through the first section, and touched against the surface of the contact pressing plate 20. Next when the tip portion of the MEMORY STICK MS is further pressed in the insertion direction while being touched against the surface of the contact pressing plate 20 (Ref. FIG. 14), the periphery of the recess 20 g keeps engaged with the bent portion 26K of the locking/unlocking hardware 26 so as to retain the contact pressing plate 20 in its initial position, and the contact pressing plate 20 is rotated and detruded against the elastic force of the contact terminals 14 ai, as shown in FIG. 15. This causes the tip portion of the contact portions of the contact terminals l4 ai to pass through the slits 20 ai and to penetrate the opening of the base member without interfering with the MEMORY STICK MS.
Thereafter, the tip portion of the MEMORY STICK MS is touched the touching surface 22E of the ejector 22 against the biasing force of the coil spring (not shown) and pressed in the insertion direction together with the ejector 22, upon passing through the second section over the contact pressing plate 20 and entering the third section. After that, when such pressing force is released, the end portion of the cam lever 24 is separated from the first guide groove to be engaged with the cam surface of the third guide groove. In other words, the ejector controller portion keeps the ejector 22 in the retaining state. Therefore, the contact pad of the retained MEMORY STICK MS held is electrically connected with the contact portions of the contact terminals 18 ai. When removing the MEMORY STICK MS, the MEMORY STICK MS is once pressed slightly further forward. At that time, advancing of the ejector 22 causes one end portion of the cam lever 24 to release and separate from the cam surface, and lead it to the second guide groove. Thus, the ejector 22 is pressed backward by the biasing force of the coil spring (not shown). At this time, when the tip portion of the MEMORY STICK MS is pressed backward with the ejector 22 over the contact pressing plate 20 to a position close to the card slot 8CS, the end portion of the contact pressing plate 20 automatically rotates upward about the supporting shafts 20S as shown in FIG. 14, by the restoring force of the contact portions of the contact terminals 14 ai. Because of this rotation, the rim of the recess 20 g is rotated toward the locking/unlocking hardware 26 to be forcibly engaged with the bent portion 26K of the locking/unlocking hardware 26, thus resulting in the locked state as shown in FIG. 13.
Then, upon pulling further outward the end portion of the MEMORY STICK MS exposed outside the IC card connector, the MEMORY STICK MS is removed.
When mounting the SD card SD or the MMC card, the front edge of the SD card SD is guided along the groove 10G1 upon passing through the card slot 8CS as above to be inserted in the second section of the card accommodation portion through the first section, as shown in FIGS. 19 and 20.
At that time, one of the side faces of the SD card SD presses the curved portion 26B of the locking/unlocking hardware 26 in the width direction toward the sidewall 10WR as shown in FIG. 22. This causes the bent portion 26K of the locking/unlocking hardware 26 to be separated and disengaged from the rim of the recess 20 g, resulting in unlocking the contact pressing plate 20. Additionally, the front edge of the SD card SD presses the contact pressing plate 20 such that the front edge of the SD card SD is touched to press down the contact portions of the contact terminals 14 ai. Accordingly, the end portion of the contact pressing plate 20 is rotated about the supporting shafts 20S and detruded without interfering with the tip portion of the contact portions of the contact terminals 14 ai, as shown in FIGS. 19 and 20, as well as being slid by a predetermined distance SL as shown in FIGS. 16, 17 and 18. At that time, the end portion of the cam lever 24 is separated from the first guide groove, thus to be engaged with the cam surface of the third guide groove when the pressing force is removed after the front edge of the SD card SD is maintained touched against the touching surface 22 b of the ejector 22 and further pressed together with the ejector 22 against the biasing force of the coil spring (not shown). Thus, the ejector controller portion keeps the ejector 22 in the retaining state.
Accordingly, the SD card SD is retained in the second section of the card accommodation portion, and also the contact pad of the SD card SD and the contact portions of the contact terminals 14 ai are made to touch via the slits 20 ai of the contact pressing plate 20 so as to be electrically connected.
When removing the SD card SD, the mounted SD card SD is once pressed slightly further forward. Advancing of the ejector 22 causes one end portion of the cam lever 24 to be released and separated from the cam surface and to be led to the second guide groove. Thus, the ejector 22 is pressed backward together with the contact pressing plate 20 and the SD card SD via the projecting piece 20, by the predetermined distance SL by the biasing force of the coil spring.
Then, the end portion of the contact pressing plate 20 automatically rotates upward about the supporting shafts 20S by the restoring force of the contact terminals 14 ai. At that time, the rim of the recess 20 g is rotated toward the locking/unlocking hardware 26 to be forcibly engaged with the bent portion 26K of the locking/unlocking hardware 26 which is now back to its initial position, thus resulting in the locked state.
Then, upon pulling further outward the end portion of the SD card SD exposed outside the IC card connector, the SD card SD is removed.
Further, when inserting the XD card XD, the front edge of the XD card XD is guided along the groove 10G2 upon passing through the card slot 8CS, thus to be inserted in the first section of the card accommodation portion, as shown in FIGS. 23 and 24. At that time, one of the side faces of the XD card XD is inserted without contacting the curved portion 26B of the locking/unlocking hardware 26. Then, when the pressing force is removed after the front edge of the XD card XD is kept retained by the step portion 22 a of the ejector 22 and further pressed together with the ejector 22 against the biasing force of the coil spring (not shown), one end portion of the cam lever 24 is separated from the first guide groove to be engaged with the cam surface of the third guide groove. Namely, the ejector controller portion keeps the ejector 22 in the retaining state.
Accordingly, the XD card XD is retained in the first section of the card accommodation portion, and also the contact pad of the XD card XD and the contact portions of the contact terminals 16 ai are made to touch to be electrically connected.
When removing the XD card XD, the mounted XD card XD is once pressed slightly further forward. At that time, advancing of the ejector 22 causes one end portion of the cam lever 24 to be released and separated from the cam surface and to be led to the second guide groove. Thus, the ejector 22 is pressed backward together with the XD card XD by the biasing force of the coil spring.
Then, upon pulling further outward the end portion of the XD card XD exposed outside the IC card connector, the XD card XD is removed.
Accordingly, in the foregoing embodiment, when mounting the MEMORY STICK MS for example, the tip portions of the contact portions of the contact terminals 14 ai unused are pressed against by the unlocked contact pressing plate 20 up to a position where the contact portions do not interfere with the tip portion of the MEMORY STICK MS. Such a structure allows to prevent the contact portions of the contact terminals 14 ai from being damaged, and since the contact pressing plate 20 is slidably and rotational movably disposed between a group of the contact terminal 18 ai and a group of the contact terminal 16 ai, the contact pressing plate 20 can be provided inside the IC card connector within a relatively small space. This permits reducing the overall length of the IC card connector provided with a multiple card accommodation.
Patent CitationsCited PatentFiling datePublication dateApplicantTitleUS4404464Jan 23, 1979Sep 13, 1983Moreno Roland C DMethod and apparatus for electrically connecting a removable article, in particular a portable electronic cardUS4421372Jun 13, 1979Dec 20, 1983The Babcock & Wilcox CompanyInsertion-withdrawal mechanism for rack mounted circuit boardsUS4722693Mar 30, 1987Feb 2, 1988Friedhelm RoseSafety shutters for electrical receptaclesUS5035633Feb 23, 1990Jul 30, 1991Kabushiki Kaisha ToshibaData-processing apparatus in which a card-shaped recording medium is usedUS5179504Mar 5, 1991Jan 12, 1993Olympus Optical Co., Ltd.Shutter mechanism undergoing rotational and translational movements for use in recording medium and/or reproducing apparatus using card-like mediumUS5207598Feb 24, 1992May 4, 1993Molex IncorporatedFor providing an electrical connection between contactsUS5300763Nov 27, 1991Apr 5, 1994Olympus Optical Co., Ltd.Information recording/reproducing apparatusUS5490791Oct 26, 1993Feb 13, 1996The Whitaker CorporationCard edge connectorsUS5563397Sep 18, 1995Oct 8, 1996Anritsu CorporationCards receiving mechanism having function for certainly receiving qualified cards and blocking unqualified cards and foreign articlesUS5876218May 28, 1997Mar 2, 1999Gateway 2000, Inc.Piggy back PC cardUS6056573Jul 16, 1997May 2, 2000Alps Electric Co., Ltd.IC card connectorUS6068500Jul 28, 1998May 30, 2000Itt Manufacturing Enterprises, Inc.Multi-contact PC card and host systemUS6109940Oct 9, 1998Aug 29, 2000Methode Electronics, Inc.Shutter mechanism for card adapterUS6123557Mar 29, 1999Sep 26, 2000Inventec CorporationAutomatic opening mechanism for docking station connector coverUS6129572Aug 3, 1998Oct 10, 20003M Innovative Properties CompanyElectrical connector with latch to retain IC cardUS6135809Jul 10, 1998Oct 24, 2000The Whitaker CorporationCard connectorUS6203378Feb 23, 1999Mar 20, 2001Japan Solderless Terminal Mgf. Co., LtdCard connecting adapterUS6345760May 27, 1999Feb 12, 2002Asahi Seiko., Ltd.Machine for process for IC cards and apparatus for issuing IC cardsUS6361369Sep 17, 1999Mar 26, 2002Sony CorporationMemory card, and receptacle for sameUS6386920Nov 20, 2001May 14, 2002Kinpo Electronics, Inc.Joint socket device for memory cardsUS6399906Nov 2, 2000Jun 4, 2002Yamaichi Electronics Co., Ltd.Switch for a card connectorUS6402529Feb 7, 2001Jun 11, 2002Yamaichi Electronics Co., Ltd.Card connectorUS6413108Jan 14, 2000Jul 2, 2002Itt Manufacturing Enterprises, Inc.Personal computer peripheral device adapterUS6457647Jan 8, 1997Oct 1, 2002Canon Kabushiki KaishaMemory card adaptor to facilitate upgrades and the likeUS6468101Sep 27, 2001Oct 22, 2002Kel CorporationCard connectorUS6482029Apr 26, 2001Nov 19, 2002Yamaichi Electronics Co., Ltd.Card connectorUS6503092Dec 27, 2000Jan 7, 2003Yamaichi Electronics Co., Ltd.Card connectorUS6511350Nov 6, 2000Jan 28, 2003Yamaichi Electronics Co., Ltd.Card connectorUS6524137Mar 15, 2002Feb 25, 2003Carry Computer Eng. Co., Ltd.Integral multiplex adapter cardUS6527590Sep 7, 2001Mar 4, 2003Alps Electric Co., Ltd.Card connector having overstroke for card mounting positionUS6547601 *May 2, 2001Apr 15, 2003Alps Electric Co., Ltd.Card connector deviceUS6601766Dec 21, 2000Aug 5, 2003Minolta Co., Ltd.Electronic device using card-type mediaUS6607404Nov 2, 2000Aug 19, 2003Yamaichi Electronics Co., Ltd.Card connectorUS6612492Jun 6, 2002Sep 2, 2003Chant Sincere Co., Ltd.Four-in-one memory card insertion portUS6641413Jun 25, 2002Nov 4, 2003Alps Electric Co., Ltd.Card connector apparatus capable of receiving plural kinds of cardsUS6666724Dec 31, 2002Dec 23, 2003Tai-Sol Electronics, Co., Ltd.Multi-purpose card connectorUS6699053Jun 25, 2002Mar 2, 2004Alps Electric Co., Ltd.Card connector apparatus capable of receiving different kinds of cardsUS6699061Dec 5, 2000Mar 2, 2004Yamaichi Electronics Co., Ltd.Card connectorUS6700788Dec 18, 2002Mar 2, 2004Alps Electric Co., Ltd.Connector device for cards permitting insertion of different types of cardsUS6716066Mar 21, 2003Apr 6, 2004Jih Vei Electronics Co., Ltd.Multi-memory card connectorUS6780062Jul 11, 2002Aug 24, 2004Carry Computer Eng., Co., Ltd.Multi-specification read/write signal transmission module for silicon disksUS6783399May 28, 2003Aug 31, 2004Samsung Electro-Mechanics Co., LtdUniversal slot for accommodating various types of flash memory cardsUS6863571Mar 24, 2004Mar 8, 2005Yamaichi Electronics Co., Ltd.Composite type card connectorUS6913492 *Dec 22, 2003Jul 5, 2005Alps Electric Co., Ltd.Connector device for card into which plural kinds of cards of different shapes can be insertedUS6976879Nov 26, 2003Dec 20, 2005Yamaichi Electronics Co., Ltd.Card connectorUS7052325 *Sep 16, 2004May 30, 2006Northstar Systems Corp.Structure for all-in-one memory card socketUS7182645Jan 21, 2005Feb 27, 2007Yamaichi Electronics Co., Ltd.Card connector for an electronic device and a contact used thereinUS20030157839Jun 29, 2001Aug 21, 2003Tomisaburo YamaguchiIc card connectorUS20040026507Aug 6, 2003Feb 12, 2004Shigeyuki NagataMagnetic card transaction apparatusUS20040106326Jan 24, 2003Jun 3, 2004Wen-Tsung LiuCard switch deviceUS20040110423Nov 26, 2003Jun 10, 2004Yamaichi Electronics Co., Ltd.Card connectorCN2520582YJan 15, 2002Nov 13, 2002金成塑胶工业股份有限公司Ic卡连接器DE3937383A1Nov 7, 1989Jun 7, 1990SagemAufnahmevorrichtung fuer chipkartenDE4139482A1Nov 29, 1991Jun 3, 1993Man Technologie GmbhMechanical protection system for electronic card readers - has mechanical flap held in closed position that can once be displaced by card insertionEP0284431A2Mar 25, 1988Sep 28, 1988Mitsubishi Denki Kabushiki KaishaMechanism for connecting IC card and external deviceEP0696008A2Oct 14, 1989Feb 7, 1996Omron CorporationCard reader having locking mechanismEP0936705A2Feb 8, 1999Aug 18, 1999The Great American Gumball CorporationPersonal computer peripheral device adapaterEP0939582A2Feb 26, 1999Sep 1, 1999Japan Solderless Terminal Mfg. Co., Ltd.Card connecting adapterEP1146474A1Nov 2, 2000Oct 17, 2001Matsushita Electric Industrial Co., Ltd.Card connectorEP1324256A1Dec 18, 2002Jul 2, 2003Tyco Electronics AMP K. K.Card connectorEP1487001B1Mar 25, 2004Aug 30, 2006Omron CorporationElectromagnetic relayJP2784346B2 Title not availableJP2000251024A Title not availableJP2000251025A Title not availableJP2000277200A Title not availableJP2001135385A Title not availableJP2001195546A Title not availableJP2001237027A Title not availableJP2002157056A Title not availableJP2002164124A Title not availableJP2002174532A Title not availableJP2002289295A Title not availableJP2003288962A Title not availableJP2003317858A Title not availableJP2004058232A Title not availableJP2004071257A Title not availableJP2004095234A Title not availableJP2004193111A Title not availableJP2004214119A Title not availableJP2004311123A Title not availableJP2005011666A Title not availableJP2005044780A Title not availableJP2005135696A Title not availableJPH1021348A Title not availableJPH1091729A Title not availableJPH07335321A Title not availableJPH10187896A Title not availableJPH11316110A Title not availableJPS63133473A Title not available* Cited by examinerNon-Patent CitationsReference1English Abstract for Japanese Publication No. 08055661, dated Feb. 27, 1996, Application No. 06219371, application date Aug. 10, 1994, for inventor Yoshikawa Takamasa, Title: Card Connecting Adaptor.2European Patent Office Search Report dated Mar. 1, 2004, for European Patent Application No. 00971781.0.3International search Report Application No. PCT/JP00/007762, dated Feb. 6, 2001 from the European Patent Office.4Office Action dated Jul. 18, 2008 issued in the corresponding Japanese Application No. 2005-106769.5Office Action dated Jun. 6, 2008 in corresponding Chinese Patent Application No. 2006-100670367.6Official Action from Japanese Patent Office for Application No. 2003-385753, mailed Jun. 14, 2005.Referenced byCiting PatentFiling datePublication dateApplicantTitleUS7798835 *Jul 28, 2009Sep 21, 2010Concraft Holding Co., Ltd.Electronic connector with press-fitted terminals in a body floating on a support memberUS8678861 *Jun 24, 2011Mar 25, 2014Hon Hai Precision Industry Co., Ltd.Card connector with structure for preventing insertion of inappropriate size cardsUS20120329306 *Jun 24, 2011Dec 27, 2012Hon Hai Precision Industry Co., Ltd.Card connectorUS20140099805 *Oct 10, 2012Apr 10, 2014Motorola Mobility LlcElectronic connector capable of accepting a single subscriber identity mopdule or a memory card* Cited by examinerClassifications U.S. Classification235/441, 439/630, 235/380International ClassificationG06K7/06Cooperative ClassificationG06K7/0013, G06K7/0043European ClassificationG06K7/00K3C, G06K7/00KLegal EventsDateCodeEventDescriptionMar 7, 2013FPAYFee paymentYear of fee payment: 4Mar 31, 2006ASAssignmentOwner name: YAMAICHI ELECTRONICS CO., LTD., JAPANFree format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:SATO, SHIGERU;REEL/FRAME:017744/0885Effective date: 20060323RotateOriginal ImageGoogle Home - Sitemap - USPTO Bulk Downloads - Privacy Policy - Terms of Service - About Google Patents - Send FeedbackData provided by IFI CLAIMS Patent Services