JP3798335B2 - IC card connector - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an IC card connector for attaching and detaching an IC card used as an external storage medium in a personal computer or other electronic device by push-in or push-out. Alternatively, the present invention relates to an IC card connector having a function of preventing erroneous insertion in the reverse direction.
[0002]
[Prior art]
2. Description of the Related Art A card-type memory device incorporating a semiconductor memory, a so-called IC card storage medium, is widely used as an external storage device for electronic devices such as a computer body, a video camera device, and a portable information terminal device. This IC card has a very small shape compared to a storage medium that has been used in the past, and has a large storage capacity. When transferring data from a digital camera or portable information terminal device to the computer body, This is a convenient storage medium when printing data directly to a printer, and conversely when transferring computer data to these electronic devices.
[0003]
However, since this IC card is currently very small in shape, it can be easily inserted incorrectly in the front or back or front-rear direction, and may be pulled out once inserted. Has a retaining function.
For example, the IC card 31 shown in FIG. 11 has a length of 50.0 mm, a width of 21.5 mm, and a thickness of 2.8 mm, has ten electrodes 24 at the tip, and is used for locking on one side. A retaining recess 59 is formed, and an inclined surface 32 for preventing erroneous insertion and an erroneous insertion preventing groove 42 are formed at one corner.
[0004]
Conventionally, in order to lock the IC card 31 as described above, a locking spring in which a leaf spring is partially bent in a C shape has been arranged on the side surface of the insertion path. Then, when the IC card 31 is inserted in a normal state, when the protruding portion that is gradually bent into the C-shape of the locking spring is pushed by the inclined surface 32 for preventing erroneous insertion, and pushed to the position of the retaining recess 59, The locking spring is fitted and held in the retaining recess 59.
[0005]
[Problems to be solved by the invention]
In a conventional locking spring in which a leaf spring is partially bent in a C shape, if the IC card 31 is pulled out after being locked once, it is easily deformed, and there is a problem that the strength is insufficient as a preventive measure against disconnection. there were.
In addition, in the case where the front and back or front and back are inserted incorrectly, the locking spring in which the leaf spring is bent is easily deformed if it is strongly pushed into the corner portion of the IC card 31 where there is no inclined surface. There was a problem of insufficient strength.
[0006]
The present invention has been made in view of the above problems, and has a simple structure for a locking spring and, by increasing the strength, more reliably prevents unplugging after insertion and prevents erroneous insertion of the front and back or front and back. An object of the present invention is to provide an IC card connector that exhibits the above.
[0007]
[Means for Solving the Problems]
The present invention provides a thin box-shaped connector housing having an upper surface and a front surface opened by an insulating material, a cover that covers the upper surface of the housing, and has an upper surface portion, both side surface portions, and a rear surface portion, and a front surface of the connector housing. The IC card insertion slot is provided with a contact connected to the electrode of the IC card, a slider that moves forward and backward in conjunction with the IC card insertion / removal operation, and the slider provided when the IC card is pushed in. A lock mechanism that holds the lock due to the engagement between the lock spring and the recess on the side of the IC card and releases the lock by releasing the engagement between the lock spring and the recess on the side of the IC card when the IC card is pushed out in the IC card connector provided with the a section, the IC card insert port has an electrode on the lower surface, omission for locking on one side stop A first IC card having a concave portion and a curved surface for preventing erroneous insertion that is curved at one corner, and an electrode on the lower surface, which is slightly wider and longer than the first IC card. The overlapping part of the width and length of the IC card is shared so that two types of IC cards of the second short IC card can be inserted, and different parts are formed extending in the width direction and the thickness direction, The lock spring is provided in a lock spring mounting recess on the lower surface of the slider, and is press-fitted and fixed in a vertical mounting hole provided in the lock spring mounting recess, and is bent in a U shape laterally from the press-fit portion. A spring portion disposed so as not to extend and project on the sliding side of the slider with respect to the IC card, and provided on the other end of the spring portion, and a triangular portion is provided on the sliding side of the slider with respect to the IC card. A locking protrusion that can be moved freely, It is a direction substantially perpendicular to the moving direction of the slider integrally with the locking projection of the slider, and is not deformed by the pressing force from the locking projection side to the side opposite to the sliding side of the slider with the IC card. A metal plate is integrally formed with a metal plate to prevent the IC card extended with a sufficient width from being removed, and the housing is provided at the position where the IC card is pushed out when the IC card is pushed out. A notch recess is formed to allow the escape prevention part to advance, and the side part of the cover faces the position of the removal prevention part when the IC card is pushed in. A retaining piece for blocking the advancement of the retaining portion is formed, an engaging portion for the second IC card is formed at the front end portion of the slider, and a guide rail is integrally formed on the lower surface of the slider. The how The IC card connector is characterized in that a slider guide groove that reciprocates by fitting the guide rail is formed on a slider sliding surface of a ging .
[0008]
In the configuration as described above, the IC card 31 is inserted into the insertion slot 5.
When the IC card 31 is normally inserted, the inclined surface 32 comes into contact with the locking projection 50 of the lock spring 47 and is pushed in, so that the opposite-side removal preventing portion 51 protrudes into the cutout recess 14 on the other side. When the IC card 31 is further pushed in, the locking projection 50 is fitted into the recess 59 of the IC card 31, and the removal preventing part 51 is restored.
When the IC card 31 is pushed in this state, the slider 3 is also pushed together. At this time, the drop prevention part 51 is restored to its original position, and thus moves along the inner wall of the housing 1. Then, the locking mechanism 33 stops in a stable state, and the electrode 24 contacts the contact 7.
[0009]
When the IC card 31 is to be pulled out, the locking projection 50 is pushed in, but the stopper 51 is obstructed by the stopper piece 58 and cannot be pushed in, so the IC card 31 cannot be pulled out. . At this time, a space between the triangular locking protrusion 50 of the lock spring 47 and the slip-out preventing portion 51 on the other end side is formed with a sufficiently constant width, so that it deforms even when a force is applied. There is nothing.
[0010]
If the IC card 31 is inserted in the reverse direction (or front and back) by mistake, the drop prevention part 51 protrudes from the other side, and if it is pushed further, the drop prevention part 51 comes into contact with the end face of the notch recess 14. Thus, the movement of the IC card 31 and the slider 3 is prohibited.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
A first embodiment of an IC card connector according to the present invention will be described with reference to FIGS.
The IC card connector of the present invention includes a thin box-shaped housing 1 shown in FIG. 2A, a cover 2 formed by bending a metal plate shown in FIG. 2B, and the housing 1 and the cover 2. The slider 3 shown in FIG. 3 housed inside is configured as a main part.
[0012]
The housing 1 is made of an insulating material, such as LCP, in a thin box shape having a width of 33.6 mm, a depth of 45.6 mm, and a height of 4.4 mm. The IC card shown in FIG. IC card insertion slot 5 into which IC card 31 is inserted, and IC card insertion slot 4 for another IC card (not shown) that is slightly wider but shorter in length are connected to the IC card. It is formed according to the difference in shape. These IC card insertion ports 4 and 5 share the overlapping portion of the width and thickness of the IC card, and are formed by extending different portions in the width direction and the thickness direction, and are provided with a guide step 12. ing. Further, locking projections 20 when the cover 2 is covered are integrally formed on the left and right outer surfaces and the rear outer surface of the housing 1.
[0013]
A contact 6 made of phosphor bronze for an IC card (not shown) is provided at an intermediate depth position inside these insertion ports 4 and 5, and a contact portion curved in a letter-like shape at the tip of the contact 6 is a housing 1. It is formed at a height that protrudes obliquely from the approximate center of the bottom surface 17 in the depth direction and does not hinder the insertion of the IC card 31. The pin terminal 9 at the base end portion of the contact 6 faces the lower surface on the front side of the housing 1 and is connected to a printed circuit board or the like.
[0014]
An IC card contact 7 made of phosphor bronze is formed from the rear end of the housing 1 toward the insertion side, further inside the contact 6. The contact 7 is formed at a slightly higher position than the contact 6. The pin terminal 10 at the rear end of the contact 7 slightly protrudes from the rear end of the housing 1 and is connected to a printed circuit board or the like. In addition, guide portions 13 that are located in both sides of the contact 7 and guide the insertion of the IC card 31 inside the insertion opening 5 are formed so as to be inclined upward from the front side of the insertion toward the back. .
[0015]
The cover 2 is formed by vertically bending a left side surface portion 53, a right side surface portion 54, a rear surface portion 55, and a front surface portion 56 from the upper surface portion 52 to the left and right sides and the front and rear sides, respectively. 54 and the rear surface portion 55 are formed with fitting holes 57 that engage with the locking projections 20 of the housing 1, respectively. Further, the cover 2 is formed with a retaining piece 58 vertically bent at a position desired by the notch recess 14 on the left side surface of the housing and slightly inward, and the upper surface portion A part 52 is cut and raised to form a detachment prevention spring portion 37.
[0016]
The slider 3 is placed on the slider sliding surface 8 at the left back of the housing 1.
As shown in the perspective view seen from the top surface of FIG. 3 (a) and the perspective view seen from the bottom surface of FIG. 3 (b), the slider 3 has a front end facing the insertion ports 4 and 5, An engagement portion 38 for an IC card (not shown) is formed, a lock pin receiving hole 44 for a lock mechanism portion 33 described later is formed, and a return spring receiving recess 43 is formed at the rear end portion. . Further, the IC card engaging portion 39 and the erroneous insertion preventing projection 40 curved from one side surface to the rear end portion are integrally formed, and a lock spring mounting hole 60 is formed slightly inside the other side surface. . Lock spring mounting recesses 41 are formed on the bottom surface so as to communicate with both side surfaces, and guide rails 45 are integrally formed at three locations, and are reciprocated by fitting into the slider guide groove 11 of the slider sliding surface 8. It is supposed to be.
[0017]
The lock spring 47 is formed by stamping and bending a metal plate, press-fitting portion 48 for press-fitting and fixing, a spring portion 49 curved in a U-shape, a locking projection 50 projecting in a triangular shape, and the other end. It has each part with the omission prevention part 51 of the side. In particular, the triangular locking protrusion 50 and the other-end-side drop prevention portion 51 are formed with a sufficiently constant width so as not to be deformed even when a force is applied. It acts as a return device and is configured not to contact directly when the IC card 31 is attached or detached. Then, when the lock spring 47 is fitted into the lock spring mounting recess 41 on the bottom surface of the slider 3 and the press-fitting portion 48 is press-fitted and fixed in the lock spring mounting hole 60, the locking projection 50 is located on one side of the slider 3. It is slightly protruded and incorporated so that the removal preventing part 51 is substantially the same surface as the other side surface.
[0018]
Next, the lock mechanism 33 will be described with reference to FIGS.
The lock mechanism 33 is formed at one end continuous with the slider sliding surface 8 and is composed of a heart cam 34, a guide groove 36 around the heart cam 34, and a lock pin 35 that moves in the guide groove 36. . The guide groove 36 has an inclined surface and a stepped portion as shown in FIG. 6 shown as a straight line in the drawing, and a lock fitted into the lock pin receiving hole 44 of the slider 3 by reciprocation of the slider 3. The other end of the pin 35 moves counterclockwise as indicated by the arrow in FIG. 4 while intermittently stopping in the direction of the points A, B, C, D, A... In order to prevent the lock pin 35 from coming out of the slide groove 36 at the time of movement, the lock pin 35 is urged from above by a detachment prevention spring portion 37 that is cut and raised downward in a tongue shape. Yes.
[0019]
In FIGS. 1 and 2, 15 on the left side and 16 on the right side are insertion end determination terminals for an IC card (not shown), which are formed of a material having elasticity and conductivity such as phosphor bronze. The leading ends of 15 and 16 are faced to the side of the insertion slot 4 and are moved in and out by inserting and removing an IC card (not shown) to control operations such as reading and writing.
[0020]
Next, the attaching / detaching operation of the IC card 31 in the first embodiment of the present invention will be described.
The IC card 31 is inserted into the IC card insertion slot 5 shown in FIGS. 1A, 1B, 1C and 2A with the electrode 24 facing downward. The IC card 31 is guided and inserted into the insertion slot 5 without fitting into the other insertion slot 4. At this time, the slider 3 is pushed out by the return spring 46, and the lock pin 35 is at point A of the guide groove 36.
[0021]
When the IC card 31 continues to be inserted, the tip part is pushed further into the back while lightly contacting the contact 6, the inclined surface 32 moves along the side surface of the slider 3, and the lock spring 47 provided on the slider 3 Contact the locking projection 50. The locking protrusion 50 is pushed against the spring portion 49, and the opposite-side removal preventing portion 51 protrudes from the other side surface. The tip of the IC card 31 is in contact with the IC card engaging portion 39 as shown by a two-dot chain line in FIG. 7A, and the IC card erroneous insertion preventing protrusion 40 and the erroneous insertion preventing groove 42 are engaged. Until the lock spring 47 is restored, the locking protrusion 50 is fitted into the concave portion 59 on the side surface of the IC card 31, and the slip-out preventing portion 51 on the opposite side returns.
[0022]
When the IC card 31 is pushed in this state, the slider 3 is pushed together against the spring 46. At this time, since the drop prevention unit 51 has returned to its original position, the drop prevention unit 51 moves without being disturbed by the retaining piece 58. Then, the lock pin 35 moves from the point A to the point B of the guide groove 36, and is returned to the point C along the guide groove 36 of the heart cam 34 by the spring 46 from the point B, and stops in a stable state. As shown in FIG. 1B, the electrode 24 contacts the contact 7.
[0023]
If the IC card 31 is pulled out with the IC card 31 fully inserted, the locking protrusion 50 fitted in the recess 59 on the side surface of the IC card 31 will be pushed in, but the opposite side will come off. The prevention part 51 is obstructed by the retaining piece 58 and cannot be pushed in, and the IC card 31 cannot be pulled out. At this time, a space between the triangular locking protrusion 50 of the lock spring 47 and the slip-out preventing portion 51 on the other end side is formed with a sufficiently constant width, so that it deforms even when a force is applied. There is nothing.
In order to remove the IC card 31, once the IC card 31 is pushed against the spring 46, the lock pin 35 moves from the point C to the point D of the guide groove 36. is returned to point a stop in a stable state, IC card 31 is returned to its original position as shown in solid line in FIG. 7 (a), the electrode 24 is separated from the contact 7. When the IC card 31 is pulled out from this state, the locking projection 50 of the lock spring 47 is pushed against the spring portion 49, and the opposite-side removal preventing portion 51 protrudes from the other side surface and is easily pulled out.
[0024]
When the IC card 31 is inserted in the reverse direction (or front and back) by mistake, the right-angled tip portion resists the locking protrusion 50 of the lock spring 47 against the spring portion 49 as shown in FIG. The other side prevention part 51 protrudes from the other side. When the IC card erroneous insertion preventing protrusion 40 is brought into contact with the IC card erroneous insertion preventing projection 40 as it is and further pushed in, the removal preventing part 51 comes into contact with the end face of the retaining piece 58 and the movement of the IC card 31 and the slider 3 is prohibited.
[0025]
Next, a second embodiment of the present invention will be described with reference to FIGS.
Although basically the same as the first embodiment, the differences are as follows.
(1) In the first embodiment, not only the IC card 31 but also other shapes of IC cards can be supported, but the second embodiment is configured to support only the IC card 31. ing.
(2) In the first embodiment, the electrode 24 of the IC card 31 is inserted with the lower surface. However, in the second embodiment, the electrode 24 of the IC card 31 is inserted with the upper surface. ing. Along with this, the positions of the slider 3 and the lock mechanism 33 are configured on the right side of the housing 1.
(3) In the first embodiment, the notch recess 14 is formed to be slightly longer, and the retaining piece 58 having a length about half that of the notch recess 14 is formed by folding the cover 2. In the embodiment, the notch recess 14 is formed to be short, and the retaining piece 58 is configured to have a part of the inner wall of the housing 1.
(4) With the configuration in which the electrode 24 of the IC card 31 is inserted on the upper surface in the second embodiment, the lock spring 47 needs to be floated by the thickness of the portion where the recess 59 is formed. Therefore, a slider cradle 63 is provided on a part of the slide sliding surface 8.
(5) In the first embodiment, the detachment prevention spring portion 37 of the cover 2 that urges the lock pin 35 is cut and raised from the lock mechanism portion 33 side. In the second embodiment, the detachment prevention spring of the cover 2 is provided. Since the portion 37 is cut and raised from the slider 3 side, a spring receiving groove 62 is formed on the upper surface of the slider 3.
Except for the above differences, there is no difference between the first embodiment and the second embodiment.
[0026]
An operation of attaching / detaching the IC card 31 having the above configuration will be described.
In FIG. 10A, the IC card 31 is inserted into the insertion slot 5 and the electrode 24 is inserted upward. At this time, the slider 3 is pushed out by the return spring 46, and the lock pin 35 is at point A of the guide groove 36 (hereinafter the same as FIG. 4).
[0027]
When the IC card 31 is continuously inserted, the inclined surface 32 moves along the side surface of the slider 3 and comes into contact with the locking projection 50 of the lock spring 47. The locking projection 50 is pushed against the spring portion 49 so that the opposite-side removal preventing portion 51 protrudes into the cutout recess 14 on the other side surface. The tip portion of the IC card 31 is in contact with the IC card engaging portion 39 as shown by a two-dot chain line in FIG. 10A, and the IC card erroneous insertion preventing projection 40 and the erroneous insertion preventing groove 42 are engaged. Until the lock spring 47 is restored, the locking protrusion 50 is fitted into the recess 59 of the IC card 31, and the removal prevention part 51 on the opposite side returns.
[0028]
When the IC card 31 is pushed in this state, the slider 3 is pushed together against the spring 46. At this time, the drop prevention part 51 is restored to its original position, and thus moves along the inner wall of the housing 1. Then, the lock pin 35 moves from the point A to the point B of the guide groove 36, and is returned to the point C along the guide groove 36 of the heart cam 34 by the spring 46 from the point B, and stops in a stable state. The electrode 24 contacts the contact 7.
[0029]
If the IC card 31 is pulled out with the IC card 31 fully inserted, the locking protrusion 50 fitted in the recess 59 on the side surface of the IC card 31 will be pushed in, but the opposite side will come off. The prevention part 51 is obstructed by the inner wall of the housing 1 and cannot be pushed in, and the IC card 31 cannot be pulled out. At this time, a space between the triangular locking protrusion 50 of the lock spring 47 and the slip-out preventing portion 51 on the other end side is formed with a sufficiently constant width, so that it deforms even when a force is applied. There is nothing.
In order to remove the IC card 31, once the IC card 31 is pushed against the spring 46, the lock pin 35 moves from the point C to the point D of the guide groove 36. The IC card 31 returns to the point A and stops in a stable state, and the IC card 31 returns to the original position, and the electrode 24 is separated from the contact 7 and extracted.
[0030]
When the IC card 31 is mistakenly inserted in the reverse direction (or front and back), the right-angled tip portion resists the locking protrusion 50 of the lock spring 47 against the spring portion 49 as shown in FIG. The other side prevention part 51 protrudes from the other side. When the IC card erroneous insertion preventing protrusion 40 is brought into contact as it is and further pushed in, the removal preventing part 51 comes into contact with the end face of the notch recess 14 and the movement of the IC card 31 and the slider 3 is prohibited.
[0031]
【The invention's effect】
According to the first aspect of the present invention, the structure of the locking spring is simple and high in strength, and can more reliably exhibit the function of preventing the removal after insertion and preventing erroneous insertion of the front and back or the front and back. . Further, the lock spring is formed with a sufficient width so as not to be deformed even by a pressing force from the engaging projection side. Furthermore, the operation of the lock spring coming-off prevention portion to advance and retreat by the notch recess and the retaining piece or to be engaged and disengaged is surely performed. Furthermore, the spring portion of the lock spring is bent and extended in a U shape laterally from the press-fit portion, and is disposed so as not to protrude to the sliding side of the slider with the IC card, and only serves as a return.
Incidentally, this embodiment of the lock spring has a length of about 8 mm. Since it is such a small spring component, by adopting a U-shaped curve, this spring part is configured to simply act as a return and not to contact directly when the IC card is attached or detached.
The IC card insertion slot is a first IC having an electrode on the lower surface, a recess for locking to be formed on one side surface, and a curved surface for preventing erroneous insertion at one corner. It can be used for two types of IC cards: a card and a second IC card having an electrode on the lower surface and a width slightly longer than the first IC card.
Since the guide rail is integrally formed on the lower surface of the slider and the slider guide groove is formed on the slider sliding surface of the housing, the guide rail can be fitted into the slider guide groove to smoothly reciprocate.
[Brief description of the drawings]
1A and 1B show a first embodiment of an IC card connector according to the present invention, in which FIG. 1A is a cross-sectional view taken along line BB in FIG. 1C, and FIG. Sectional drawing and (c) are front views.
2 is an exploded view of the IC card connector of FIG. 1, wherein (a) is a perspective view of a housing and (b) is a perspective view of a cover.
3 is an exploded view of a slider and a lock spring in the IC card connector of FIG. 1. FIG. 3A is a perspective view seen from the top surface, and FIG. 3B is a perspective view seen from the bottom surface.
4 is an enlarged plan view of a lock mechanism and a slider in the IC card connector of FIG. 1. FIG.
5 is a cross-sectional view of the IC card connector of FIG. 4 taken along line CC.
6 is a cross-sectional view when the guide groove in the IC card connector of FIG. 4 is linearly replaced.
7 is a cross-sectional view of the main part when the IC card is inserted into the IC card connector of FIG. 1, where (a) is a diagram of normal insertion, and (b) is an incorrect insertion with the front and back reversed. FIG.
FIGS. 8A and 8B are exploded views of a second embodiment of an IC card connector according to the present invention, in which FIG. 8A is a perspective view of a housing, and FIG. 8B is a perspective view of a cover;
9 is an exploded view of the slider and the lock spring in the IC card connector of FIG. 8, wherein (a) is a perspective view seen from the top surface, and (b) is a perspective view seen from the bottom surface.
10 is a cross-sectional view of the main part when the IC card is inserted into the IC card connector of FIG. 8, (a) is a diagram when it is normally inserted, and (b) is an incorrect insertion with the front and back reversed. FIG.
FIGS. 11A, 11B, 11C and 11E are a front view, a plan view, a partially cut left side view, and a right side view, respectively, of an IC card.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Housing, 2 ... Cover, 3 ... Slider, 4 ... Insertion port, 5 ... Insertion port, 6 ... Contact, 7 ... Contact, 8 ... Slider sliding surface, 9 ... Pin terminal, 10 ... Pin terminal, 11 ... Slider Guide groove, 12 ... Guide stepped portion, 13 ... Guide portion, 14 ... Notch recess, 15 ... Insertion end determination terminal, 16 ... Insertion end determination terminal, 17 ... Bottom surface, 18 ... Protrusion, 19 ... Return spring receiving recess, DESCRIPTION OF SYMBOLS 20 ... Locking protrusion, 24 ... Electrode, 26 ... Slider stopper part, 31 ... IC card, 32 ... Inclined surface, 33 ... Locking mechanism part, 34 ... Heart cam, 35 ... Lock pin, 36 ... Guide groove, 37 ... Detachment Prevention spring part 38 ... Engagement part 39 ... Engagement part 40 ... Misinsertion prevention projection 41 ... Lock spring mounting recess 42 ... Misinsertion prevention groove 43 ... Return spring receiving recess 44 ... Lock pin receiving hole 45 ... Guide rail, 6 ... Return spring, 47 ... Lock spring, 48 ... Press-fit portion, 49 ... Spring portion, 50 ... Locking projection, 51 ... Drop prevention portion, 52 ... Top portion, 53 ... Left side portion, 54 ... Right side portion, 55 ... Rear surface portion 56... Front portion 57. Retaining hole 58. Retaining piece 59. Recessed portion 60. Lock spring mounting hole 61. Incorrect insertion preventing step portion 62. Spring receiving groove 63.

Claims (1)

A thin box-shaped connector housing having an upper surface and a front surface opened by an insulating material, a cover that covers the upper surface of the housing, and has an upper surface portion, both side surfaces, and a rear surface portion, and an IC card insertion provided on the front surface of the connector housing In the mouth, a contact connected to the electrode of the IC card, a slider that moves forward and backward in conjunction with the IC card attachment / detachment operation, and a lock spring and IC provided on the slider when the IC card is pushed in A lock mechanism for holding a lock by engagement with a recess on the side of the card and releasing the lock by releasing the engagement between the lock spring and the recess on the side of the IC card when the IC card is pushed out in the IC card connector that, the IC card insertion slot has an electrode on the lower surface, the retaining recess forms for locking on one side And a first IC card having an inclined surface for preventing erroneous insertion that is curved at one corner and an electrode on the lower surface, the width being slightly wider and shorter than the first IC card. The lock spring is formed by sharing overlapping portions of the width and length of the IC card so that two types of IC cards of the second IC card are inserted, and extending different portions in the width direction and the thickness direction. Is provided in a lock spring mounting recess on the lower surface of the slider, press-fitted to press fit into a vertical mounting hole provided in the lock spring mounting recess, and extends from the press-fitted portion to the U-shaped sideways. A spring portion arranged so as not to protrude on the sliding side of the slider with respect to the IC card, and provided at the other end of the spring portion, a triangular portion can be projected and retracted on the sliding side of the slider with respect to the IC card. Locking protrusion and this locking protrusion And a direction substantially orthogonal to the moving direction of the slider integrally wide enough so as not to deform by pressure from the sliding side with the engagement projection side to the opposite side of the IC card in the slider A removal prevention part that prevents the extended IC card from being pulled out is integrally formed of a metal plate, and this housing faces the position of the removal prevention part when the IC card is pushed out. A notch recess is formed to allow the advancement of the removal prevention part, and the advancement of the removal prevention part is made on the side of the cover so as to face the position of the removal prevention part when the IC card is pushed in. A retaining piece is formed at the front end of the slider, an engaging portion for the second IC card is formed at the front end of the slider, and a guide rail is integrally formed on the lower surface of the slider. An IC card connector characterized in that a slider guide groove that reciprocates by fitting the guide rail is formed on a sliding surface of the rider .

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