JP4010955B2 - Card connector - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention includes a body having a contact, a slider that slides between the ejecting position and the locking position with respect to the body, a biasing mechanism that applies a biasing force to the slider in the ejecting direction, and the slider And a locking mechanism for holding the cam in the locking position. The locking mechanism has a cam groove formed in a heart shape with respect to the slider, and one end is engaged with the cam groove, and the other end is supported on the body side. When a card is inserted into the body and the slider that comes into contact with the card is slid to the locked position, a lock point of the cam groove is formed. One end of the hook pin reaches the lock position to hold the slider in the locked position, and in this locked state, the card is operated again in the insertion direction. It was in the disengaged one end of the hook pin from the locking point, about the card connector operating configuration of the locking mechanism is configured to allow sliding operation of the eject direction of the slider by the biasing force of the spring.
[0002]
[Prior art]
As the card connector configured as described above, a slider 7 (slider of the present invention) is provided so as to be slidable with respect to the card holder 5, and a heart-shaped cam groove 19 is formed on the card holding member 5, There is a rocking member 27 (hook pin of the present invention) in which the tip 31 engages with the cam groove 19 in the slider 7, and an engaging protrusion 29 is formed in the middle of the rocking member 27. . In this card connector, when the card member 3 (the card of the present invention) is inserted into the card holding member 5, the slider 7 is operated by contact with the card member 3, and as a result, the tip of the swinging member 31 becomes the cam groove. At the same time as reaching the predetermined position of 19 and reaching the locked state, the engagement protrusion 29 increases the protrusion amount of the card member 3 with respect to the engagement recess 13 as the posture of the swing member 31 changes, and this engagement It is configured to be deeply engaged with the mating recess 13 to prevent dropping (see, for example, Patent Document 1).
Further, as the card connector configured as described above, the elastic lock piece 50 is attached to the eject member 41 (the slider of the present invention), the guide projection 60 is formed on the connector housing 2, and the lever guide groove 42 of the heart cam 43 is formed. A cam lever 45 (hook pin of the present invention) engaged with the eject member 41 and the eject member 41 are linked. In this card connector, when the card 10 is inserted, the guide protrusion 60 abuts against the elastic lock piece 50 and the locking portion 50b is engaged with the notch 18 of the card 10 to prevent the card 10 from falling off. (For example, refer patent document 2).
[0003]
[Patent Document 1]
JP 2001-185286 A (paragraph numbers [0019] to [0031], FIGS. 5 and 7)
[Patent Document 2]
JP 2002-134224 A (paragraph numbers [0024] to [0041], FIG. 4, FIG. 7, FIG. 9, FIG. 10)
[0004]
[Problems to be solved by the invention]
When considering a card-like storage medium (card of the present invention) used for a digital camera, a mobile phone, or a personal digital assistant (PDA), such as a Memory Stick (trademark) or an SD card (trademark) In addition, as described in Patent Document 1 and Patent Document 2, a relatively small storage medium is often set in the apparatus main body via a card connector having a heart cam type lock mechanism.
[0005]
In this way, the card connector having the heart cam type locking mechanism is configured such that the slider that contacts the card by pushing the card into the body of the card connector holds the card when the locking mechanism reaches the locking position. By operating the card in the direction to push it again, the lock mechanism is unlocked, and the card is pushed out together with the slider by an urging force such as a spring.
[0006]
However, considering the operation for removing the card after holding the card with respect to the card connector having the structure described above, it is not recognized that it is necessary to operate the card in the pushing direction again in order to remove the card. In the case of a user or a user who is not accustomed to removing the card, there are cases where the operation is performed in the direction in which the card is accidentally extracted. If the card is accidentally removed in this way, even if the card can be removed, the slider will remain in the locked position, and after that, it will not be possible to perform proper operations and improvements are desired. Yes.
[0007]
In particular, as shown in Patent Literature 1 and Patent Literature 2, the card is held by engaging an engagement piece into a concave portion of the card (engagement concave portion of Patent Literature 1, notch of Patent Literature 2). The card connector has a function of preventing the card from dropping out in the locked state. However, when the card connector is mistakenly operated in the direction of removing the card, there is a possibility that the engaging structure with respect to the concave portion may be damaged and there is room for improvement. .
[0008]
It is an object of the present invention to rationally provide a card connector that can properly operate the following operations even when the card is accidentally pulled out after the card is held in the card connector having a heart cam type locking mechanism. The point is to configure.
[0009]
[Means for Solving the Problems]
The features, operations and effects of the card connector according to claim 1 of the present invention are as follows.
〔Characteristic〕
A body having a contact; a slider that slides between the eject position and the lock position with respect to the body; an urging mechanism that applies an urging force to the slider in an eject direction; and the slider that is in the lock position. A locking mechanism for holding the cam, and the locking mechanism includes a cam groove formed in a heart shape with respect to the slider, and a hook pin having one end engaged with the cam groove and the other end supported on the body side. When a card is inserted into the body and the slider that contacts the card is slid to the lock position, the hook pin is connected to the lock point of the cam groove. When one end reaches and holds the slider in the locked position, and the card is operated again in the insertion direction in this locked state. In the card connector in which the operation mode of the lock mechanism is set so that one end of the hook pin is detached from the lock point and the slide operation in the eject direction of the slider is permitted by the biasing force of the spring, the slider is the lock In a state where the card is held at a position, when a force in the pulling-out direction is applied to the card, an unlocking mechanism is provided for detaching one end of the hook pin from the lock point in conjunction with this operation. In the point.
[0010]
[Action / Effect]
According to the above feature, when the slider that contacts the card after inserting the card inside the body reaches the lock position, one end of the hook pin that engages the cam groove of the lock mechanism reaches the lock point, and the slider Is held in the locked position. In this locked state, when the card is operated in the removal direction, the unlocking mechanism releases the locked state by releasing one end of the hook pin from the lock point in conjunction with the operation in the card removal direction, and The slider is operated to the eject position by the urging force of the mechanism. That is, even when the user removes the card by mistake and operates the card in the pulling-out direction, the slider always operates to the eject position, so that it is possible to take out using the biasing force of the biasing mechanism. In addition, even when the card is set again after removal, an operation in an appropriate form is possible. As a result, even if you hold the card in the card connector with a heart cam lock mechanism and then accidentally pull out the card without compromising the operation of removing the card by operating it again in the pushing direction. Thus, the card connector that can properly operate the subsequent operations is rationally configured.
[0011]
The features, functions and effects of the card connector according to claim 2 of the present invention are as follows.
〔Characteristic〕
The card connector according to claim 1, wherein when the card is inserted into the body, an engagement piece is formed on the slider for engaging with the concave portion of the card to prevent the card from falling off, and the unlocking mechanism includes In a situation where the slider is held in the locked position, when a force in the pulling direction is applied to the card, a displacement force when the engaging piece is released from the recess is determined by the hook pin. In the point which is provided with the connection member which transmits to the direction which makes it detach | leave from the said lock point with respect to one end side.
[0012]
[Action / Effect]
According to the above feature, after the card is inserted into the body, the engaging piece formed on the slider is engaged with the concave portion of the card to prevent the card from dropping out before the slider reaches the lock position. Thereafter, the slider reaches the lock position and is held. When the card is operated in the extraction direction in this locked state, the displacement force when the engagement piece is released from the concave portion of the card during the operation in the extraction direction is applied to the hook pin against the one end side of the hook pin. The direction of release from the lock point is transmitted and the lock mechanism is unlocked. When the lock is released, the slider moves to the eject position and the card can be removed. As a result, by using the structure that prevents the locked card from dropping out and the structure of the lock mechanism, the card can be properly removed even if the card is accidentally removed. It became.
[0013]
The features, functions and effects of the card connector according to claim 3 of the present invention are as follows.
〔Characteristic〕
3. The card connector according to claim 2, wherein the engagement piece is disposed on a surface of the slider opposite to the cam groove forming surface, and the engagement piece is a spring toward a direction along the depth direction of the cam groove. When the engagement piece is displaced in the pushing direction against the urging force of the spring, the displacement force is transmitted to one end side of the hook pin, and the one end side is separated from the lock point. The link member is composed of a rod-shaped member to be detached.
[0014]
[Action / Effect]
According to the above feature, when operated in the direction of pulling out the locked card, the engaging piece engaged with the concave portion of the card is displaced in the pushing direction, and this displacement force is constituted by a rod-shaped member. It is transmitted to one end side of the hook pin by the linkage member, and one end side of the hook pin is detached from the lock point. That is, by disposing the engaging piece and the linking member in a positional relationship between the front and back sides and configuring the linking member with a rod-shaped member, when the engaging piece is displaced in the pushing direction, the rod-shaped member directly It is realized that a force is applied to one end of the hook pin in the detaching direction. As a result, the arrangement of the engagement piece and the lock mechanism makes it very simple, but even if the card is accidentally pulled out, the lock mechanism is securely unlocked and the slider is ejected. The card can be properly removed by operating in the direction.
[0015]
The features, functions and effects of the card connector according to claim 4 of the present invention are as follows.
〔Characteristic〕
The card connector according to any one of claims 1 to 3, wherein the lock mechanism includes the lock point at which one end of the hook pin is positioned when the slider is at the lock position, and the slider at an eject position. In some cases, the one end of the hook pin is disposed opposite to the eject point, and the one end of the hook pin is directed from the lock point to the eject point when the lock state is released by the unlocking mechanism. This is in the point of being provided with a groove-like separation path that allows movement.
[0016]
[Action / Effect]
According to the above feature, when the locked card is operated in the direction of removing, the unlocking mechanism is disengaged from the lock point at one end of the hook pin, and after this disengagement, the slider is ejected by the biasing force of the biasing mechanism. However, when the slider moves in this way, one end of the hook pin can be moved to the eject point via the separation path. In other words, if the release path is not formed, it can be imagined that after one end of the hook pin is detached from the lock point, this one end is completely detached from the cam groove and it is difficult to return to the eject point. In the case where a separation path that allows movement of one end of the hook pin is formed, it is not necessary to largely disengage this one end from the cam groove, and this one end can be reliably returned to the ejection point. As a result, one end of the hook pin can be reliably moved to the ejection point, and the subsequent operations can be performed properly.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
As shown in FIG. 1 or FIG. 2, a body B having a plurality of first contacts 1 and second contacts 2 arranged in parallel, an eject position Ej and a lock along the card insertion / removal direction with respect to the body B A slider S formed to be slidable between positions Lo (a first concept of the first lock position Lo1 and the second lock position Lo2), and a compression coil spring 3 (which applies an urging force to the slider S in the eject direction) An example of an urging mechanism, a lock mechanism L that holds the slider S at the lock position Lo, and a case C that covers them are configured as a card connector.
[0018]
This card connector is provided in a device such as a digital camera, a mobile phone, or a personal digital assistant (PDA), and is represented by a Memory Stick (trademark) or an SD card (trademark). The card M and the card M represented by Microdrive (trademark) as a small hard disk are mounted and separated.
[0019]
FIG. 1 shows a memory stick type card M. The card M is entirely made of a resin material, and a plurality of electrodes P are formed in parallel at the end of the card. Are removed in an arc shape to form a notch N for preventing erroneous insertion, and a part of the side edge is removed to form a recess D for engagement. Further, this card connector is configured as a dual-purpose type that allows use of the memory stick type card M shown in FIG. 1 and a small card (not shown) having a reduced size in the insertion / removal direction.
[0020]
When the card M is inserted into this card connector, the slider S reaches the first lock position Lo1 or the second lock position Lo2 by the contact with the card M, and the lock mechanism L is locked. Keep state. When the memory stick type card M is inserted into the card connector, the first contact 1 comes into contact with the electrode P of the card M, and instead of the small card (not shown). ) Is inserted, the card electrode comes into contact with the second contact 2. Next, when the card M is operated again in the insertion direction from this locked state, the lock by the lock mechanism L is released, and the slider S moves to the eject position Ej by the urging force of the compression coil spring 3. As a result of the card M being pushed out, the card M can be taken out (details of this operation will be described later).
[0021]
The case C is formed by press-molding a metal material that is relatively easy to process and has appropriate rigidity, such as a thin plate of an aluminum alloy or a copper alloy, and the card M inserted into the body B is inserted into the case C. Has a function of guiding. In addition, the case C is integrally formed with a leaf spring portion 5 that cuts out a part of the portion that guides the slider S and applies a biasing force to the hook pin 4 of the lock mechanism L.
[0022]
The body B is integrally formed with a body portion 10 into which the card M is inserted by an insulating resin material and a guide portion 11 for guiding the slider S, and the first contact with respect to the body portion 10. 1 and a second contact 2 are provided. Further, a lock-side stopper 12 is formed at an end portion of the guide portion 11 in the lock direction, and an eject-side stopper 13 is integrally formed at an end portion in the eject direction.
[0023]
The slider S includes a slide portion 20 that linearly slides while being guided by the guide portion 11 of the body B, a contact portion 21 that is formed in a direction orthogonal to the slide portion 20, and a slide portion 20. A rib 22 for preventing erroneous insertion that contacts the notch N of the card M is integrally formed of a resin material at a portion extending over the contact portion 21. As shown in FIG. 3, the engagement piece 23 is provided in a state in which the engagement piece 23 can be withdrawn and retracted from the storage space 20 </ b> A formed in the slide portion 20 and is urged and urged by the compression spring 24. With this structure, when the card M is inserted, the engagement piece 23 is engaged with the recess D formed in the card M to prevent the card M from falling off. The engaging piece 23 is integrally formed with a guide body 23A that is in sliding contact with the inner surface of the storage space 20A and a rod-like protruding piece 25 (an example of a linking member) that protrudes in the direction opposite to the protruding direction of the engaging piece 23. Alternatively, it is formed by fitting another member (metal, resin, etc.), and this protruding piece 25 is inserted through a through hole 20B formed in the slide portion 20.
[0024]
The lock mechanism L includes a heart cam CAM formed on the surface of the slide portion 20 opposite to the surface on which the engagement piece 23 is disposed, and the hook pin 4. The heart cam CAM has a cam groove G having the shape shown in FIGS. 6 to 8, and the hook pin 4 bends both ends of a wire material having a relatively high rigidity such as a piano wire, and the cam groove G is formed at one end thereof. A scanning shaft 4A that engages with the ejector-side stopper 13 is formed, and a support shaft 4B that is swingably supported by the eject-side stopper 13 is formed on the other end side. The hook pin 4 can be contacted with the bottom of the cam groove G by the end of the copying shaft 4A by the pressure from the leaf spring portion 5 formed on the case C.
[0025]
The cam groove G has an eject point Ep where the scanning shaft 4A is positioned when the slider S is at the eject Ej position, and a first position where the scanning shaft 4A is positioned when the slider S is at the first lock position Lo1. Between the first lock point Lp1 and the eject point Ep, and when the slider S is in the second lock position Lo2, between the second lock point Lp2 where the scanning shaft 4A is located. It is formed in an annular shape. The superordinate concept of the first lock point Lp1 and the second lock point Lp2 is collectively referred to as a lock point Lp.
[0026]
The first lock point Lp1 or the second lock point Lp2 has a wall-like shape in which the copying shaft 4A is fitted so as to prevent the slider S from moving to the ejection position Ej by the urging force of the compression coil spring 3. A lock surface LS is formed.
[0027]
The cam groove G is formed in two systems between the eject point Ep and the first lock point Lp1 and the second lock point Lp2. Basically, the cam groove G is formed on the conventional heart cam. It has a structure that does not change. Specifically, an insertion lane Gin is formed from the eject point Ej toward the two lock points Lp1 and Lp2, a return lane Gre is formed from the first lock point Lp1 toward the eject point Ej, and these insertion lanes Gin and A second lock point Lp2 is arranged at a position close to the eject point Ep at an intermediate position from the return lane Gre. Further, a bypass lane Gb is formed between the insertion lane Gin reaching the first lock point Lp1 and the return lane Gre, and further, a separation lane Gd as a separation route is formed between the first lock point Lp1 and the return lane Gre. Forming.
[0028]
Of these cam grooves G, the insertion lane Gin has a groove depth set so that the lower side in the direction of movement of the scanning shaft 4A (the direction indicated by the arrow) is shallow (the bottom surface of the cam groove G is partially inclined). In the region extending from the insertion lane Gin to the first lock point Lp1, two return blocking portions Gs having a stepped groove depth are formed, and the first lock point Lp1 and the return lane Gre A return blocking portion Gs having a deep groove is also formed in a stepped manner at the boundary portion. Similarly, in the return lane Gre, the groove depth is set so that the lower side in the moving direction of the copying shaft 4A (the direction indicated by the arrow) becomes shallow (the bottom surface of the cam groove G is partially inclined). Also at the boundary portion between the return lane Gre and the eject point Ej, a return blocking portion Gs having a deep groove is formed in a stepped shape.
[0029]
The return blocking portion Gs is also formed at the corresponding portion of the second lock point Lp2 as in the first lock point Lp1. Note that the cam groove G has a return blocking portion Gs formed at a plurality of positions by reducing the groove depth on the lower side in the moving direction of the copying shaft 4A in the insertion lane Gin and the return lane Gre. The entire cam groove G is not required to be deepened.
[0030]
In the bypass lane Gb, when the insertion is stopped in the middle of the insertion of the card M or the like, when the slider S needs to return the copying shaft 4A to the ejection position Ej in the middle of the operating range, the copying shaft 4A is set to the second lock point Lp2. It was formed to prevent the inconvenience introduced in. Further, as will be described later, when the card M is held at the first lock position Lo1 and a force in the removal direction is applied to the card M, the release lane Gd is operated by a lock release mechanism R described later. This is for returning the copying shaft 4A from the cam groove G without releasing the copying shaft 4A when returning the copying shaft 4A to the ejection point Ep when the lock mechanism L is unlocked.
[0031]
As shown in FIG. 3, the through hole 20 </ b> B through which the protruding piece 25 formed integrally with the engaging piece 23 or by fitting another member (metal, resin, etc.) is inserted is the first lock point. It is formed at a position overlapping with Lp1. By setting the position in this way, when the engaging piece 23 is displaced in the direction of sinking with respect to the slide portion 20 of the slider, the projecting piece 25 contacts the edge of the copying shaft 4A of the hook pin 4. Thus, the scanning shaft 4A located at the first lock point Lp1 is pushed up, and the lock mechanism L is unlocked. Thus, the unlocking mechanism R is constituted by the protruding piece 25 that protrudes and operates in conjunction with the displacement of the engaging piece 23. After the protruding piece 25 is separated from the first lock point Lp1, the copying shaft 4A is The vehicle moves from the leaving lane Gd to the return lane Gre and finally reaches the eject point Ep.
[0032]
With this configuration, when the card M is not inserted into the card connector of the present invention, the slider S is at the eject position Ej, and the memory stick type card M is inserted into the card connector in this state. Then, the contact portion 21 of the slider S comes into contact with the end portion of the card M, the engagement piece 23 engages with the concave portion D of the card M, and the slider S moves in the locking direction against the urging force of the compression coil spring 3. Start moving to. By continuing this operation, the copying shaft 4A of the hook pin 4 reaches a position exceeding the first lock point Lp1, and then the pushing operation force is released, whereby the copying shaft 4A is guided to the return preventing portion Gs. As a result, as shown in FIG. 3, it moves to the first lock point Lp1 and reaches the locked state.
[0033]
In this locked state, the first contact 1 of the body B and the electrode P of the card M are brought into contact with each other, and the signal can be accessed. Next, when taking out the locked card M, the card M is operated again in the pushing direction so that the copying shaft 4A is guided to the return blocking portion Gs. As a result, the return lane Gre from the first lock point Lp1. After that, by releasing the pushing operation of the card M, the slider S is moved to the ejection position Ej by the urging force of the compression coil spring 3, and the card M is discharged together with the slider S. The Thus, in the state where the slider S has reached the ejection position Ej, the copying axis 4A reaches the ejection point Ep.
[0034]
In particular, in the present invention, when a user unfamiliar with taking out the locked card M accidentally picks up the card M and applies an operating force in the removal direction, as shown in FIG. The slider S is displaced to the side sinking into the slide portion 20, and in association with this displacement, the protruding piece 25 constituting the unlocking mechanism R contacts the shaft end of the copying shaft 4A located at the first lock point Lp1. As a result of moving the scanning shaft 4A in the pushing direction, as shown in FIG. 5, the scanning shaft 4A is separated from the first lock point Lp1, and the slider S is ejected by the biasing force of the compression coil spring 3. It operates up to Ej, and the card M can be taken out with this operation. The scanning shaft 4A that has left the first lock point Lp1 moves from the separation lane Gd to the return lane Gre and reaches the ejection point Ep.
[0035]
Further, when the card connector of the present invention is compared with a card connector that does not include the unlock mechanism R, the memory stick type card M that does not include the unlock mechanism R is held by the lock mechanism L. If the card M is mistakenly extracted, the slider S remains in the locked state. After that, when a smaller card M is inserted, the card M does not contact the slider S. Not only is there a sense of incongruity, but it is also possible to insert the card M shallower than the appropriate position or insert it deeper than the appropriate position, and after this insertion, it is extremely difficult to remove the card M. It becomes. On the other hand, in the present invention, even when the memory stick type card M is held by the lock mechanism L and the card M is mistakenly extracted, the slider S is always moved to the eject position Ej by the function of the lock release mechanism R. Therefore, even when a small card M is inserted after that, the slider S can be surely locked at the second lock position Lo2, and the above-described inconvenience does not occur.
[0036]
[Another embodiment]
In addition to the above-described embodiment, the present invention may be configured as follows (in this another embodiment, components having the same functions as those of the above-described embodiment are given the same numbers and symbols as in the embodiment). is doing).
[0037]
(A) When the slider S cannot be placed in a positional relationship where the surface on which the cam groove is formed and the surface provided with the engagement piece 23 cannot be placed on the front and back, the separating shaft 4A for detaching the scanning shaft 4A located at the lock point Lp The lock release mechanism R is configured to include a member and transmit the displacement of the engagement piece 23 to the release member via a link mechanism, a cam mechanism, or the like, and to release the copying shaft 4A from the lock point. With this configuration, the locked state can be released without being limited by the relative positional relationship between the engagement piece 23 and the heart cam CAM.
[0038]
(B) When the card M is inserted into the body B and the body B is provided with a contact member that contacts the card M in a state where the lock mechanism L reaches the locked state, the contact member is removed. The unlocking mechanism R may be configured with a linking member or the like so as to disengage the copying shaft 4A located at the lock point Lp of the heart cam CAM by making use of reaching the state of not contacting the card M.
[0039]
(C) In the embodiment of the invention, the card connector is configured so that two sets of contacts 1 and 2 are formed inside the body B so as to be compatible with two types of cards. Alternatively, the present invention may be applied to a card connector configured to support three or more types of cards M.
[0040]
(D) An elastic deformation portion similar to the spring plate is formed on a part of the slider S, and further, an engagement piece is formed on the elastic deformation portion so that the engagement piece is integrated with the slider. It is also possible to produce it. In this way, when the engagement piece is formed integrally with the slider, the number of parts can be reduced and the assembly is facilitated.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view of a card connector.
FIG. 2 is a diagram showing the plane and side surfaces of the body with the slider in the eject position.
FIG. 3 is a cross-sectional view showing the state of the body when the card is inserted and the state of the concave portion of the card, the engaging piece of the slider, and the protruding piece.
FIG. 4 is a cross-sectional view showing the state of the body when the card is operated in the removing direction, and the state of the concave portion of the card, the engaging piece of the slider, and the protruding piece.
FIG. 5 is a cross-sectional view showing the state of the body when the card is unlocked by operating the card in the removing direction, and the state of the concave portion of the card, the engaging piece of the slider, and the protruding piece.
FIG. 6 is a view showing a cam groove of a heart cam.
FIG. 7 is a diagram showing a movement path of the scanning shaft in the cam groove of the heart cam.
FIG. 8 is a perspective view showing the shape of the cam groove of the heart cam.
[Explanation of symbols]
1, 2 contacts
4 Hook pin
4A One end of hook pin
23 Engagement piece
24 Spring
25 Linking member
B body
D recess
G Cam groove
Gd departure route
L Lock mechanism
M card
R lock release mechanism
S slider
Ej Eject position
Lo lock position
Lp lock point

Claims (4)

A body having a contact; a slider that slides between the eject position and the lock position with respect to the body; an urging mechanism that applies an urging force to the slider in an eject direction; and the slider that is in the lock position. And a locking mechanism for holding the
The locking mechanism is configured in a heart cam type having a cam groove formed in a heart shape with respect to the slider, and a hook pin having one end engaged with the cam groove and the other end supported on the body side, When a card is inserted into the body and the slider contacting the card is slid to the locked position, one end of the hook pin reaches the lock point of the cam groove and the slider is moved to the locked position. In this locked state, when the card is operated again in the insertion direction, one end of the hook pin is detached from the lock point, and the slide operation in the eject direction of the slider by the biasing force of the spring is allowed. A card connector in which the operation mode of the locking mechanism is set,
In the state where the slider is held at the locked position, when a force in the pulling direction is applied to the card, the unlocking is performed to release one end of the hook pin from the lock point in conjunction with this operation. Card connector with mechanism. When the card is inserted into the body, the slider is formed with an engagement piece that engages with the concave portion of the card to prevent the card from falling off, and the lock release mechanism holds the slider in the locked position. In this situation, when a force in the pulling-out direction is applied to the card, a displacement force when the engaging piece is detached from the recess is changed from the lock point to one end side of the hook pin. The card connector according to claim 1, further comprising a linking member for transmitting in a direction of detachment. The engaging piece is disposed on the surface of the slider opposite to the cam groove forming surface, and the engaging piece is projected and urged by a spring in a direction along the depth direction of the cam groove. When the joint piece is displaced in the pushing direction against the urging force of the spring, the displacement force is transmitted to one end side of the hook pin, and the linkage is made by the rod-shaped member that separates the one end side from the lock point. The card connector according to claim 2, wherein the member is configured. The locking mechanism is configured so that the lock point at which one end of the hook pin is positioned when the slider is in the lock position and the eject point at which one end of the hook pin is positioned when the slider is in the eject position. And a groove-like disengagement path that allows one end of the hook pin to move from the lock point toward the eject point when the lock state is released by the lock release mechanism. The card connector according to any one of 1 to 3.

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