JP3774661B2 - Card connector - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a card connector, and more particularly to a card connector in which insertion of a card into a set position and ejection from the set position are performed by a so-called push-push operation.
[0002]
[Prior art]
This type of card connector is described in Japanese Patent Laid-Open No. 2001-185286 (prior example), which will be described with reference to FIGS. 16 and 17 are horizontal partial cross-sectional views showing the main part of the card connector described in the above publication, and FIG. 18 is an explanatory view showing the cam groove shape.
[0003]
The slider 300 is slidably held back and forth on the body 200 in which the card 100 is inserted and removed, and the slider 300 is always elastically biased backward by a spring 310. The slider 300 is provided with an engagement surface 320 that engages with the card 100 inserted into the body 200 and a plate piece portion 321 that fits into the recessed portion 112 on the back side of the card 100. When inserted into the body 200 in a normal posture, the card 100 engages with the engaging surface 320, and slides the slider 300 forward (arrow F) against the bias of the spring 310.
[0004]
A pin member 350 made of an elastic wire is attached to the slider 300 in a cantilever manner. In the pin member 350, an engaging body 330 is bent and formed at an intermediate portion, and a pin 340 is bent at a tip. On the other hand, the body 200 is integrally provided with a cam portion 370 provided with a cam groove 360 for guiding the pin 340, and further provided with a recess 110 on the back side on one side in the width direction of the card 100, and A recessed portion 112 is provided on the back side of the front end corner portion of the card 100. A cam mechanism is formed by a combination of the cam portion 370 and the pin member 330.
[0005]
As shown in FIG. 18, the cam groove 360 is located at the end of the groove-shaped forward path 361 and the groove-shaped forward path 361 for guiding the pin 340 to the front of the cam portion 370 (corresponding to the arrow F direction in FIG. 16). A locking portion 362 that locks the pin member 340 and a groove-shaped return path 363 that guides the pin member 340 to the rear of the cam portion 370 by using the locking portion 362 as a starting point and leads to the starting point of the groove-shaped forward path 361 are provided. Step portions 364, 365, and 366 that prevent the backward travel of the pin 340 are provided at the vicinity of the end point of the groove-shaped forward path 361, the position near the start point of the groove-shaped return path 363, and the junction of the groove-shaped return path 363 with the groove-shaped forward path 361 367 are provided.
[0006]
In this card connector, when the card 100 is inserted into the body 200 in a normal posture, the one end surface 101 of the card 100 pushes the engaging member 330 and displaces the pin member 350 while the slider 300 remains stopped at the initial position. By doing so, the engaging body 330 is retracted to the side. The displacement operation of the pin member 350 at this time is performed in a state where the pin 340 is located at the starting point of the groove-shaped forward path 361 shown in FIG. 18, and the cam groove 360 is sufficiently wide at this starting point position. It has become. Therefore, the displacement operation of the pin member 350 at this time is performed without difficulty.
[0007]
As described above, the one end face 101 of the card 100 pushes the engaging member 330 to displace the pin member 350, thereby retracting the engaging member 330 to the side, and then the deforming of the pin member 350 causes the engaging member 330 to move to the card. 100, the card 100 is engaged with the engagement surface 320 of the slider 300 positioned at the initial position by fitting the concave portion 112 of the card 100 to the plate piece 321, and thereafter The card 100 pushes the slider 300 from the initial position to the front F thereof. With this insertion operation, the pin 340 is locked to the locking portion 362 as shown in FIG. 16 via the groove-shaped forward path 361 of the cam groove 360. In this state, an electrode (not shown) of the card 100 is connected to an electrode (not shown) on the body 200 side.
[0008]
In the card connector described in the preceding example, when the card 100 is inserted into the body 200 in a normal posture, the engaging body 330 is fitted into the recess 110 of the card 100, so that the card 100 is forcibly and strongly pushed backward. As long as it is not pulled, the engagement body 330 is engaged with the card 100, thereby exhibiting a half-lock function in which the card 100 is prevented from moving backward from the slider 300. Further, in a state where the pin 340 is locked to the locking portion 362 of the cam groove 360, a full lock function that prevents the slider 300 from moving backward is exhibited. Further, when the pin 340 is locked to the locking portion 362 of the cam groove 360 and the card 100 is forcibly pulled backward, the one end surface 101 of the card 100 pushes the engaging body 330 in the retracting direction to push the pin. Since the member 350 is displaced, the full lock releasing function that the pin 340 leaves the engaging portion 362 and is pushed out of the stepped portion 366 is exhibited. Therefore, the pin 340 returns to the starting point of the groove-shaped forward path 361 via the groove-shaped return path 363, and the slider 300 returns to the initial position accordingly.
[0009]
On the other hand, when the card 100 is inserted into the body 200 in an inverted posture, as shown in FIG. 17, the other end face 102 of the card 100 rides on the engaging body 330 and retracts the engaging body 330 to the side. In such a case, the card 100 pushes the slider 300 from the initial position to the front F while the engaging member 330 is retracted to the side as shown in the drawing. In such a case, the pin 340 enters the narrow groove-shaped forward path 361 and is pressed against the groove wall 361a as shown in the figure, so that the pin member 350 is forced to be deformed.
[0010]
[Problems to be solved by the invention]
However, as described above, the other end surface 102 of the card 100 in which the card 100 has been inserted into the body 200 in an inverted posture rides on the engaging body 330 and retracts the engaging body 330, so that the pin 340 is inserted into the cam groove 360. If the pin member 350 is forcibly deformed while passing through the groove-shaped forward path 361, the pin member 350 may be permanently deformed and the half-lock function described above may be impaired. In addition, if the pin member 350 is permanently deformed, the above-described full lock function may be impaired.
[0011]
The present invention has been made under the above circumstances, and a card is inserted in an inverted position while adopting a cam mechanism composed of a combination of a cam portion and a pin member to enable push / push operation. Even at times, it is an object of the present invention to provide a card connector that does not cause a situation in which the half lock function or the full lock function is impaired by preventing the pin member from being forcedly deformed.
[0012]
[Means for Solving the Problems]
The card connector according to the present invention has a body into which a card is inserted, and a slider that is engaged with the card inserted into the body and pushed forward is forward and backward in a state in which the slider is elastically biased toward the rear. It is slidably held. In addition, the cam portion and the pin member of the cam mechanism formed by a combination of a cam portion and a pin member provided with a pin that follows the cam portion are allocated to the slider and the body, and the cam portion is A groove-shaped forward path for guiding the pin forward of the cam part, a locking part positioned at the end of the groove-shaped forward path for locking the pin, and the pin as a starting point for the pin And a groove-shaped return path that leads to the starting point of the groove-shaped forward path without forcibly deforming the pin member. Further, the slider is engaged with a recess provided on one side in the width direction of the card inserted into the body in a normal posture, and the engaging body is positioned with respect to the slider. An elastic body that constantly biases in the insertion direction with respect to the place, and a rear guide surface for causing the engaging body to ride on one end face in the width direction of the card that has been inserted into the body in a normal posture; The engaging body has a front guide surface for allowing the card to ride on one end face in the width direction of the card when the card is pulled rearward from the state where the engaging body is fitted in the recess. The rear guide surface of the engaging body has a function of climbing the other end surface in the width direction of the card that has been inserted into the body with the engaging body turned upside down, and the groove-shaped return path on the cam portion. The retraction path that continues to the side of the starting point of the groove-shaped forward path is added continuously, and the engagement body that rides on the other end surface in the width direction of the card that has been inserted in the body in an inverted position is provided. A pressing portion that pushes the pin member and pushes the pin located at the starting point of the groove-shaped forward path to the retracting path as it retracts to the side against the bias by the elastic body is on the engaging body. Is provided.
[0013]
According to the present invention, when the card is inserted into the body in a normal posture, the same action as described with reference to FIG. 16 is performed, and the half lock function and the full lock function are normally exhibited. On the other hand, when the card is inserted into the body in an upside down posture, when the slider is stopped at the initial position, the other end surface in the width direction of the card rides on the engagement body, and the engagement body is moved to the elastic body. Since it is retracted to the side against the bias, the pressing part provided on the engaging body pushes the pin member to push the pin located at the starting point of the groove-shaped forward path into the retracting path and position the pin in the retracting path Let For this reason, when the slider is subsequently pushed by the card and pushed forward from the initial position, the pin moves along the retraction path and enters the groove-shaped return path, and moves along the groove-shaped return path. At this time, the pin member is not forcedly deformed, so that the pin member is permanently deformed and the half lock function or the full lock function is not lost.
[0014]
In the present invention, it is desirable to have return means for returning the pin pushed out by the pressing portion to the retraction path from the retraction path to the starting point of the grooved forward path. According to this, even if the card is inserted into the body in an upside down posture and the pin is pushed out into the retracting path, when the card is pulled out from the body, the return means moves the pin back to the starting point of the grooved forward path. By inserting the card into the body in a normal posture, the half lock function and the full lock function can be exhibited.
[0015]
In the present invention, the starting point of the grooved forward path is positioned lower than the retreat path, and the return means is body And an inclined surface that is wider than the retraction path and has a downward slope toward the groove-shaped outward path, and a spring body that elastically biases the pin member and presses the inclined surface against the retraction path. It is desirable to adopt a configuration. According to this, even if the card is inserted into the body in an inverted posture and the pin is pushed out into the retreat path, when the card is pulled out from the body, the pin naturally returns from the retraction path to the starting point of the groove-shaped return path. . Therefore, it is possible to configure the return means without increasing the number of parts.
[0016]
In the present invention, it is desirable that the starting point of the groove-shaped forward path and the retreat path are communicated with each other by an inclined surface that slides the pin. According to this, when the card is inserted into the body in an inverted posture, the pin slides up the inclined surface from the starting point of the groove-shaped return path and is smoothly pushed out to the retreat path. Therefore, the pin member is not forced to be deformed. Also, after the card is inserted into the body in an upside down position and the pin is pushed out into the retraction path, when the card is pulled out of the body, the pin slides on the inclined surface from the retraction path and naturally returns to the starting point of the groove-shaped return path Moving.
[0017]
In the present invention, the groove-shaped return path has a detour portion protruding laterally from the locking portion which is the starting point thereof, and a return path main portion extending rearward from the detour portion, and the pin is engaged with the lock When the engagement body is retracted to the side against the urging force by the elastic body when the engagement body is locked to the portion, the pressing portion pushes the pin member, thereby causing the detour portion to move. It is desirable that it can be extruded to the main part of the return path. According to this, when the card is pulled strongly from the full lock state where the pin is locked to the locking portion and pulled out from the slider, the one end surface of the card rides on the engaging body, and the engaging body becomes an elastic body. As a result, the pressing part pushes the pin member and pushes the pin through the detour part to the return path main part. Therefore, the pin returns to the starting point of the groove-shaped forward path through the groove-shaped return path, and the slider returns to the initial position accordingly.
[0018]
In the present invention, in the groove-shaped return path, it is desirable that a stepped portion that prevents the pin from returning from the return path main part to the detour part is provided at the boundary between the bypass part and the return path main part. According to this, once the full lock function is released, it is possible to prevent the pin from returning from the return path main part back to the detour part and being locked by the locking part to be in the full lock state.
[0019]
In this invention, the said cam part is provided in the said body, and the structure that the said pin member is attached to the said slider can be employ | adopted.
[0020]
In the present invention, the elastic body made of a spring plate, the engagement body made of a mountain-shaped portion connected to the tip of the spring plate, and the pressing portion made of a protruding piece connected to the mountain-shaped portion. It is possible to adopt a configuration in which an integrally provided sheet metal unit is attached to the slider. According to this, the elastic body, the engaging body, and the pressing portion are formed by a single component called a sheet metal unit. Therefore, the increase in the number of parts is suppressed, and the number of assembly steps is also reduced.
[0021]
In the present invention, it is desirable that the spring body forming the return means is integrally connected to the sheet metal unit. According to this, in addition to the elastic body, the engagement body, and the pressing portion, the spring body is also a sheet metal. Since it is formed by a single part called a unit, the increase in the number of parts is further suppressed, and the number of assembly steps is further reduced.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a plan view of an embodiment of the card connector of the present invention, and FIG. 2 is an enlarged cross-sectional view of a portion taken along line II-II in FIG.
[0023]
1 and 2, the body 1 of the card connector is made of a synthetic resin molding having excellent electrical insulation, and has an insertion slot 11 for the card 100 at the rear end, and the insertion slot 11 Is attached with a shutter 12 that is opened and closed as indicated by an arrow A following the card 100 when the card 100 is inserted or removed. Reference numeral 13 denotes a shaft portion that forms the rotation center of the shutter 12. In the body 1, the upper surface of the portion excluding the place where the insertion port 11 is formed is open, and the open portion is covered with a metal cover 14 that is attached to the body 1 and exhibits electromagnetic shielding properties. It is.
[0024]
FIG. 3 is a partially broken plan view showing a state in which the card 100 is inserted in the normal posture in the body 1 with the cover 14 (see FIG. 1) removed. As shown in FIG. 3, the body 1 is attached to the front wall 15 of the body 1 with a required number of contact pieces 16 arranged side by side in the left-right direction W at intervals, and each contact piece 16 is attached to the front wall 15. It extends into the rear card insertion space. The contacts 18 at the tips of these contact piece members 16 are individually elastically contacted with electrodes (not shown) having a required number of poles formed in the electrode forming region 113 of the card 100 inserted up to an appropriate position of the body 1. It has become. Further, the front end of each contact piece 16 forms a soldering terminal portion 19 protruding forward of the front wall 15. Further, a slider 2 and a cam mechanism 4 are disposed on one side of the body 1.
[0025]
4 is an explanatory view showing the cam groove shape of the cam portion 41 forming the cam mechanism 4, and FIG. 5 is a schematic view showing the slider 2 and the pin member 5 and the sheet metal unit 6 for forming the cam mechanism described later. 6 is a side view of the slider 2 with the pin member 5 and the sheet metal unit 6 attached thereto, FIG. 7 is an enlarged sectional view taken along line VII-VII in FIG. 4, and FIG. 8 is an enlarged view taken along line VIII-VIII in FIG. It is sectional drawing.
[0026]
Figure 3 As shown in FIG. 5 or FIG. 6, the slider 2 is made of a synthetic resin molding that is elongated in the front-rear direction. The slider 2 has a width of a card (IC card or the like) 100 inside thereof. direction It has a support surface 21 that supports the one end face 101 and an engagement surface 22 that extends continuously in a curved shape continuously to the support surface 21 and is formed in a curved shape of the card 100 inserted into the body 1. The one end corner portion 103 thus made abuts against the engaging surface 22 and engages with the slider 2. Also a slider 2 In the lower part, the plate piece part 23 projects backward. In addition, this slider 2 5 is provided with a long recessed portion 24 at the front and rear opened outward as shown in FIG. 5, and a lower plate portion 25 forming the recessed portion 24 is bent at a right angle to the base portion of the pin member 5. A hole portion 26 into which the shaft portion 51 is rotatably inserted is formed, and the left and right direction W of the pin 52 bent at a right angle to the front end of the pin member 5 is formed in front of the hole portion 26. A slit-like cut-out portion 27 is formed to allow the rocking motion. Then, as shown in FIG. 6, the shaft portion 51 of the pin member 5 is rotatably inserted into the hole portion 26, and the pin 52 is disposed in the cut portion 27.
[0027]
As shown in FIG. 5 or FIG. 6, the sheet metal unit 6 is manufactured by machining a single metal plate, and has a spring body 61 extending obliquely downward and a position inside the spring body 61. An elastic piece 62 that can be elastically deformed in the perspective direction with respect to the spring body 61, an engagement body 63 formed by bending the tip of the elastic piece 62 into a mountain shape, and a connection to the tip of the engagement body 63. And a pressing portion 64 that protrudes outward and is integrally provided with a shaft pressing portion 65 that extends from the base portion of the spring body 61 and is formed in a downward folded shape.
[0028]
The sheet metal unit 6 is fitted into the recessed portion 24 of the slider 2 as shown in FIG. In the state where the sheet metal unit 6 is fitted in the recessed portion 24, the curved portion 66 provided at the tip of the spring body 61 presses the pin member 5 downward as shown in FIG. Is opposed to the shaft portion 51 of the pin member 5 to prevent the shaft portion 51 from floating and coming out of the hole portion 26. Also figure 3 As can be seen, the engaging portion 63 protrudes inward (outside the recessed portion 24) from the opening 29 formed in the inner plate portion 28 forming the recessed portion 24, and the pressing portion 64 is It faces the pin member 5 from the inside.
[0029]
The slider 2 in which the pin member 5 and the sheet metal unit 6 are assembled is shown in FIG. 3 In this manner, the body 1 is slidably held back and forth on one side of the body 1 and is always urged rearwardly by a spring 7 formed of a coil spring interposed between the slider 2 and the body 1. The initial position of the slider 2 is regulated by the slider 2 coming into contact with the contact surface 17 on the body 1 side.
[0030]
The cam portion 41 is provided integrally with the body 1 on one side portion of the body 1, forms the cam mechanism 4 together with the pin member 5 described above, and includes the cam groove 42 having the shape shown in FIG. Thus, the pin 52 follows the cam groove 42. The cam groove 42 includes a groove-shaped forward path 43 that guides the pin 52 to the front F of the cam portion 41, a stepped locking portion 44 that is positioned at the end point of the groove-shaped forward path 43 and locks the pin 52, The pin 52 is connected to the cam portion starting from the locking portion 44. 41 The pin member 5 (see FIG. 5 and the like) has a groove-shaped return path 45 that leads to the starting point P of the groove-shaped forward path 43 without forcibly deforming the pin member 5 (see FIG. 5 and the like). It is located outside the forward path 43. Of these, the groove-shaped forward path 43 is a skewed portion 43a or a detour portion extending obliquely inward from the starting position. 43b To the end point (locking portion 44), the groove-shaped return path 45 includes a detour portion 45a protruding outward from the lock portion 44 and a return path main portion 45b extending straight backward from the detour portion 45a. have. Further, the groove-shaped return path 45 continues straight to the straight return path main portion 45b, and the groove-shaped return path 45 43 As shown in FIG. 7, a groove-shaped forward path is added to the side of the starting point P. 43 The starting point P is positioned lower than the retreat path 46, and the groove-shaped forward path 43 The starting point P and the retreat path 46 are communicated with each other by an inclined surface 47. This inclined surface 47 is a groove-shaped outward path. 43 When the pin 52 located at the starting point P is pushed outward, the pin 52 is slid to ride on the retreat path 46, or the pin 52 that rides on the retreat path 46 is slid to form a groove. Outbound 43 Has a function of moving to the starting point P.
[0031]
In the cam groove 42 having the above-described shape, the starting point of the detour portion 43b of the groove-shaped forward path 43, both sides sandwiching the locking portion 44, and the groove-shaped return path 45 of Steps 31, 32, 33, and 34 that prevent the pins 52 from going backward are provided at the junctions with the groove-shaped forward path 43. FIG. 8 shows a stepped portion 33 formed at a boundary portion between the detour portion 45a and the return path main portion 45b.
[0032]
On the other hand, as shown in FIG. 7, the pin 52 has an outer peripheral edge at the tip (lower end) wider than the retreat path 46 and the groove-shaped forward path. 43 It is processed into the inclined surface 53 which consists of a curved surface (R surface) which has the downward gradient which goes to. Therefore, as shown by the arrow f in FIG. 7, when the pin member 5 is pressed by the curved portion 66 of the spring body 61 described in FIG. 6 and the like, and the inclined surface 53 of the pin 52 is pressed against the retreat path 46, Pin 52 is recessed from the retraction path 46 43 Move to the start point P of
[0033]
9 to 15 are explanatory views showing the operation of the slider 2 and the cam mechanism 4. Among these, as shown in FIGS. 10, 13, and 14, when the engaging body 63 is retracted to the side against the bias of the elastic piece 62, the pressing portion 64 pushes the pin member 5. pin 52 The groove-shaped return path 45 of the cam groove 42 of It can be displaced until the position is reached.
[0034]
Next, as shown in FIG. 15, a recessed portion 104 is formed on the back side of the front end one-side corner portion 103 of the card 100 such as an IC card. Further, a recess 106 is formed in one end face 101 in the width direction of the card 100.
[0035]
Here, the spring force that elastically biases the slider 2 backward by the spring 7 is larger than the force required to retract the engaging body 63 elastically biased by the elastic piece 62 to the side of the slider 2. It has become.
[0036]
Next, the operation and the like will be described.
As shown in FIG. 9, the slider 2 positioned at the initial position is regulated by being elastically pressed against the contact surface 17 on the body 1 side by the urging force of the spring 7.
[0037]
When the slider 4 is positioned at the initial position and the card 100 is inserted forward into the body 1 in a normal posture, the engaging body 63 projecting inward from the support surface 21 of the slider 2 is inclined. After the one-side end surface 103 of the card 100 hits the side guide surface 63a, the one-side end surface 101 of the card 100 rides on the engaging body 63 as shown in FIG. 10 and retracts the engaging body 63 outward. The one end face 101 of the card 100 gets over the engaging body 63, and the engaging body 63 is fitted into the recess 106 as shown in FIG. During this time, when the engaging body 63 is retracted, the pin 52 positioned at the starting point P of the groove-shaped forward path 43 of the cam groove 42 by the pressing portion 64 pressing the pin member 5 as shown in FIG. The pin 52 pushed out to the retracting path 46 in this way is pushed out into the retracting path 46, and the pressing portion 64 is displaced inward by the engagement of the engaging body 63 in the recess 106. Then, the inclined surface 53 of the pin 52 slides down the inclined surface 47 from the retreat path 46 by the action of the urging of the spring body 61 and returns to the starting point P of the groove-shaped forward path 43 (see FIG. 7).
[0038]
As shown in FIG. 11, when the engaging body 63 is fitted into the recess 106 of the card 100, the engaging body 63 engages with the card 100 inside the recess 106 unless the card 100 is forcibly pulled backward. As a result, a half-lock function that prevents the card 100 from being independently retracted from the slider 2 is exhibited. Further, since the plate piece portion 23 on the slider 2 side fits into the recessed portion 104 of the card 100, the leading end one side corner portion 103 of the card 100 hits the engaging portion 22 of the slider 2.
[0039]
Thereafter, when the card 100 is pushed and the slider 2 is pushed together with the card 100 toward the front F against the bias of the spring 7, the pin 52 of the pin member 5 that follows the slider 2 becomes the groove of the cam groove 42. Move the forward path 43 to the front F without difficulty. 4 It strikes against the front end of the detouring part 43b described in. At this time, when the push action on the card 100 is released, the slider 2 is pushed back by the force of the spring 7, and the pin 52 reaches the end point of the groove-shaped forward path 43 through the bypass 43b as shown in FIG. Locked to the locking portion 44. At this time, the full lock function that the backward movement of the slider 2 that half-locks the card 100 is prevented is exhibited, and the contact 18 of the contact member 16 on the body 1 side is connected to the electrode of the card 100 as shown in FIG. Elastic contact.
[0040]
When the card 100 is strongly pulled in the pulling direction as shown by an arrow R in FIG. 13 from the full lock state, the one end face 101 of the card 100 is engaged as shown in FIG. 13 by the action of the inclined front guide surface 63b of the engaging body 63. Riding on the combined body 63, the engaging body 63 is retracted outward and the half-lock state is released, and accordingly, the pressing portion 64 pushes the pin member 5 and engages with the locking portion 44 at the end point of the groove-shaped forward path 43. The pin 52 that has been stopped is passed through the detour 45a as shown in FIG. Channel-shaped return path 45's Return route Since it pushes out to 45b, a full lock state is cancelled | released.
[0041]
When the full lock state is released in this way, the slider 2 is moved rearward by the urging of the spring 7, and accordingly, the pin 52 is moved from the groove-shaped return path 45 to the retraction path 46, and the groove-shaped forward path. 43 Return to the starting point P (see FIG. 7). Further, the slider 2 returns to the initial position shown in FIG.
[0042]
Next, as shown in FIG. 14, when the card 100 is inserted into the body 1 in an inverted position, the other end surface 102 in the width direction of the card 100 is brought into engagement with the engaging body 63 when the slider 2 is stopped at the initial position. Upon getting on, the engaging body 63 is retracted to the side against the urging of the elastic piece 62. For this reason, the pressing part 64 pushes the pin member 5, pushes the pin 52 located at the starting point P of the groove-shaped forward path 43 to the retracting path 46 through the inclined surface 47, and positions the pin 52 in the retracting path 46. Accordingly, when the slider 2 is subsequently pushed by the card 100 and pushed forward from the initial position, the pin 52 moves along the retraction path 46 and enters the groove-shaped return path 45, and the groove-shaped return path 45 moves forward F. Moving. At this time, the pin member 5 is not forced to be deformed. Further, since a step portion 33 is formed between the return main portion 45b of the groove-shaped return path 45 and the detour path 45a, the pin 52 reaches the starting point of the groove-shaped return path 45 and is engaged. A situation where the full lock is caused by being locked to the stop 44 does not occur.
[0043]
After the user notices that the card 100 has been inserted in the inverted position, once the card 100 is removed and the card 100 is inserted into the body 1 in the normal position, the action described with reference to FIGS. The card 100 is half-locked to the slider 2 and then the slider 2 is fully locked.
[0044]
【The invention's effect】
According to the present invention, a cam mechanism composed of a combination of a cam portion and a pin member is used to enable push-push operation, but even when the card is inserted in an inverted position, the pin member is not deformed excessively. Since it is not forced, it is possible to provide a card connector that does not cause a situation in which the half lock function or the full lock function is impaired. Therefore, even when the pin member has to be manufactured with an extremely fine wire as the card connector becomes thinner, it is possible to provide a highly reliable half-lock function or full-lock function.
[Brief description of the drawings]
FIG. 1 is a plan view of an embodiment of a card connector of the present invention.
FIG. 2 is an enlarged cross-sectional view of a portion taken along line II-II in FIG.
FIG. 3 is a partially cutaway plan view showing a state where a card is inserted in a normal posture in a body with a cover removed.
FIG. 4 is an explanatory view showing a cam groove shape.
FIG. 5 is a schematic perspective view showing a slider, a pin member, and a sheet metal unit.
FIG. 6 is a side view of a state in which a pin member and a sheet metal unit are attached to a slider.
7 is an enlarged sectional view taken along line VII-VII in FIG. 4;
8 is an enlarged sectional view taken along line VIII-VIII in FIG.
FIG. 9 is an explanatory diagram showing an initial position of a slider.
FIG. 10 is an explanatory diagram showing an initial stage of card insertion.
FIG. 11 is an explanatory view showing a half-locked state of card insertion.
FIG. 12 is an explanatory diagram showing a full lock state.
FIG. 13 is an explanatory diagram showing a state in which full lock is released.
FIG. 14 is an explanatory diagram of a state where a card is inserted in an inverted position.
FIG. 15 is a perspective view of a main part when the card is viewed from the back side.
FIG. 16 is an explanatory diagram of a full lock state of a conventional card connector.
FIG. 17 is an explanatory view showing a state in which a card is inserted into a conventional card connector in an inverted position.
FIG. 18 is an explanatory diagram showing a cam groove shape employed in a conventional card connector.
[Explanation of symbols]
1 body
2 Slider
4 Cam mechanism
5 Pin member
6 Sheet metal unit
33 steps
41 Cam part
43 Channel-shaped outbound
44 Locking part
45 Channel return
45a bypass
45b Return part
46 Retreat Path
47 Inclined surface
52 pins
53 Inclined surface (return means)
61 Spring body (return means)
62 Elastic piece (elastic body)
63 Engagement body
63a Rear guide surface
63b Front guide surface
64 Pressing part
100 cards
101 One end face in the width direction of the card
106 recess

Claims (9)

In the body into which the card is inserted, a slider that is engaged with the card inserted in the body and pushed forward is held slidably forward and backward in a state of being elastically biased toward the rear,
The cam portion and the pin member of a cam mechanism formed by a combination of a cam portion and a pin member provided with a pin that follows the cam portion are allocated to the slider and the body, and the cam portion includes the pin A groove-shaped forward path that guides the cam portion forward, a locking portion that is positioned at the end point of the groove-shaped forward path and that locks the pin, and the pin is located behind the cam portion starting from the locking portion. Having a groove-shaped return path that leads to the starting point of the groove-shaped forward path without forcibly deforming the pin member by guiding to the
An engaging body for fitting the slider into the recess provided on one side in the width direction of the card inserted into the body in a normal posture and positioning the card with respect to the slider, and the engaging body with respect to the recess An elastic body that is always urged in the insertion direction, and a rear guide surface for causing the engagement body to ride on one end surface in the width direction of the card that has been inserted into the body in a normal posture; and A card connector having a front guide surface for causing the card to ride on one end face in the width direction of the card when the card is pulled rearward from the state where the engaging body is fitted in the recess. ,
The rear guide surface of the engaging body has a function of climbing the other end surface in the width direction of the card inserted into the body in an inverted posture, and is continuous with the groove-shaped return path on the cam portion. The retraction path reaching the side of the starting point of the groove-shaped forward path is added, and the engaging body that has run over the other side end face in the width direction of the card inserted in the body in an inverted position is the elastic The engaging body is provided with a pressing portion that pushes the pin member to push the pin located at the starting point of the groove-shaped forward path into the retracting path as it retracts to the side against the urging by the body. A card connector characterized by having   The card connector according to claim 1, further comprising return means for returning the pin pushed out by the pressing portion to the retraction path from the retraction path to a starting point of the grooved forward path. The starting point of the groove-shaped forward path is positioned lower than the retreat path, and the return means is provided on the body and has an inclined surface that is wider than the retreat path and has a downward slope toward the groove-shaped forward path, The card connector according to claim 2, further comprising: a spring body that elastically biases the pin member and presses the inclined surface against the retreat path.   The card connector according to any one of claims 1 to 3, wherein a starting point of the groove-shaped forward path and the retreat path are communicated with each other by an inclined surface that slides the pin.   The groove-shaped return path has a detour portion protruding laterally from the locking portion which is the starting point thereof, and a return path main portion extending rearward from the detour portion, and the pin is locked to the lock portion. When the engaging body is retracted to the side against the urging force by the elastic body, the pressing portion pushes the pin member to cause the pin to pass through the bypass portion and the return path main body. The card connector according to any one of claims 1 to 4, wherein the card connector is extrudable to the portion.   6. The card connector according to claim 5, wherein, in the groove-shaped return path, a step portion is provided at a boundary portion between the detour part and the return path main part to prevent the pin from returning from the return path main part to the detour part. .   The card connector according to claim 1, wherein the cam portion is provided on the body, and the pin member is attached to the slider.   The elastic body made of a spring plate, the engagement body made of a mountain-shaped portion connected to the tip of the spring plate, and the pressing portion made of a projecting piece connected to the mountain-shaped portion are integrally provided. The card connector according to claim 7, wherein a sheet metal unit is attached to the slider.   9. The card connector according to claim 8, wherein the spring body is integrally connected to the sheet metal unit.

Images