JP2009110097A - Card connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a card connector on which a thin card such as a memory card is mounted, that is, a card connector in which a detection mechanism for discriminating the type of a card is installed in a slider moving while holding the card. <P>SOLUTION: The slider 41 moving back and forth between (a) and (b) by holding an inserted card is installed at the right side position of a case body 22. The slider 41 is provided with a lock mechanism 35 for locking the slider 41 itself according to the insertion of the card C and a detection mechanism 30 for identifying the type of the card C. When the first card C1 is held by the slider 41, a detection convex part 33 of the detection mechanism 30 is moved backward against an elastic member 30A according to the shape of a guide identification groove 6 formed in the card. Thus, terminal parts 31 and 32 of the elastic member 30A are made to slide on a pair of parallel electrodes 28A and 28B, and the conductive connection of the pair of parallel electrodes 28A and 28B is performed. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a card connector to which a card in which an electronic circuit such as a memory chip is housed in a small and thin case, and more particularly to a card connector having a detection mechanism for identifying the type of inserted card.

As prior art related to the present invention, there are, for example, the following Patent Documents 1 and 2.
In the card connector described in Patent Document 1, a slide member that holds the card and is movable in the insertion direction and the ejection direction of the card, a coil spring attached to the slide member, and terminals at both ends of the coil spring And a fixed electrode that can be contacted respectively. When the card is inserted, the slide member is moved in the back direction while holding the card. At this time, the movable contacts at both ends of the coil spring come into contact with the first fixed contact and the second fixed contact, respectively, and the fixed contact is conducted between the two fixed contacts. It is detected that it is attached to the camera.

Patent Document 2 describes an invention relating to a plate-like recording medium holder to which a plate-like memory card is mounted. When the memory card inserted into the holder is pushed in the back direction together with the slider, the engaging convex portion provided so as to be able to advance and retract on the slider protrudes and engages with the engaging concave portion formed on the side surface of the memory card. To hold the memory card.
Japanese Patent Laid-Open No. 2007-213857 JP 2003-150921 A

  However, if a detection mechanism that detects the type of card and a slider that moves integrally while holding the card are provided separately, there is a problem that the number of parts increases.

  Further, in the conventional card connector shown in Patent Document 1, the insertion of the card cannot be detected unless the inserted card and the slider that moves integrally with the card are moved to the predetermined loading position in the innermost part. It is a configuration. That is, it is difficult to accurately detect the card even when it is desired to detect whether or not the card is inserted at an early stage when the card starts to be inserted into the storage area.

  The present invention solves the above-described conventional problems. For example, a card equipped with a slider that moves integrally while holding a card, which can detect the type of card at an early stage immediately after insertion. The purpose is to provide a connector.

The present invention provides a storage area in which a card in which an electronic circuit is stored in a case is mounted, a connection terminal located in the storage area and conducting to an external connection portion provided in the card, and the card together with the card In a card connector comprising a slider provided movably in the insertion direction and the ejection direction of
The storage area is provided with a pair of parallel electrodes formed in parallel along the insertion direction and the ejection direction of the card,
The slider is provided with a lock mechanism that locks the slider at a predetermined position in the storage area according to an insertion state of the card, and a detection mechanism that detects the card,
The detection mechanism includes a detection convex portion that can freely advance and retreat with respect to a guide identification groove provided on a side surface of the card, and biases the detection convex portion in a lateral width direction orthogonal to the insertion direction and the ejection direction of the card. And an elastic member that protrudes into the guide identification groove of the card,
When the card is mounted in the storage area, the elastic member moves in the lateral width direction according to the shape of the guide identification groove that is different for each card. The connection state can be switched.

  In the present invention, since the detection mechanism for identifying the card type and the like is mounted on the slider, it is possible to reduce the number of parts as a whole card connector and to make it compact.

  Moreover, in the present invention, the inserted card is held by the slider. At this time, the detection convex portion provided on the slider is moved in the lateral width direction, and the elastic member is deformed in the compressing direction. In this state, when the card and the slider are moved together to the back of the apparatus, the pair of contacts of the detection mechanism moved in the compression direction come into contact with the pair of parallel electrodes, and the electrodes are electrically connected. For this reason, card insertion can be detected at the insertion stage.

  In the above, the elastic member is formed of a torsion coil spring that can be deformed in a width direction perpendicular to the winding direction, and one end and the other end of the torsion coil spring are the pair. It is preferable to be able to contact each of the parallel electrodes.

  In the above means, the torsion coil spring that generates a biasing force that presses the detection convex portion against the card also functions as a member that connects the pair of parallel electrodes, so the number of parts can be reduced.

  Alternatively, the detection mechanism may be provided with a conductive connection member having a pair of contacts that can contact each of the pair of parallel electrodes.

In the card connector of the present invention, the slider that holds the card and moves integrally can be provided with a detection mechanism for identifying and detecting the type of the card at the same time, so that an increase in the number of components can be prevented, It becomes possible to make it compact.
Moreover, it can be detected at an early stage when the card type is inserted.

The card connector of the present invention will be described below with reference to the drawings.
1 is a perspective view showing an appearance of a card connector in a state where a card is mounted, FIG. 2 is a perspective view showing a card connector with a lid removed, FIG. 3 is an exploded perspective view of the card connector, and FIG. FIG. 5 is a plan view of the card connector, and FIG. 6 is a cross-sectional view of the card connector taken along line VI-VI shown in FIG.

  7 is a plan view of the card connector showing a state in which the first card is inserted in the initial position, FIG. 8 is a plan view of the card connector showing a state in which the second card is attached in the initial position, and FIG. The top view of the card connector which shows the state in the holding position of the 1st and 2nd card | curd, FIG. 10 is the fragmentary top view of the card connector which shows the operation state in the middle of card insertion in the state which removed the cover and the slider, (A) is the case of the first card C1, (B) is the case of the second card C2, FIG. 11 is a partial sectional view showing another modification of the detection mechanism, and (A) is the second card. In the case of C2, (B) is the case of the first card C1.

  In FIG. 12 and subsequent figures, a card to be attached to the card connector is shown. FIG. 12 is a plan view of the first card, FIG. 13 is a left side view of the first card, and FIG. 14 is a perspective view showing the first card from obliquely below.

  The first card C1 shown in FIGS. 12 to 14 is used as a memory device such as a so-called multimedia card. The first card C1 has a plastic case 1 in which a memory chip such as a flash memory and an IC chip that functions as a memory controller are stored.

  As shown in FIG. 13, the case 1 has a front surface 1a that is a first surface and a back surface 1b that is a second surface. The front surface 1a and the back surface 1b are planes parallel to each other, and the distance between the front surface 1a and the back surface 1b is the thickness dimension T of the first card C1. As shown in FIG. 14, a plurality (13) of external connection portions 5 are exposed in front of the back surface 1b. The surface of the external connection portion 5 is substantially flush with the back surface 1 b of the case 1.

  Here, “front surface” and “back surface” are names for convenience to distinguish between the surface having the external connection portion 5 and the surface not having the external connection portion 5, even if the front surface 1 a is attached to the card connector 20. Alternatively, it may be mounted with the back surface 1b facing upward.

  As shown in FIGS. 12 to 14, the case 1 has a front end 1c and a rear end 1d. It also has a right side 1e and a left side 1f.

  As shown in FIG. 13, the front end 1c is a plane perpendicular to the front surface 1a, and a front inclined surface 2 is formed at the corner between the front surface 1a and the back surface 1b. The rear end 1d is a plane perpendicular to the front surface 1a and the back surface 1b. The right side 1e and the left side 1f are planes perpendicular to the front surface 1a and the back surface 1b. As shown in FIG. 12, the boundary portion between the front end portion 1c and the right side portion 1e and the boundary portion between the front end portion 1c and the left side portion 1f, that is, the left and right side portions of the front end portion 1c are front portions that are part of a cylindrical surface. Corner curved surfaces 3 and 3 are formed. The rear corner curved surface 4, which is a part of the cylindrical surface, is also formed at the boundary between the rear end 1d and the right side 1e and the boundary between the rear end 1d and the left side 1f, that is, both the left and right sides of the rear end 1d. 4 is formed.

  As shown in FIG. 12, in the plan view of the case 11 viewed from the surface 1a side, the shape of the case 1 is symmetrical to the left and right via a center line OO extending in the front-rear direction.

  In the front portion of the case 1, guide identification grooves 6 and 6 are formed which are recessed from the right side 1 e and the left side 1 f toward the center line OO. The guide identifying grooves 6, 6 are parallel to the right side 1e and the left side 1f and are located on the inner sides 6a, 6a on the inner side by the width dimension W1 from the right side 1e and the left side 1f toward the center line OO, It has inner bottom surfaces 6c and 6c parallel to the back surface 1b. Inclined portions 6b and 6b are formed between the rear end of the right guide identification groove 6 and the right side 1e and between the rear end of the left guide identification groove 6 and the left side 1f, respectively. ing. The inclined portions 6b and 6b are surfaces that gradually move away from the center line OO toward the rear, and the inclined portions 6b and 6b are flat surfaces or curved surfaces having a curvature.

  As shown in FIG. 13, the guide identifying grooves 6 and 6 are recessed from the front surface 1a of the case 1 toward the back surface 1b. The distance from the front surface 1a of the case 1 to the inner bottom surface 6c of the guide identification groove 6, that is, the depth dimension t1 from the front surface 1a to the back surface 1b of the guide identification grooves 6, 6 is the overall thickness dimension of the first card C1. It is almost 1/2 of T. Further, as a result of the guide identifying grooves 6 and 6 being recessed from the front surface 1a, the thin wall portions 7 and 7 which are portions sandwiched between the back surface 1b and the inner bottom surfaces 6c and 6c are formed on the back surface side. Is formed. The thickness dimension t2 of the thin portions 7 and 7 is also approximately ½ of the overall thickness dimension T of the first card C1.

  The guide identification grooves 6 and 6 are opened forward at the left and right sides of the front end 1c. Therefore, as shown in FIG. 14, the thickness dimension of the front end 1c is T at most of the center thereof, but the thickness dimension is t2 on both sides. As shown in FIG. 12, the length dimension L1 before and after the guide identification grooves 6 and 6 is the distance from the front end 1c of the case 1 to the rear ends of the inclined portions 6b and 6b. The length dimension L1 before and after the guide identification grooves 6 and 6 functions as an identification unit for identifying the first card C1.

  On the right side 1e and the left side 1f of the case 1, intermediate recesses 8 and 8 are formed at positions spaced apart by a distance L2 from the rear ends of the guide identification grooves 6 and 6. A longitudinal dimension L3 of the intermediate recesses 8, 8 is shorter than a longitudinal dimension L1 of the guide identification grooves 6, 6.

  The intermediate recesses 8 and 8 have inner ends 8a and 8a that are located closer to the center line OO than the right side 1e and the left side 1f and are parallel to the right side 1e and the left side 1f. The width dimension W2 from the right side 1e to the inner end 8a and the width dimension W2 from the left side 1f to the inner end 8a are substantially the same as the width dimension W1 of the guide identification grooves 6 and 6.

  The intermediate recesses 8, 8 have a front inner end 8b and a rear inner end 8c, and the distance between the front inner end 8b and the rear inner end 8c is the length dimension L3 of the intermediate recesses 8, 8. is there.

  As shown in FIGS. 13 and 14, the intermediate recesses 8 and 8 have inner bottom ends 8d and 8d, and the inner bottom ends 8d and 8d are parallel to the back surface 1b. The dimension from the surface 1a to the inner bottom ends 8d, 8d is the depth dimension t3 of the intermediate recesses 8, 8, and this depth dimension t3 is larger than the depth dimension t1 of the guide identification groove 6.

  When the first card C1 is attached to the card connector 20, the holding portion 53 (see FIGS. 2 and 7) that has passed through the guide identification groove 6 is fitted into the intermediate recess 8, thereby The card C1 is held by the slider 41 in the card connector 20.

  As shown in FIG. 13, since the guide identification grooves 6 and 6 and the intermediate recesses 8 and 8 are both recessed from the front surface 1a toward the back surface 1b to the middle of the thickness dimension T, The holding portion 53 that has passed through can be fitted into the intermediate recesses 8 and 8 immediately thereafter. Moreover, since the inclined portions 6b and 6b are formed at the rear end portions of the guide identification grooves 6 and 6, the holding member is guided to the inclined portions 6b and 6b and smoothly fits in the intermediate recesses 8 and 8.

  Furthermore, as shown in FIG. 13, the depth dimension t3 of the intermediate recesses 8 and 8 is larger than the depth dimension t1 of the guide identification grooves 6 and 6, so However, it becomes easy to enter the intermediate recesses 8 and 8. Therefore, it is possible to position the first card C <b> 1 on the slider 41 in the card connector 20 by securely fitting the holding portion 53 to the intermediate recesses 8 and 8.

  As shown in FIG. 12, a knob recess 9 that is recessed from the surface 1 a is formed slightly inside the rear end 1 d of the case 1. As shown in FIG. 1, when the first card C <b> 1 is attached to the card connector 20, the rear end portion having the knob recess 9 protrudes from the card connector 20. The first card C <b> 1 can be pulled out from the card connector 20 by hooking a fingernail on the knob 9.

(The shape of the second card)
FIG. 15 is the same plan view as FIG. 12 showing the second card C2.

  The second card C2 has a case 11 in which a memory chip and other IC chips are stored.

  The guide identification groove 16 formed in the case 11 of the second card C2 is longer than the guide identification groove 6 of the first card C1, but the first card C1 and the second card C2 have other shapes. Is the same in all. That is, the thickness dimension T, the width dimension W0, and the length dimension of the case 11 of the second card C2 are the same as the case 1 of the first card C1. The shape, size, and position of the intermediate recesses 8, 8 formed in the case 11 of the second card C2 are the same as those of the case 1 of the first card C1. In addition, in FIG. 15, the same code | symbol is attached | subjected to the part same as the case 1 of the 1st card | curd C1, and the detailed description is abbreviate | omitted.

  In the second card C2 shown in FIG. 15, guide identification grooves 16, 16 are formed on the left and right sides of the front. In the guide identification grooves 16 and 16, an inner surface 16a is formed at a position approaching the center line OO. The position of the inner side surface 16a, that is, the width dimension W1 of the guide identification grooves 16, 16 is the same as the width dimension W1 of the guide identification grooves 6, 6 of the case 1 shown in FIG. Further, the dimension from the surface 1a of the case 11 to the inner bottom surface 16c, that is, the depth dimension of the guide identification grooves 16, 16 is the same as the depth dimension t1 of the guide identification grooves 6, 6 of the case 1 shown in FIG. . The case 11 of the second card C2 is provided with thin portions 17 and 17 on the back side of the guide identification grooves 6 and 6, but the width and thickness of the thin portions 17 and 17 are also the first dimension. This is the same as the thin portions 7 of the card C1.

  However, the length L11 of the guide identification grooves 16 and 16 and the thin portions 17 and 17 of the case 11 shown in FIG. 15, that is, the distance L11 from the front end 1c to the rear end of the inclined portion 16b is the case 1 shown in FIG. The guide identification grooves 6 and 6 and the thin portions 7 and 7 are longer than the length L1. Therefore, in the 2nd card | curd C2, the inclination parts 16b and 16b which are the level | step-difference parts which function as an identification part are in the position away from the inclination parts 6b and 6b in the 1st card | curd C1 ((b) side). is there.

  The length dimension L3 of the intermediate recesses 8, 8 formed in the case 11 of the second card C2 is the same as the length dimension L3 of the intermediate recesses 8, 8 of the case 1. Further, the length dimension L11 + L12 shown in FIG. 15 is the same as the length dimension L1 + L2 shown in FIG. That is, the distance from the front end 1c in the case 11 shown in FIG. 15 to the front inner ends 8b, 8b of the intermediate recesses 8, 8 is the same as the distance in the case 1 shown in FIG.

  The number, position and shape of the external connection portions appearing on the back surface 1b of the case 11 of the second card C2 are the same as the external connection portions 5 appearing on the back surface 1b of the case 1 of the first card C1 shown in FIG. Exactly the same.

  The first card C1 and the second card C2 are mounted in the same manner on the card connector 20 shown in FIG. As shown in FIG. 5, the card connector 20 is provided with a connection terminal 55 commonly connected to both the external connection portion 5 of the first card C1 and the external connection portion of the second card C2. .

  However, since the first card C1 and the second card C2 are different in the length dimensions L1 and L11 of the guide identification grooves 6 and 16 and the thin portions 7 and 17, the card connector 20 detects this difference. This makes it possible to recognize which card is installed.

  The difference in specifications between the first card C1 and the second card C2 is, for example, the difference in drive voltage, that is, the difference in voltage to be supplied to the circuits in the cases 1 and 11 via the external connection portion for power. is there. Alternatively, the difference in specifications is the difference in memory capacity of the memory chips housed in the cases 1 and 11. Alternatively, one of the first card C1 and the second card C2 has a memory chip with a large capacity and is mainly used for storing data, and the other is a read-only memory with a predetermined program built-in. Is used for supplying a control program.

  As shown in FIGS. 12 and 15, the case 1 of the first card C1 and the case 11 of the second card C2 are both symmetrical with respect to the center line OO, and the overall planar shape is It is a rectangle. Therefore, the space inside the cases 1 and 11 can be effectively used widely, and the internal IC chip and other circuits can be integrated and arranged while being small and thin.

  Moreover, since the guide identifying grooves 6 and 16 and the intermediate recess 8 are recessed only from the surface 1a side of the cases 1 and 11, it is easy to distinguish the front and back of the case. Moreover, since the guide identification grooves 6 and 16 are formed in the front area in the left and right side portions 1e and 1f, the front and rear of the cases 1 and 11 can be easily distinguished. Therefore, it is easy to prevent the card connector 20 from being inserted in the wrong direction.

  In the following description, the term “card C” means both the first card C1 and the second card C2 in principle.

(Structure of card connector)
Next, the structure of the card connector 20 to which the various cards are mounted will be described.

  As shown in FIGS. 1 to 4 and the like, the card connector 20 has a case (housing) 21. The case (housing) 21 is composed of a synthetic resin case main body (housing main body) 22 and a lid 23 formed of a metal plate and placed over the case main body 22.

  The case main body 22 has a frame shape. The case body 22 includes a front wall portion 24, a rear wall portion 25, a right wall portion 26, a left wall portion 27, and a bottom wall portion 28 that are integrally formed. The upper surface 24a of the front wall portion 24, the upper surface 25a of the rear wall portion 25, the upper surface 26a of the right wall portion 26 and the upper surface 27a of the left wall portion 27 are flush with each other. The ceiling plate 23 a of the lid body 23 is installed so as to be in close contact with the upper surfaces 24 a, 25 a, 26 a, 27 a of the case body 22. The lid body 23 is provided with a rear side plate 23b, a right side plate 23c and a left side plate 23d, which are bent at a right angle from the ceiling plate 23a. The rear side plate 23b is installed on the outer surface of the rear wall portion 25 of the case body 22, and the right side plate 23c and the left side plate 23d are installed on the outer surface of the right wall portion 26 and the outer surface of the left wall portion 27 of the case main body 22, respectively. Yes.

  As shown in FIG. 4, the thickness dimension of the case 21 is determined by the height dimension from the lower surface 28 a of the bottom wall portion 28 of the case body 22 to the upper surface of the ceiling plate 23 a of the lid body 23. The height dimension Ta of the storage area for guiding and storing the card C is determined by the height dimension from the upper surface 28b of the bottom wall portion 28 of the case body 22 to the lower surface of the ceiling plate 23a of the lid body 23. The height dimension Ta is substantially the same as the thickness dimension T of the entire card C or slightly larger than the thickness dimension T.

  As shown in FIG. 4 and the like, the inner surface of the left wall portion 27 of the case body 22 is a guide reference surface 27b, and the left side portion 1f of the card C slides on the guide reference surface 27b, while It is inserted toward the side ((a) side). A right guide surface 24b is formed on the front wall portion 24 of the case main body 22, and the right side portion 1e of the card C is guided along the right guide surface 24b.

  As shown in FIG. 4, the distance between the guide reference surface 27b on the inner surface of the left wall portion 27 and the right guide surface 24b of the front wall portion 24 is the width dimension Wa of the storage area. 11 is substantially the same as or slightly larger than the width C0 of the card C shown in FIG.

  As shown in FIG. 4, an insertion port 29 having an opening area of Ta × Wa is opened at the front end of the case 21, and the card C is inserted from the insertion port 29 toward the storage area inside the case 21. Is done.

  As shown in FIGS. 2 and 3, on the right side of the case body 22, a guide portion 34 extending in the front-rear direction ((a)-(b) direction) is formed on the upper surface 28 b of the bottom wall portion 28. The guide portion 34 is a groove extending in the longitudinal direction having a concave cross section formed in the upper surface 28b. A slider 41 is provided inside the right wall portion 26 of the case main body 22, and the slider 41 is supported along the guide portion 34 so as to be linearly reciprocable in the front-rear direction.

  An inner side surface 41 a is formed on the left side of the slider 41. The inner side surface 41a is located at the same position as the right guide surface 24b formed on the front wall portion 24, or slightly outside the lateral width direction. As shown in FIG. 4, the width dimension between the guide reference surface 27b formed on the left wall 27 and the inner side surface 41a is Wa or slightly wider than Wa. Similar to the right guide surface 24b described above, the card C can be guided between the guide reference surface 27b and the inner side surface 41a.

  As shown in FIGS. 2 and 3, an urging member S <b> 1 such as a coil spring is provided between the slider 41 and the case body 22, and the slider 41 is on the near side toward the front wall portion 24. (B side) is urged.

  Between the slider 41 and the case 21, a lock mechanism 35 for locking the slider 41 on the back side ((a) side) is provided. The lock mechanism 35 includes a groove cam 42 formed on the upper surface of the slider 41 and a lock pin 36 provided on the case 21.

  The lock pin 36 has a proximal end portion 36a and a distal end portion 36b bent at a right angle. As shown in FIGS. 7 to 9, the base end portion 36 a of the lock pin 36 is rotatably supported in a holding recess 24 c formed in the upper portion of the front wall portion 24 of the case body 22. The distal end portion 36 b of the lock pin 36 is slidably inserted into the groove cam 42. As shown in FIGS. 1 and 3, a lock plate spring 37 is integrally formed on the right front side of the ceiling plate 23 a of the lid 23 formed of a metal plate. The lock leaf spring 37 is a cantilever support spring formed by cutting out a part of the ceiling plate 23a. The lock pin 36 is pressed by the lock plate spring 37, and the tip 36 b is pressed against the groove bottom of the groove cam 42.

  As shown in FIGS. 5, 7 to 9, and the like, the groove cam 42 includes a lock release portion 42 a positioned at the end on the back side ((a) side), and a front side (( b) a locking part 42b located on the side). Between the lock release part 42a and the lock part 42b, a forward groove 42c is formed on the left side, and a return groove 42d is formed on the right side. Inside the groove cam 42, steps are formed at the boundary portions of the lock release portion 42a, the forward groove 42c, the lock portion 42b, and the return groove 42d, and the tip portion 36b of the lock pin 36 is connected to the lock release portion 42a → It is possible to slide only in the order of forward groove 42c → lock portion 42b → return groove 42d → lock release portion 42a, and the reverse process cannot be followed.

  5 and 7, the slider 41 is moved to the near side ((b) side) by the urging member and is abutted against the front wall portion 24 of the case main body 22. At this time, the distal end portion 36 b of the lock pin 36 is located in the lock release portion 42 a of the groove cam 42. When the card C is inserted from the insertion port 29 and the slider 41 moves to the back side ((a) side) together with the card C, the tip end portion 36b of the lock pin 36 passes through the forward path groove 42c of the groove cam 42, and thereafter As shown in FIG. 9, the tip end portion 36b reaches the lock portion 42b of the groove cam 42, and the slider 41 is locked so as not to return to the front side ((b) side).

  Thereafter, when the card C is pushed and the slider 41 is moved to the back side ((a) side) by a short distance, the tip end portion 36b of the lock pin 36 comes out of the lock portion 42b of the groove cam 42 and is guided to the return path groove 42d. As a result, the slider 41 is unlocked. Therefore, the slider 41 returns to the initial position shown in FIGS. 5 and 7 by the force of the urging member S1, and during this time, the distal end portion 36b of the lock pin 36 returns from the return groove 42d to the lock release portion 42a.

  As shown in FIG. 3 and the like, an upper guide wall 43 projecting leftward toward the storage area is integrally formed on the upper side of the inner wall surface 41 a of the slider 41. The opposing dimension between the lower surface of the upper guide wall 43 and the upper surface 28b of the bottom wall portion 28 is slightly larger than the thickness dimension t2 of the thin wall portion 7 on the right side of the card C, and the thin wall portion 7 on the right side of the card C is in the meantime. It can be inserted.

  As shown in FIGS. 2 and 3, a reference stopper portion 45 that protrudes to the left of the inner side surface 41 a is integrally formed at the back end portion of the slider 41. As shown in FIG. 4, the surface facing the front side ((b) side) of the reference stopper portion 45 is a reference stopper surface 45a.

  As shown in FIGS. 3 and 5 and the like, a holding recess 41c is formed on the upper surface of the front side ((b) side) of the slider 41, and a holding plate constituting a holding mechanism is formed in the holding recess 41c. A spring (holding member) 52 is provided. The holding plate spring 52 is formed of a metal plate that functions as a plate spring material, bent into a U shape, and fitted into the holding recess 41c.

  A holding portion 53 is integrally formed at the free end of the holding leaf spring 52, and the holding portion 53 protrudes to the left in the drawing from the inner side surface 41 a of the slider 41. The holding portion 53 is bent in a V shape, and a portion facing the front side ((b) side) is an inclined guide portion 53a. The inclination guide part 53a is inclined so as to gradually move away from the card toward the front side ((b) side). A portion of the holding portion 53 that faces the back side ((a) side) is a locking portion 53b, and this locking portion 53b is in a direction substantially orthogonal to the front-rear direction ((a)-(b) direction). Is formed.

  As shown in FIG. 2, the holding portion 53 protrudes leftward from the inner side surface 41 a of the slider 41. As shown in FIG. 4, the height dimension Tb from the upper surface 28b of the bottom wall portion 28 to the lower surface of the upper guide wall 43 is substantially the same as the thickness dimension t2 of the thin portion 7 of the card C shown in FIG. It is slightly wider than that. Therefore, as shown in FIG. 2, when the card C is inserted in a normal direction with the front end 1c facing forward and the surface 1a facing upward, the right thin portion 7 is below the upper guide wall 43. The card C can be inserted to the back of the case 21.

  As shown in FIGS. 2 and 6, when the card C is inserted into the insertion slot 29 in a normal direction, the thin portion 7 on the right side of the card C enters the lower side of the upper guide wall 43, and the card C The front end 1c abuts on the reference stopper surface 45a of the reference stopper 45, and the slider 41 is moved in the direction (a) while resisting the urging force of the urging member S1 by the insertion force of the card C.

  As shown in FIGS. 2, 3 and 5, a through portion 41d extending in the plate thickness direction is formed at a middle position in the longitudinal direction of the slider 41. The type of the card C is defined in the through portion 41d. A detection mechanism 30 for identifying and detecting is provided. The detection mechanism 30 includes a torsion coil spring 30 </ b> A that functions as an elastic member and a detection convex portion 33.

  The torsion coil spring (elastic member) 30A is made of a conductive material, and the direction orthogonal to the front-rear direction (direction (a)-(b)) is the width direction of the winding portion. The torsion coil spring 30 </ b> A has a winding portion and one end portion 31 and the other end portion 32 at both ends thereof. Note that a gap is provided between the wires forming the winding portion, and the torsion coil spring 30A can be elastically deformed in the width direction.

  As shown in FIGS. 3 and 5, etc., a slit hole 41e penetrating in the plate thickness direction is integrally formed on the inner surface of the slider 41 forming the right wall of the penetrating portion 41d. One end 31 of the torsion coil spring 30A is inserted into the slit hole 41e. In other words, the torsion coil spring 30A is based on the inner surfaces of the slit hole 41e and the through portion 41d. It can be elastically deformed in the width direction with reference to the end portion 31.

  As shown in FIG. 6, one end 31 and the other end 32 facing each other with the winding portion interposed therebetween are both bent into a substantially L shape, and the tip thereof is directed upward. The bent portion of one end 31 forms one contact first 31a, and the bent portion of the other end 32 forms the other second contact 32a.

  As shown in FIG. 5 and the like, on the right side of the penetrating portion 41d of the slider 41, one wall provided in the front direction (direction (a)) and the other wall provided in the rear direction (direction (b)). A storage portion 41f is integrally formed in a region provided between the two. The opposing dimension of the one wall and the other wall facing each other in the front-rear direction is Wc, and the storage portion 41f is provided with a detection convex portion 33 that can move freely in the lateral width direction.

  The width dimension in the front-rear direction of the detection convex portion 33 is smaller than the Wc. A convex portion 33a is formed on the right side surface of the detection convex portion 33, and the left side surface is elastically pressed leftward toward the storage area by the other end portion 32 of the torsion coil spring 30A.

  As shown in FIG. 3, a guide convex portion 33 b having a T shape is formed on the lower surface of the detection convex portion 33. The guide convex portion 33b is inserted in a guide concave portion 41g formed in a concave shape on the left side of the penetrating portion 41d in the storage portion 41f of the slider 41. The guide convex portion 33b can move in the width direction orthogonal to the guide concave portion 41g while being restricted from moving in the front-rear direction. Thereby, the convex part 33a of the detection convex part 33 exists in the state which can move linearly in the width direction within the accommodating part 41f.

  The detection convex portion 33 has the winding portion of the torsion coil spring 30 </ b> A in a natural length, and the tip of the convex portion 33 a protrudes toward the storage area side from the left side of the upper guide wall 43. When a rightward pressing force is applied to the detection convex portion 33, the winding portion of the torsion coil spring 30A is compressed, and the detection convex portion 33 is retracted into the storage portion 41f. When the pressing force is released, the torsion coil spring 30A is restored, and the detection convex portion 33 protrudes from the storage portion 41f to the storage region.

  As shown in FIGS. 3 and 5, a pair of parallel electrodes 28 </ b> A and 28 </ b> B extending linearly along the front-rear direction are formed on the right end side of the upper surface 28 b of the bottom wall portion 28. The dimension between one parallel electrode 28A and the other parallel electrode 28B is approximately the same as the width dimension between one end 31 and the other end 32 when the torsion coil spring 30A is in a compressed state. They are formed with the same dimensions. Further, the width dimension of the pair of parallel electrodes 28A and 28B itself is formed to be slightly larger than the diameter of the one end 31 and the other end 32.

  The torsion coil spring 30A is loaded inside the through-hole 41d in a state where a tension is applied between the one end portion 31 and the other end portion 32 in the circumferential direction of the coil (twisted state). ing. Therefore, as shown in FIG. 6, the first contact 31a at one end 31 represses the surface of one parallel electrode 28A, and the second contact 32a at the other end 32 is the other parallel electrode 28B. Or the upper surface 28b of the bottom wall 28 is pressed down.

  In a state where the first contact 31a of one end 31 elastically presses one parallel electrode 28A and the second contact 32a of the other end 32 elastically presses the other parallel electrode 28B, The other parallel electrode 28B is in a conductive state. The first contact 31a at one end 31 represses the other parallel electrode 28A. When the first contact 31a at one end 31 is located on the upper surface 28b of the bottom wall 28, One parallel electrode 28A and the other parallel electrode 28B are in a non-conductive state.

  As shown in FIGS. 10A and 10B, when the slider 41 moves in the front-rear direction, the first contact 31a of the one end 31 is always set regardless of whether or not the torsion coil spring 30A is deformed. Slides linearly on one parallel electrode 28A along the front-rear direction. On the other hand, as shown in FIG. 10A, when the torsion coil spring 30A is in a compressed state, the second contact 32a of the other end portion 32 extends along the front-rear direction on the other parallel electrode 28B. Slide linearly. As shown in FIG. 10B, when the torsion coil spring 30A is in the extended state, the second contact 32a of the other end portion 32 is on the upper surface 28b of the bottom wall portion 28 along the front-rear direction. Slide linearly.

  As shown in FIGS. 2 to 5 and the like, a connection terminal 55 is provided on the back side ((a) side) of the case main body 22. The connection terminals 55 are arranged in the same number and the same pitch as the external connection parts 5 exposed on the back surface 1b of the first card C1 shown in FIG. As shown in FIG. 3, the base end side of each connection terminal 55 is fixed in a cantilever state molded to the lower surface 28a of the bottom wall portion 28, and the tip end side in the (a) direction is the vertical direction. A free end that is elastically deformable is formed. The surface of the connection terminal 55 is formed of a conductive metal plate plated with a low resistance noble metal material such as gold.

(Card loading operation)
Next, a card mounting operation to the card connector 20 will be described.

  2 and 7 to 9 show the operation when the card C is loaded in the normal orientation.

  As shown in FIG. 5, in a state where no card is mounted, the slider 41 moves to the insertion port 29 side ((b) side) in the front-rear direction.

  When the card C is inserted from the insertion slot 29 in a normal posture with the front end 1c facing forward and the surface 1a facing upward, the thin portion 7 formed on the right side of the case 1 of the card C is Then, it passes under the holding portion 53 formed by the holding leaf spring 52 provided on the front side of the slider 41.

  Further, the right guide identification groove 6, that is, the upper portion of the right thin portion 7 passes below the detection convex portion 33 and moves in the region of the height Tb shown in FIG. 4 toward the back side.

  Here, as shown in FIG. 7, when the inserted card C is the first card C1, the convex portion 33a of the detection convex portion 33 hits the right side portion 1e of the first card C1, and the detection convex portion. The entire portion 33 is retracted into the storage portion 41f. Therefore, since the torsion coil spring 30A is compressed in the width direction, the conductive state is set between the one parallel electrode 28A and the other planar transmission electrode 28B while the slider 41 moves in the front-rear direction ( (See FIG. 10A).

  On the other hand, as shown in FIG. 8, when the inserted card C is the second card C2, the detection convex portion 33 enters the left guide identification groove 16, and the right side of the second card C2. It does not hit part 1e. For this reason, the state which the detection convex part 33 protruded in the left direction is maintained. In this state, the torsion coil spring 30A extends in the width direction, and the one parallel electrode 28A and the other plane transmission electrode 28B are set in a non-conductive state while the slider 41 moves in the front-rear direction. (See FIG. 10B).

  Therefore, when a control unit (not shown) monitors whether the one parallel electrode 28A and the other parallel electrode 28B are in a conductive state, the pair of parallel electrodes 28A, 28B are in a conductive state. It can be determined that the inserted card C is the first card C1. Further, when the pair of parallel electrodes 28A and 28B is in a non-conductive state, the control unit can determine that the second card C2 has been inserted into the case.

  Moreover, since the pair of parallel electrodes 28A and 28B extend from the side to the back, the torsion coil spring 30A can be compressed in the width direction immediately after the card C is inserted. Therefore, the type of the card C can be determined at an early stage of inserting the card.

  During this time, the holding portion 53 of the holding leaf spring 52 provided on the slider 41 passes through the inside of the guide identification groove 6 on the right side of the card C, that is, passes over the thin portion 7 and behind the guide identification groove 6. It hits the inclined part 6b. Since the holding portion 53 is pushed rightward by the inclined portion 6 b, the holding leaf spring 52 is deformed and the holding portion 53 is temporarily retracted into the holding recess 41 c of the slider 41. When the holding portion 53 slides the right side 1e of the card C by the distance L2 or L12 and reaches the intermediate concave portion 8, the holding portion 53 is moved to the right intermediate concave portion 8 by the elastic return force of the holding leaf spring 52. The card C is held inside the slider 41 by being fitted inside.

  At this time, since the inclined guide portion 53a facing the front side of the holding portion 53 slides on the inclined portion 6b inclined in the same direction, the card C is pushed into the case 21 with a light force, and the holding portion 53 is moved. The intermediate recess 8 can be fitted. After the fitting, the locking portion 53b formed in the holding portion 53 in a direction substantially perpendicular to the insertion direction of the card C is hooked on the front inner end 8b of the intermediate recess portion 8, so that the card C Is difficult to escape in the forward direction (direction (b)).

  When the card C is pushed in after the holding portion 53 is fitted in the intermediate recess 8, as shown in FIG. 7 or FIG. 8, the card C (first card C1 or second card C) 2 is further moved to the back. When pushed, the front end 1 c of the card C hits the reference stopper surface 45 a of the reference stopper 45 provided on the back side of the slider 41.

  When the card C is further pushed in, the reference stopper surface 45a formed on the slider 41 is pushed by the front end portion 1c of the card C, and the card C and the slider 41 move together to the back side.

  When the card C reaches the mounting completion position shown in FIG. 9, the lock portion 42b of the groove cam 42 formed on the slider 41 is engaged with the tip end portion 36b of the lock pin 36, and the slider 41 is locked at that position. The At this time, each of the connection terminals 55 provided on the back side of the case main body 22 is pressed and connected to each of the external connection portions 5 exposed on the back surface 1b of the card C.

  A control unit (not shown) accesses the memory in the case main body 22 via the connection terminal 55 of the case main body 22 and the external connection portion 5 exposed on the back surface 1b of the card C. Is written, or information written in the memory is read.

  In the above embodiment, as the detection mechanism 30 for detecting the type of card, the first contact 31a of one end 31 of the torsion coil spring 30A forming the elastic member and the second contact 32 of the other end 32 are used. Although the contact 32a has been described using the configuration in which the contact 32a slides on the pair of parallel electrodes 28A, 28B, the present invention is not limited to this.

  For example, as shown in the modification of FIGS. 11A and 11B, a convex that can contact the pair of parallel electrodes 28A and 28B between the elastic member B made of a coil spring or the like and the detection convex portion 33, respectively. The structure in which the conduction | electrical_connection connection member 60 provided with the 1st contact 61 and the 2nd contact 62 of a shape may be provided. The conductive connecting member 60 is formed of a conductor at least between the first contact 61 and the second contact 62.

  In this configuration, as shown in FIG. 11A, when the inserted card C is the second card C2, the conductive connecting member 60 and the detection convex portion 33 are placed on the left storage area by the elastic member 30B. The convex portion 33a enters the guide identification groove 16 of the second card C2. At this time, the first contact 61 and the second contact 62 are positioned on the one parallel electrode 28A and the other parallel electrode 28B, respectively, and the pair of parallel electrodes 28A and 28B are set in a conductive state.

  On the other hand, as shown in FIG. 11 (B), when the inserted card C is the first card C1, it is pushed rightward by the right side 1e of the first card C1, so that the conductive connecting member 60 And the detection convex part 33 is moved to the right direction which leaves | separates from a storage area | region. At this time, the elastic member 30B is compressed, and the first contact 61 and the second contact 62 of the conduction connecting member 60 are disengaged from the one parallel electrode 28A and the other parallel electrode 28B. Therefore, the pair of parallel electrodes 28A and 28B is switched to a non-conducting state.

  Therefore, by detecting the conduction state between one parallel electrode 28A and the other parallel electrode 28B, it is identified whether the inserted card C is the first card C1 or the second card C2. be able to.

  In the above embodiment, the detection mechanism for identifying the type of the card C inserted into the card connector 20 has been described. However, the present invention is not limited to this. For example, it can be used as a mechanism for detecting whether or not an inserted card is inserted, whether or not a card is erroneously inserted, or whether or not a write protection is set by detecting irregularities formed on the side of the card.

The perspective view which shows the external appearance of the card connector in the state in which the card | curd C was mounted | worn. The perspective view which shows the card connector which removed the cover body. The disassembled perspective view of a card connector. The front view which looked at the card connector with which the card | curd is not mounted | worn from the front. The top view of the card connector which removed the cover body. Sectional drawing of the card connector in the VI-VI line shown in FIG. The top view of the card connector which shows the state with which the 1st card | curd was mounted | worn in the initial position. The plane of the card connector which shows the state with which the 2nd card was mounted | worn in the initial position. The top view of the card connector which shows the state in the holding position of a card | curd. It is a fragmentary top view of the card connector which shows the operation state in the middle of card insertion, (A) is the case of the 1st card and (B) is the case of the 2nd card. It is a fragmentary sectional view showing other modifications of a detection mechanism, (A) is the case of the 2nd card C2, and (B) is the case of the 1st card C1. The top view of a 1st card | curd. The left view of a 1st card | curd. The perspective view which shows the 1st card | curd from diagonally lower side. The top view which shows a 2nd card | curd.

Explanation of symbols

C card (first card and second card)
C1 1st card C2 2nd card 1,11 Case 1a Case surface 1b Case back surface 1c Front end 1d Rear end 1e Right side 1f Left side 5 External connection 6 Guide groove 6b Step 7 Thin part 8 Middle Recess 20 Card connector 21 Case (housing)
22 Case body 23 Lid 23a Ceiling plate 27 Left wall 27b Guide reference surface 28 Bottom wall 28b Top surface 28A of bottom wall One parallel electrode 28B Other parallel electrode 30 Detection mechanism 30A Torsion coil spring (elastic member)
31 One end 31a First contact 32 Other end 32a Second contact 35 Lock mechanism 36 Lock pin 41 Slider 42 Groove cam 52 Holding leaf spring 53 Holding portion 55 Connection terminal 60 Conducting connection member

Claims (3)

A storage area in which a card in which an electronic circuit is stored in a case is mounted; a connection terminal located in the storage area and conducting to an external connection provided in the card; and a card insertion direction together with the card; In a card connector provided with a slider provided movably in the ejection direction,
The storage area is provided with a pair of parallel electrodes formed in parallel along the insertion direction and the ejection direction of the card,
The slider is provided with a lock mechanism that locks the slider at a predetermined position in the storage area according to an insertion state of the card, and a detection mechanism that detects the card,
The detection mechanism includes a detection convex portion that can freely advance and retreat with respect to a guide identification groove provided on a side surface of the card, and biases the detection convex portion in a lateral width direction orthogonal to the insertion direction and the ejection direction of the card. And an elastic member that protrudes into the guide identification groove of the card,
When the card is mounted in the storage area, the elastic member moves in the lateral width direction according to the shape of the guide identification groove that is different for each card. A card connector characterized in that the connection state can be switched.   The elastic member is formed of a torsion coil spring that can be deformed in a width direction orthogonal to the winding direction, and one end and the other end of the torsion coil spring are the pair of parallel electrodes. The card connector according to claim 1, wherein each card connector is connectable to each other.   The card connector according to claim 1, wherein the detection mechanism is provided with a conductive connecting member having a pair of contacts that can contact each of the pair of parallel electrodes.

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