JP3982371B2 - Memory card connector device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a memory card connector device for removably connecting a memory card such as an SD memory card or a multimedia card (MMC).
[0002]
[Prior art]
Conventionally, it has a box shape having a memory card insertion slot at the front, and a connector body into which the memory card is slid out of the memory card insertion slot, and a plurality of I of the memory card disposed inside the connector body. A plurality of contacts that respectively contact the / O contact surface, and a slider that is movably disposed in the front-rear direction inside the connector body and moves in the front-rear direction together with the memory card when the memory card is inserted / removed from the memory card insertion slot A coil spring that constantly urges the slider forward, a cam pin that is held by the slider and the other end is engaged with a heart cam groove provided in the connector body, and one end is fixed to the slider The other end includes a lock body that engages with a locking recess provided on the side surface of the memory card when the memory card is mounted Mori card connector device is provided (for example, see Patent Document 1).
[0003]
In this connector device, a tapered guide surface that guides the other end of the lock body is formed on the connector body, and when the slider moves backward against the elastic force of the coil spring as the memory card is inserted. As the slider moves, the other end of the cam pin moves along the groove of the heart cam groove. Then, when the memory card is inserted to the locked position, the other end of the cam pin is fitted into the recessed portion opened on the front side provided in the heart cam groove, thereby restricting the forward movement of the slider. Retained. When the slider moves backward as the memory card is inserted, the other end of the lock body gradually approaches the side surface of the memory card provided with the locking recess along the guide surface provided on the connector body. When the memory card is inserted to the vicinity of the lock position, the other end of the lock body is engaged with the lock recess, so that the memory card is prevented from falling off.
[0004]
[Patent Document 1]
JP 2001-357931 A (pages 4 to 5 and FIG. 4)
[0005]
[Problems to be solved by the invention]
In the memory card connector device configured as described above, since the other end of the lock body is guided by the tapered surface provided on the connector body, the slider moves forward from the lock position or before the slider moves to the lock position. After that, there is a position where the other end of the lock body is engaged with the locking recess, and if the memory card is forcibly pulled out at that position, the locking recess of the memory card can be deformed or locked even with a relatively small force. There was a problem that the body was deformed.
[0006]
The present invention has been made in view of the above problems, and its purpose is to reliably release the locking state between the locking body and the locking recess except during locking, and to prevent accidents during card insertion and removal. An object of the present invention is to provide a memory card connector device that prevents the above.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, according to the first aspect of the present invention, there is provided a connector main body having a box shape having a memory card insertion slot at a front portion, into which a memory card is slid and inserted from the memory card insertion slot, and a connector main body. The memory card is inserted into and removed from the memory card insertion slot, and is arranged inside the connector body so as to be movable in the front-rear direction. Along with the memory card, a slider that moves in the front-rear direction, a biasing spring that constantly biases the slider forward, and a slider that moves to a predetermined position when the pushing force of the memory card is released after moving the slider to the rearmost position. The slide is released when the slider moves backward due to the pushing force applied to the memory card after the lock. -A locking means and a card locking means for locking the memory card by engaging the locking recess of the memory card when the slider is locked at the predetermined position, and the slider locking means is formed on the surface of the slider The heart cam groove, one end is held by the connector body and the other end is engaged in the heart cam groove, and when the slider moves to the predetermined position, the other end fits into a recess opening on the front side provided in the heart cam groove. And a cam pin that restricts the movement of the card in the forward direction, and the card lock means is provided with a locking portion that is held by the slider at one end side and that engages with the locking recess of the memory card at the other end side. It is composed of a lock body having high elasticity, and is integrated with the lock body in the recess of the heart cam groove. Providing a protruding part that protrudes partly, when the protruding part is pressed backward at the other end of the cam pin moved into the concave part, the lock body is elastically deformed and the locking part enters the concave part for locking, When the other end of the cam pin moves from the recess and there is no force to push the protrusion backward, the locking portion is retracted from the locking recess by the elastic restoring force of the lock body.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail.
[0009]
(Embodiment 1)
15 and 16 show an exploded perspective view and an overall perspective view of the entire embodiment corresponding to a memory card MC such as an SD memory card, and the connector device of the present embodiment has a thickness as shown. A base shell 1 formed by punching and bending an extremely thin stainless metal plate, and a base shell formed by punching and bending an extremely thin stainless metal plate in the same manner as the base shell 1. 1 is attached to the rear portion of the connector main body 3 and the cover shell 2 comprising the base shell 1 and the flat box-shaped connector main body 3 with the memory card insertion opening 42 opened at the front. A contact block 4 and a slurry made of a U-shaped resin molded product disposed in the connector body 3 on the front side of the contact block 4 so as to be movable in the front-rear direction. And Dah 5 is obtained by a major component.
[0010]
As shown in FIG. 17, the base shell 1 is provided with side pieces 6a and 6b formed by bending in the direction of the upper surface (corresponding to the inside of the connector main body 3) on both sides, and the front and rear ends are open. At the rear end, there is a protruding piece 9 for press-fitting from below into a press-fitting hole 8 (see FIG. 18) penetrating the resin base body 7 of the contact block 4 in the vertical direction to fix the contact block 4 to the rear upper surface. Four folds are formed on both sides at a predetermined interval.
[0011]
Further, in the position slightly forward from the rear end, there are formed contacts 10 to be described later, which are held by the contact block 4, and holes 11 for releasing switch pieces 30a, 30b, 31a, 31b.
[0012]
The rear ends of the side pieces 6a and 6b are integrally connected to the rear ends of the spring seat protrusions 12 and 12 provided in parallel with the inner surfaces of the side pieces 6a and 6b. These spring seat protrusions 12 are inserted into one end of the biasing coil spring 13 in order to prevent buckling of the biasing coil spring 13 (biasing spring) of the slider 5.
[0013]
By the way, the L-shaped piece 14 that supports one end of the cam pin 16 that restricts the movement of the slider 5 in the front-rear direction is cut inwardly at a position slightly forward of the tip position of the spring seat protrusion 12 of the side piece 6a. It is formed by raising. Specifically, the L-shaped piece 14 has a shaft hole 14b formed in the standing piece 14a, and a shaft portion 16a at one end of the cam pin 16 is inserted into the shaft hole 14b so that the shaft portion 16a can be pivoted. I support. The cam pin 16 is disposed in a recessed portion formed on the side surface of the leg piece 5c of the slider 5 parallel to the standing piece 14a, and the other end shaft portion 16b is moved to the heart cam groove portion 15 formed on the outer side surface on the front side of the leg piece 5c. I am allowed to engage freely.
[0014]
Further, a pressing spring piece 17 that presses the side surface of the cam pin 16 toward the leg piece 5c side of the slider 5 parallel to the side piece 6a is formed by cutting and raising at the front part of the side piece 6a of the base shell 1.
[0015]
In addition, a concave notch is formed on the front end of the base shell 1 (on the side of the memory card insertion slot 42) so that both side edges are widened forward, and is directed upward along the side edges that form the inclined sides of the notch. Thus, the protrusion 18 for preventing reverse insertion is formed by cutting and raising.
[0016]
The space between the projecting pieces 18 and 18 corresponds to the memory card insertion slot 42 of the memory card MC, and a step portion 18a is formed at the upper inner edge of each projecting piece 18, and the step portions of the projecting pieces 18 and 18 on both sides are formed. 18a, the dimension between the inner edges above 18a is set slightly larger than the maximum width dimension on both sides of the memory card MC, and the dimension between the upper surface of the base shell 1 and the upward surface of the step portion 18a is 1 is set to a dimension slightly smaller than the height dimension of the downward surface of the downward step portion 101 formed over the entire length in the front-rear direction on both side edges of the back surface of the memory card MC with the back surface side on the top surface of The dimension between the inner edges on the lower side of the upward stepped portion 18a is set to be slightly larger than the width on both sides below the downward stepped portion 101 of the memory card MC.
[0017]
Thus, when the back surface side of the memory card MC is placed on the upper surface side of the base shell 1, the downward step portion 101 of the memory card MC can pass over the step portion 18 a of the projecting piece 18, and from the memory card insertion opening 42. When the memory card MC is inserted into the base shell 1 and the surface of the memory card MC is directed toward the upper surface of the base shell 1, both side portions of the memory card MC on the base shell 1 side are projecting pieces 18 on both sides. 18 cannot pass between the inner edges of the memory card MC, thereby preventing erroneous insertion due to a mistake in the front and back direction of the memory card MC.
[0018]
Further, a stopper piece 26 is formed by cutting and raising the inner edge of the front side (memory card insertion slot 42 side) of the right end hole 11 corresponding to the right end contact 10 of the contact block 4. In other words, when the memory card MC is inserted into the memory card insertion slot 42 in the normal direction, the groove (not shown) that leads to the I / O contact surface (not shown) provided on the back surface of the memory card MC is inserted. The contacts 10... Can be moved to the contact position through the opening in FIG. 5B, but if the memory card MC is to be inserted in a non-regular direction with the front-rear direction reversed, a stopper is provided on the front surface in the insertion direction. The pieces 26 collide with each other to restrict further movement, and the tip portions of the contacts 10 of the contact block 4 are prevented from hitting and being damaged by the front surface on the insertion side of the memory card MC.
[0019]
On the other hand, as shown in FIG. 19, the cover shell 2 is integrally provided with downward side pieces 20 and 20 by bending on both sides, and three downward protruding pieces 21 are bent at a predetermined interval at the rear end. These protruding pieces 21 are press-fitting holes that are penetrated so as to open on the upper surface of the base body 7 of the contact block 4 arranged at the rear end of the upper surface of the base shell 1 when the cover shell 2 is attached onto the base shell 1. The contact block 4 is fixed by being press-fitted into the contact 22.
[0020]
Further, on the front side of the cover shell 2, a window hole 23 in which the [SD] mark marked on the surface of the memory card MC inserted into the connector main body 3 can be visually recognized is formed on both sides of the window hole 23. Is formed by punching the slit 24 so as to be parallel to each other, and projecting the central portion of the piece 25 between the slit 24 and the window hole 23 downward from the lower surface of the cover shell 2 and projecting into the connector main body 3 at the projecting tip. The memory card MC is elastically brought into contact with the surface of the inserted memory card MC to hold the memory card MC.
[0021]
As shown in FIG. 18, the contact block 4 includes a plurality of contacts (9 in the SD memory) in parallel on the rear rear surface of the memory card MC and contacts 10 corresponding to the I / O contact surfaces, respectively, and the memory card MC. A pair of switch pieces 30a, 30b for position detection and a pair of switch pieces 31a, 31b for position detection of the write protect switch SW of the memory card MC are integrally held on the resin base body 7 by insert molding, The contact side of the contacts 10... And the switch pieces 30a, 30b, 31a, 31b is projected on the front surface (memory card insertion slot 42) side of the base body 7, and the solder for soldering each to a circuit board or the like on the rear surface side. The attached terminal portions 32 are protruded. The base body 7 is provided with a step at the front upper portion, and the press-fitting holes 8 are vertically penetrated so that one end is opened at the step, and the press-fitting hole is opened at one end on the rear upper surface of the base 7. 22... Are vertically penetrated through the rear portion of the base body 7. Further, on both side surfaces of the base body 7 are provided recesses 47 for fitting and guiding one end side portions of biasing coil springs 13 and 13 for inserting spring seat protrusions 12 and 12 provided on both sides of the rear portion of the base shell 1. is there. Here, the recess 47 on one side is provided on the lower side of the base 7, and the recess 47 on the other side is provided on the upper side of the base.
[0022]
As shown in FIG. 15, the slider 5 is formed in a U shape by a synthetic resin molded product, and the leg pieces 5b and 5c are integrally projected forward from the front ends of both ends of the center piece 5a. A concave groove 33 is formed on the lower surface side of the central piece 5a for projecting forward the switch pieces 30a, 30b, 31a, 31b and the tips of the contacts 10 when the slider 5 is moved backward. Correspondingly formed.
[0023]
The both side leg pieces 5b and 5c function as guides for the left and right side portions of the memory card MC. The front end inner side surfaces are inclined so that the distance between the inner side surfaces of the leg pieces 5b and 5c widens outward. 34.
[0024]
Further, one leg piece 5b is formed with a narrow groove 35 having a substantially U-shaped cross section having an outer portion, an upper portion, and a rear end portion opened in the central direction from the upper rear end. The other end of the biasing coil spring 13 is housed, and the inner surface of the front end of the narrow groove 35 is a surface that receives the elastic force of the biasing coil spring 13. Similarly, a narrow groove (not shown) for accommodating the other end of another biasing coil spring 13 is formed in the other leg piece 5c, and the biasing coil spring 13 is formed on the inner surface of the front end of the narrow groove. It is designed to receive resilience. Here, both the leg pieces 5b, 5c receive the elastic force of the biasing coil springs 13, 13 in the forward direction, so that the slider 5 can smoothly slide in the connector body 3 in the front-rear direction.
[0025]
Also, receiving guides 19a and 19b for mounting and sliding the downward stepped portions 101 on both sides of the memory card MC from the front end toward the rear are integrally formed at the lower part of the inner side surfaces of both leg pieces 5b and 5a.
[0026]
Further, a heart cam groove 15 is formed on the outer surface of the front side of one leg piece 5c. As shown in FIGS. 10A and 10B, the heart cam groove portion 15 is composed of a heart cam 15a and a guide groove 15b. The shaft portion 16b of the cam pin 16 is engaged with the guide groove 15b, and as the slider 5 moves back and forth. The relative movement in the guide groove 15b of the shaft portion 16b of the cam pin 16 is guided by the guide groove 15b and the uneven surface 15c formed on the bottom surface of the guide groove 15b.
[0027]
In addition, at the corner between the center piece 5a and the leg piece 5c, an overhanging portion is formed with an inclined surface 5d formed on the front surface where an inclined cut portion 102 formed at one corner of the front portion on the insertion side of the memory card MC abuts. 5e is provided.
[0028]
The front portion of the heart cam 15a is formed with a concave portion 15d opened to the front side, and when the pushing force of the memory card MC after the slider 5 is moved to the rearmost position is released, the shaft portion 16b of the cam pin 16 is formed in the concave portion 15d. By fitting, the movement of the slider 5 in the forward direction is restricted, and the slider 5 is held at a predetermined position. The leg piece 5c is provided with a holding hole 36 extending in the left-right direction at one end thereof in the recess 15d in which the shaft portion 16b of the cam pin 16 is engaged with the slider 5 held at a predetermined position. In the holding hole 36, a protruding piece 50b and an elastic contact piece 50c of a lock body 50, which will be described later, are press-fitted and held.
[0029]
The lock body 50 is formed, for example, by punching and bending a thin metal plate having elasticity such as stainless steel, as shown in FIGS. 11 (a) to 11 (c). A lever piece 50a disposed substantially parallel to the inner surface of the leg piece 5c, a protruding piece 50b protruding in a direction substantially perpendicular to the lever piece 50a from the lower edge of the front end of the lever piece 50a, and a protruding piece The elastic contact piece 50c which is continuously extended from the rear edge of the base portion 50b and is curved so that the intermediate portion protrudes backward, and the rectangular shape which protrudes from the rear end edge of the lever piece 50a to the side opposite to the side piece 5c. It is comprised with the locking piece 50d.
[0030]
The lock body 50 is held by the leg piece 5c by press-fitting the protruding piece 50b and the elastic contact piece 50c provided on the front end side into the holding hole 36 of the leg piece 5c, and the front end portion of the protruding piece 50b is formed in the recess 15d. It protrudes. Further, the leg piece 5 c is formed with a recessed portion 39 opened to the upper surface side and the inner surface side, and the lever piece 50 a of the lock body 50 is disposed inside the recessed portion 39.
[0031]
Since the inside of the holding hole 36 is formed with a wider width in the front-rear direction than the opening end on the inner surface side (memory card MC side), when the protruding piece 50 b and the elastic contact piece 50 c are inserted into the holding hole 36. Since the elastic contact piece 50 c is engaged with the opening edge of the holding hole 36, the lock body 50 is prevented from being detached from the holding hole 36, and the protruding piece 50 b and the elastic contact piece 50 c are free in the holding hole 36. Can be moved to. Here, the front end portion of the protruding piece 50b protrudes from the holding hole 36 into the recess 15d. When the shaft portion 16b of the cam pin 16 is fitted into the recess 15d when the memory card MC is locked, the biasing coil spring 13 is moved to the slider. The front end portion of the protruding piece 50b is pressed rearward by the shaft portion 16b with a force that biases the front portion 5 forward. Due to this pressing force, the rear end portion of the lever piece 50a is elastically deformed so as to bend in the direction approaching the memory card MC, and the locking piece 50d exits the recessed portion 39 and engages with the locking recess 103 of the memory card MC. This prevents the memory card MC from being removed. On the other hand, when the memory card MC is not locked, the shaft portion 16b of the cam pin 16 comes out of the recess 15d, so that there is no force to push the protruding piece 50b of the lock body 50 backward, and the lever piece 50a is locked by the elastic return force. The piece 50d is retracted from the locking recess 103 into the recess 39, and the locking state between the locking piece 50d and the locking recess 103 is released.
[0032]
Next, the assembly procedure of the connector device of this embodiment will be briefly described. When assembling the connector device, the spring seat protrusions 12 and 12 formed by bending the rear side ends 6a and 6b of the base shell 1 in parallel with the side pieces 6a and 6b from the rear ends of the base shell 1 are coil springs for biasing. The coil springs 13 and 13 for urging | biasing are distribute | arranged in the both sides of the rear part of the base shell 1 by inserting in the one end part of 13 and 13. FIG.
[0033]
Next, the contact block 4 is placed on the upper rear portion of the base shell 1. At this time, the projecting pieces 9 projecting to the rear end of the base shell 1 are press-fitted into the press-fitting holes 8 of the contact block 4 from below to fix the contact block 4 on the base shell 1. At this time, the rear end side portions of the urging coil springs 13 and 13 are accommodated in the recesses 47 and 47 formed on both side surfaces of the base body 7, respectively. Next, the slider 5 is placed on the base shell 1 on the front side of the contact block 4 thus arranged. At this time, the front portions of the biasing coil springs 13 and 13 are fitted into narrow grooves 35 formed on the rear side surfaces of both leg pieces 5 b and 5 c of the slider 5. The shaft portion 16 a at one end of the cam pin 16 is inserted into the shaft hole 14 b of the upright piece 14 a of the L-shaped piece 14 cut and raised from the side piece 6 a of the base shell 1, and the cam pin 16 of the slider 5 is supported. It is disposed between the leg piece 5c and the inner side of the side piece 6a of the base shell 1, and is further engaged with a heart cam groove portion 15 in which the shaft portion 16b at the other end of the cam pin 16 is formed on the front outer surface of the leg piece 5c. Enter. At this time, the cam pin 16 is urged in the direction of the leg piece 5c by the pressing spring piece 17 provided on the side piece 6a of the base shell 1.
[0034]
Here, the slider 5 is urged by the urging coil springs 13 and 13 and is pushed forward (to the memory card insertion slot 42 side) so that the inclined surfaces 34 and 34 formed at the front end portions of the both leg pieces 5b and 5c are based. Further forward movement of the slider 5 is restricted by abutting against the inclined surface portion of the back surface of the projecting pieces 18 provided at the front end of the shell 1. In this state, one end of the cam pin 16 has moved to the position a at the rear end of the guide groove 15b (see FIGS. 8 and 10). The slider 5 is attached to the slider 5 as described above.
[0035]
In this way, the contact block 4 and the slider 5 are arranged on the base shell 1, and the urging coil springs 13 and 13, the cam pin 16, and the lock body 50 are mounted, and then the cover shell 2 is moved to the base shell 1 from above. Cover. At this time, the protruding piece 21 formed at the rear end of the cover shell 2 is press-fitted into the press-fitting hole 22 of the base 7 of the contact block 4 from above, and the both side pieces 20 and 20 are placed outside the both side pieces 6a and 6b of the base shell 1. It hangs down along the side. At this time, the locking holes 41 provided so that the upward leading portions of the elastic locking pieces 40 formed by cutting and raising the both side pieces 20, 20 of the cover shell 2 correspond to the both side pieces 6 a, 6 b of the base shell 1. It will be locked to. As a result, the shells 1 and 2 are joined together to form a flat and box-shaped connector body 3 having a front opening in the insertion slot 42 of the memory card MC, and at the same time, the connector device is completed.
[0036]
Here, the connector device according to the present embodiment is mounted on the contacts 10 and the switch pieces 30 a, 30 b, 31 a, and 31 b on the lower surface of the soldering terminal portions 32 and the bottom surface of the base shell 1. A soldering piece 44 projecting forward from the lower surface of the projection 43, the front edge between the front end of the leg piece 5b and the projection piece 18 and the front edge between the front end of the leg piece 5c and the projection piece 18; An SMD type connector device having a lower bottom surface 44 is constructed. Further, by grounding the metal connector main body 3, it is strong against static electricity and external noise.
[0037]
7 to 9 show the connector device in a state where the memory card MC is not inserted. In this state, the slider 5 is moved in the forward direction (memory) by receiving the elastic force of the biasing coil springs 13 and 13. The card has been moved to the card insertion slot 42 side). In this state, since the shaft portion 16b of the cam pin 16 is located at the rear end portion of the guide groove 15b and is out of the lock position (recessed portion 15d), there is no force to push the protruding piece 50b of the lock body 50 backward, The locking piece 50d is retracted into the recessed portion 39 by the elastic restoring force of the lever piece 50a, and does not protrude inward from the inner side surface of the leg piece 5c.
[0038]
Next, the operation of each part when the memory card MC is inserted into the connector device of this embodiment will be described.
[0039]
First, when the memory card MC is inserted from the memory card insertion opening 42 of the connector main body 3 with the front and back direction and the front and back directions being in the normal direction, the downward step portions 101 and 101 on both sides of the lower surface of the memory card MC are the front end of the base shell 1. The tip of the memory card MC is inserted between the leg pieces 5b, 5c of the slider 5 in the connector body 3 and passes downward on the receiving guides 19a, 19b. The stepped portions 101 and 101 are on board. When the memory card MC is further inserted into the connector main body 3, the inclined cut portion 102 formed on one side of the front portion of the memory card MC eventually collides with the inclined surface 5d of the protruding portion 5e of the slider 5 to move the slider 5 backward. Will be pushed to. Further, when the memory card MC is further pushed in against the elastic force of the biasing coil springs 13 and 13 applied to the slider 5, the slider 5 moves backward in cooperation with the movement of the memory card MC. As the slider 5 moves backward, the shaft portion 16b of the cam pin 16 moves to the position b of the guide groove 15b below the heart cam 15a while being guided by the concave and convex surface 15c at the bottom of the guide groove 15b of the heart cam groove portion 15 (FIG. 10). When the memory card MC is pushed to a position close to the position where the rear surface of the central piece 5a of the slider 5 contacts the front surface of the base 7 of the contact block 4, the shaft portion 16b of the cam pin 16 reaches the position c where it contacts the front end portion of the guide groove 15b. (Refer to FIG. 10), and no further pressing is possible. When the pushing force applied to the memory card MC at this position is released, the slider 5 returns to the front together with the memory card MC by the elastic force of the biasing coil spring 13, but the shaft portion 16b of the cam pin 16 is guided to the guide groove 15b. It moves to the position d which fits into the recessed part 15d of the heart cam 15a. Therefore, when the shaft portion 16b of the cam pin 16 contacts the recess 15d of the heart cam 15a, further forward movement of the slider 5 is restricted, and the memory card MC remains in the connector body 3 at that position.
[0040]
Now, when the front portion of the memory card MC moves to a predetermined position by being pushed in, the front portion of each contact 10 that protrudes forward from the concave groove 33 on the lower surface of the central piece 5a of the slider 5 is on the back surface of the memory card MC. The formed corresponding I / O contact surfaces are sequentially contacted. Further, when the tip of the switch piece 30a protruding forward through the concave groove 33 of the central piece 5a of the slider 5 is pushed by the inclined cut portion 102 of the memory card MC and comes into contact with the other switch piece 30b, the switch is turned on. Using this switch signal, it is possible to detect that the memory card MC has been inserted into the normal position by an external detection circuit (not shown).
[0041]
Further, a concave portion 105 in which the write protection switch SW knob 104 is exposed is provided on one side surface of the memory card MC corresponding to the switch pieces 31a and 31b. When the tip of the switch piece 31b rides on the knob 104 or falls into the recess 105, the switch card 31b moves away from or comes into contact with the tip of the switch piece 31a located below, and the switch signal causes the memory card MC to enter the write protect state. It is possible to detect whether or not there is.
[0042]
While the memory card MC is mounted, the backward movement of the slider 5 is restricted by fitting the shaft 16b of the cam pin 16 into the recess 15d of the heart cam 15a. There is a risk of falling off. Therefore, in the present embodiment, when the slider 5 moves to a predetermined position and the shaft portion 16b of the cam pin 16 stays at the lock position (recessed portion 15d) of the heart cam 15a, the lock body 50 protruding into the recessed portion 15d from the holding hole 36 is provided. The protruding piece 50b is pressed backward by the shaft portion 16b of the cam pin 16, and by this pressing force, the rear end portion of the lever piece 50a is elastically deformed so as to bend toward the memory card MC, and is provided at the rear end portion of the lever piece 50a. The locking piece 50d protrudes from the recess 39 and protrudes inward from the inner surface of the leg piece 5c, and the locking piece 50d engages with the locking recess 103 of the memory card MC. Thus, the memory card MC is locked. This state is the state shown in FIGS.
[0043]
When the memory card MC inserted as described above is taken out from the connector device, first, the rear portion of the memory card MC exposed from the memory card insertion slot 42 of the connector body 3 is pushed in the insertion direction, and the memory card MC together with the slider 5 is inserted. Move to. By this movement, the shaft portion 16b of the cam pin 16 is detached from the concave portion 15d of the heart cam 15a and is guided by the guide groove 15b to move to a position e in the guide groove 15b above the concave portion 15d (see FIG. 10). At this time, the shaft portion 16b of the cam pin 16 is disengaged from the concave portion 15d, so that the shaft portion 16b moves the protruding piece 50b of the lock body 50 rearward by the force that the biasing coil spring 13 biases the slider 5 forward. Since the pressing force is lost, the front end portion of the protruding piece 50b protrudes from the holding hole 36 into the recess 15d, and the locking piece 50d is retracted into the recess 39 by the elastic return force of the lever piece 50a. The locked state between the stopper 50d and the locking recess 103 of the memory card MC is released (see FIG. 4). Thus, the locking piece 50d of the lock body 50 is engaged with the locking recess 103 only when the shaft portion 16b of the cam pin 16 is in the lock position (recess 15d), and when the shaft portion 16b is disengaged from the lock position. The locking state between the locking piece 50d and the locking recess 103 is reliably released. Thus, even when an excessive force is applied to the memory card MC when the memory card MC is pulled out, the locking piece 50d (the locking body 50d) is not engaged with the locking recess 103. ) And the recess 103 for locking can be reliably prevented.
[0044]
Thereafter, when the pushing force of the memory card MC is released, the slider 5 moves forward by the resilient force of the biasing coil springs 13 and 13. When the slider 5 moves forward, the shaft portion 16b of the cam pin 16 is guided by the guide groove 15b as the slider 5 moves, and the position f in the upper guide groove 15b of the heart cam 15a (FIGS. 5, 6, and 10). Browse through). The slider 5 moves to the memory card insertion slot 42 side by the elastic force of the biasing coil springs 13 and 13 and returns to the state shown in FIGS. 7 to 9, and the shaft portion 16b of the cam pin 16 is a guide. It moves to the position a of the rear end of the groove 15b. At this time, the rear part of the memory card MC is largely exposed to the outside from the memory card insertion slot 42 of the connector main body 3, and the memory card MC can be taken out from the connector main body 3.
[0045]
In the present embodiment, the connector device having the SMD structure has been described as an example. However, as shown in FIG. 17, the DIP and the stand-off leg pieces 45 that are cut and raised on the base shell 1 are projected downward. The soldering piece 44... May be formed in an L-shaped cross section to correspond to the DIP type, or the leg piece to the soldering part at the tip may be lengthened to correspond to the yr standoff type. The base shell 1 corresponding to each of SMD, DIP, and stand-off can be manufactured simply by changing the die for punching and bending.
[0046]
By the way, when the connector device is mounted on a board or the like, if it is necessary to insulate the circuit pattern of the board, or if it is necessary to insulate from other parts, the connector main body 3 that requires the insulating tape 46. It is good to stick on the surface (see FIG. 15).
[0047]
(Embodiment 2)
A second embodiment of the present invention will be described with reference to FIGS. Since the basic structure of the connector device is the same as that of the first embodiment, the same components are denoted by the same reference numerals and the description thereof will be omitted, and only the characteristic features of this embodiment will be described.
[0048]
In the first embodiment, the protruding piece 50 b and the elastic contact piece 50 c provided on the front end side of the lock body 50 are inserted into the holding hole 36 penetrating the leg piece 5 c of the slider 5, and the elastic contact piece 50 c is inserted into the holding hole 36. The lock body 50 is prevented from coming off by being locked to the opening edge, and the lock body 50 is held by the slider 5. In this embodiment, the front end side of the lock body 50 ′ is connected to the leg piece 5 c of the slider 5. It is press-fitted and fixed.
[0049]
The lock body 50 ′ is formed by punching and bending a thin metal plate having elasticity such as stainless steel, for example, as shown in FIGS. 22 (a) to 22 (c). A lever piece 50a disposed substantially parallel to the inner surface of the leg piece 5c, a protruding piece 50b protruding in a direction substantially perpendicular to the lever piece 50a from the lower edge of the front end portion of the lever piece 50a, and a lever It is comprised by the square-shaped latching piece 50d which protrudes from the rear end edge of the piece 50a on the opposite side to the side piece 5c, and the L-shaped press-fit piece 50e which protrudes ahead from the front end edge of the lever piece 50a.
[0050]
On the other hand, the leg piece 5c of the slider 5, as shown in FIG. 20, has a holding hole 36 extending in the left-right direction at one end in the recess 15d in which the shaft portion 16b of the cam pin 16 is engaged in the locked state of the memory card MC. A press-fit groove 37 is formed on the upper surface of the front end portion of the leg piece 5c.
[0051]
Thus, when the lock body 50 ′ is attached to the slider 5, the press-fitting piece 50e is press-fitted into the press-fitting groove 37 from above with the rear end side of the lever piece 50a being bent inward, and then the lever piece 50a. The rear end side is returned to the direction approaching the leg piece 5c, and the protruding piece 50b protruding from the front end side of the lever piece 50a is inserted into the holding hole 36 of the leg piece 5c, so that the lock body 50 'is attached. Is completed. Note that the opening edge of the holding hole 36 may be widened or the width of the protruding piece 50b may be narrowed so that the lock body 50 'can be easily attached.
[0052]
Here, when the lock body 50 ′ is attached to the slider 5, the front end portion of the protruding piece 50 b protrudes from the holding hole 36 into the recess 15 d of the heart cam groove portion 15.
[0053]
Thus, as described in the first embodiment, in the state where the memory card MC is mounted, the slider 5 moves to a predetermined position, and the shaft portion 16b of the cam pin 16 fits into the lock position (recessed portion 15d) of the heart cam 15a. Therefore, the protruding piece 50b of the lock body 50 'protruding from the holding hole 36 into the recess 15d is pressed backward by the shaft portion 16b of the cam pin 16, and the lever piece 50a is elastically deformed by this pressing force, and the lever piece 50a is press-fitted. Since it is bent toward the memory card MC with the connection portion with the piece 50e as a fulcrum, the locking piece 50d provided at the rear end of the lever piece 50a protrudes from the recessed portion 39, and the locking recess 103 of the memory card MC. The memory card MC is locked by engaging with.
[0054]
On the other hand, when the memory card MC is pulled out, if the rear portion of the memory card MC exposed from the memory card insertion port 42 of the connector body 3 is pushed in the insertion direction and the memory card MC is moved in the insertion direction together with the slider 5, the cam pin is moved by this movement. The sixteen shaft portions 16b are separated from the recess 15d of the heart cam 15a and are guided by the guide groove 15b to move to a position e in the guide groove 15b above the recess 15d. Thereafter, when the pushing force of the memory card MC is released, the slider 5 is moved forward by the resilient force of the biasing coil springs 13 and 13, and the shaft portion 16b of the cam pin 16 is guided by the movement of the slider 5. It moves to the position a of the rear end of the groove 15b. At this time, the rear part of the memory card MC is largely exposed to the outside from the memory card insertion slot 42 of the connector main body 3, and the memory card MC can be taken out from the connector main body 3.
[0055]
Here, when the shaft portion 16b of the cam pin 16 is disengaged from the recess 15d, the shaft portion 16b presses the protruding piece 50b of the lock body 50 ′ rearward by the force with which the biasing coil spring 13 biases the slider 5 forward. Thus, the front end portion of the protruding piece 50b protrudes from the holding hole 36 into the recess 15d, and the front end side of the lever piece 50a moves away from the memory card MC by the elastic return force of the lever piece 50a. At this time, the locking piece 50d provided at the tip of the lever piece 50a is retracted into the recess 39, and the locking state between the locking piece 50d and the locking recess 103 of the memory card MC is released.
[0056]
As described above, the locking piece 50d of the lock body 50 ′ is engaged with the locking recess 103 only when the shaft portion 16b of the cam pin 16 is in the lock position (recess 15d), and the shaft portion 16b is moved from the lock position. When released, the locked state between the locking piece 50d and the locking recess 103 is reliably released. Therefore, even if an excessive force is applied to the memory card MC when the memory card MC is pulled out, the locking piece 50d (the lock body 50) or the locking piece 50d is not engaged with the locking recess 103. Problems such as deformation of the locking recess 103 can be prevented.
[0057]
Each of the above-described embodiments is compatible with a multi-memory card (MMC) having the same outer shape except that the recess 103 is not provided, in addition to the memory card MC provided with the locking recess 103 such as an SD memory. When a memory card comprising this multi-memory card is inserted, the locking piece 50d of the lock body 50 is pushed by the side surface of the memory card, so that the front end side of the lock body 50 is bent to the opposite side of the memory card. It is supposed to be.
[0058]
【The invention's effect】
As described above, the invention of claim 1 is a box-like shape having a memory card insertion slot at the front, and a connector main body into which the memory card is slid and inserted / removed from the memory card insertion slot; A plurality of contacts disposed on the memory card and in contact with a plurality of I / O contact surfaces of the memory card, and disposed in the connector main body so as to be movable in the front-rear direction. A slider that moves forward and backward with the memory card, a biasing spring that constantly biases the slider forward, and a slider that locks the slider in place when the pushing force of the memory card is released after moving the slider to the rearmost position. Slider lock means for releasing the lock when the slider moves backward due to the pushing force applied to the memory card after the lock A card locking means for locking the memory card by engaging the locking recess of the memory card when the slider is locked at the predetermined position, and the slider locking means includes a heart cam groove formed on the surface of the slider; , One end is held by the connector body and the other end is engaged in the heart cam groove, and when the slider moves to the predetermined position, the other end is fitted into a recess opening on the front side provided in the heart cam groove so that the forward direction of the slider And a cam pin for restricting the movement of the card, and the card locking means is provided with an elastic portion in which one end side is held by a slider and a locking portion is provided on the other end side to engage with a locking recess of the memory card. A lock body having at least a part protruding into the recess of the heart cam groove integrally with the lock body. When the protrusion is pressed backward at the other end of the cam pin that has moved into the recess, the lock body is elastically deformed to cause the locking portion to enter the lock recess and the other end of the cam pin. However, when the force that moves from the concave portion and presses the protruding portion backward disappears, the locking portion is retracted from the concave portion for locking by the elastic restoring force of the lock body. By adopting such a configuration, when the memory card is locked, the slider moves to a predetermined position, and the other end of the cam pin fits into the recess of the heart cam groove as the slider moves. Due to the forward biasing force, the other end of the cam pin presses the protruding portion of the lock body protruding into the recess, and the locking body is elastically deformed by this pressing force, so that the locking portion is locked. It is possible to lock the memory card by entering the inside of the card. On the other hand, when the memory card is not locked, the other end of the cam pin moves out of the recess and moves in the heart cam groove part as the slider moves. Since the force that pushes the protruding part of the body backward is lost and the locking part is retracted from the locking recess by the elastic restoring force of the lock body, the locking part and the locking recess are locked. State can be reliably canceled. Therefore, when the memory card is not locked, there is no position where the locking portion engages with the locking recess, and even if the memory card is forcibly pulled out while pulling out the memory card, the locking portion becomes the locking recess. Since it is not engaged, the locking portion and the locking recess are not deformed, and there is an effect that it is possible to prevent an accident when the memory card is pulled out.
[Brief description of the drawings]
1A and 1B show a state in which the connector device of Embodiment 1 locks a memory card, wherein FIG. 1A is a top view of the main part, FIG. 1B is a side view of the main part viewed from the right side, and FIG. It is a front view of the principal part.
FIG. 2 shows a state in which the memory card is locked, (a) is a top view of the main part with the cover shell removed, and (b) is a cross-sectional view seen from the right side.
FIG. 3 is an explanatory diagram showing a state in which the memory card is locked.
4A and 4B show a state in which the memory card is inserted to the innermost part, where FIG. 4A is a top view of the main part with the cover shell removed, and FIG. 4B is a cross-sectional view seen from the right side.
5A and 5B show a state where the memory card is being pushed out from the above, wherein FIG. 5A is a top view of the main part with the cover shell removed, and FIG. 5B is a cross-sectional view seen from the right side.
FIG. 6 is an explanatory diagram of a state where the memory card is being pushed out from above.
FIG. 7 shows the state before the memory card is inserted. FIG. 7A is a top view of the main part, and FIG. 7B is a side view of the main part as viewed from the right side.
FIG. 8 shows the state before the memory card is inserted. FIG. 8A is a top view of the main part with the cover shell removed, and FIG. 8B is a cross-sectional view seen from the right side.
FIG. 9 is an explanatory diagram of a state before a memory card is inserted into the above.
FIGS. 10A and 10B show the slider, wherein FIG. 10A is a top view of the main part, and FIG. 10B is a side view of the main part.
11A is a cross-sectional view taken along the line XX in FIG. 10A, and FIG. 11B is a cross-sectional view taken along the line YY in FIG. 10A;
12A and 12B show the lock body of the same, wherein FIG. 12A is a top view, FIG. 12B is a side view seen from the right side, and FIG.
FIGS. 13A and 13B show a state in which a lock body is incorporated in the slider. FIG. 13A is a top view of the main part, and FIG. 13B is a side view of the main part.
14 is a cross-sectional view taken along line YY of FIG. 13A, showing a state in which a lock body is incorporated in the slider.
FIG. 15 is an exploded perspective view of the above.
FIG. 16 is a perspective view of the same.
17A is a rear view, FIG. 17B is a top view, FIG. 17C is a front view, and FIG. 17D is a side view as viewed from the right side.
18A and 18B show the same contact block, where FIG. 18A is a rear view, FIG. 18B is a top view, and FIG. 18C is a front view.
FIGS. 19A and 19B show the cover shell of the above, wherein FIG. 19A is a rear view, FIG. 19B is a top view, FIG. 19C is a front view, and FIG.
20A and 20B show a slider of the connector device according to the second embodiment, in which FIG. 20A is a top view of the main part, and FIG. 20B is a side view of the main part.
FIG. 21 is a cross-sectional view taken along the line YY of FIG.
22A and 22B show the lock body, wherein FIG. 22A is a top view, FIG. 22B is a side view seen from the right side, and FIG.
FIGS. 23A and 23B show a state in which a lock body is incorporated in the slider, and FIG. 23A is a top view of the main part, and FIG. 23B is a side view of the main part.
24 is a cross-sectional view taken along line YY of FIG. 23 (a), showing a state in which a lock body is incorporated in the slider.
[Explanation of symbols]
3 Connector body
5 Slider
5c Leg piece
15 Heart cam groove
15a heart cam
15d recess
16 cam pins
16a, 16b Shaft
50 lock body
50a lever piece
50b protruding piece
50d Locking piece
103 Locking recess
MC memory card

Claims (1)

A connector body having a memory card insertion slot at the front, wherein the memory card is slid out of the memory card insertion slot, and a plurality of I / O contacts of the memory card disposed inside the connector body A plurality of contacts each contacting the surface, a slider which is movably disposed in the front-rear direction inside the connector body, and moves in the front-rear direction together with the memory card when the memory card is inserted / removed from the memory card insertion slot, and a slider When the release force of the memory card after the slider is moved to the rearmost position of the slider is released, the slider is locked at a predetermined position, and the pushing force to the memory card is applied after the lock. Slider lock means for releasing the lock when the slider moves backward, and the slider is locked at the predetermined position. When click a card locking means for locking the memory card by entering engages the locking recess of the memory card,
The slider locking means includes a heart cam groove formed on the surface of the slider, one end held by the connector body and the other end engaged in the heart cam groove, and provided in the heart cam groove when the slider moves to the predetermined position. The other end is fitted in a recess opening on the front side and the cam pin restricts the movement of the slider in the forward direction, and the card locking means is held by the slider on one end side and the memory card on the other end side. It is composed of an elastic lock body provided with a locking portion to be engaged with the recess for locking, and a protrusion for projecting at least a part into the recess of the heart cam groove is provided integrally with the lock body, When the protruding part is pressed backward at the other end of the cam pin that has moved into the recess, the lock body is elastically deformed and the locking part enters the locking recess. And the other end of the cam pin moves from the concave portion and the locking portion is retracted from the concave portion for locking by the elastic restoring force of the lock body when the force for pushing the protruding portion backward is lost. Connector device.

Images