KR20090004541A - Socket for memory card - Google Patents

Abstract

A socket for a memory card is provided to prevent a socket body from being deformed by an external force when inserting the card, thereby improving assembling workability. A socket for a memory card comprises a socket body(3), a contact block, a slider(5), a slider rocking unit and a card rocking unit(24). The contact block is installed inside the socket body. The contact block supports contacts respectively contacted with a plurality of I/O contact surfaces installed in one surface of the memory card. The slider is movably arranged in forward/backward directions in the socket body. The slider is moved forward/backward with the memory card according as the memory card is inserted from a card insertion hole. The slider locking unit locks the slider at a predetermined location when a force which inserts the memory card is released after the slider is moved to a ultimate end location.

Description

Socket for memory card {SOCKET FOR MEMORY CARD}

The present invention is capable of inserting and inserting a SDIO card having the same size and terminal arrangement as a memory card such as an SD memory card (registered trademark) or a multimedia card (MCC) or an SD memory card (registered trademark). A memory card socket for connecting.

For example, the conventional memory card socket described in Japanese Patent Laid-Open No. 2003-217713 has a box shape having a card insertion opening on its front surface, and includes a socket body in which a memory card slides and is inserted from the card insertion opening, and inside the socket body. A resin base body disposed at the rear part of the battery, a plurality of contacts supported by the base body and respectively contacting a plurality of I / O contact surfaces of the memory card, and inside and behind the socket body. A slider which is arranged to be movable and moves forward and backward with the memory card according to the insertion and insertion operation of the memory card from the card insertion opening, a coil spring that always biases the slider forward, and one end ( The cam pin is supported on the socket body and the other end is coupled to the heart cam groove provided on the slider, and is mounted on the slider to install the memory card. And a locking body engaged with the locking recess provided in the side surface of the memory card.

In such a memory card socket, a metal shell (first metal shell and a second metal shell) divided into two in the thickness direction formed by bending a stainless metal plate having a very thin thickness together with punching is formed of a resin. The socket body is formed by press-fitting the basic body from both the upper and lower sides in the thickness direction. Here, in assembling the socket body, the first metal shell is press-fitted into one surface of the base body, and then the second metal shell is press-fitted from the side opposite to the base body. At that time, if a force for pressing the second metal shell into the base body is applied to the first metal shell already fixed to the base body, the first metal shell may deform.

Thus, of the first metal shell and the second metal shell constituting the socket body, only the first metal shell is press-fit and fixed to the base body, and the second metal shell is laser welded or the like to the first metal shell press-fit and fixed to the base body. In this way, it is proposed to prevent excessive force from being applied to the first metal shell when the socket body is coupled. In this case, since only the first metal shell is press-fitted and fixed to the resin base body, and the second metal shell is coupled to the first metal shell by laser welding, the base body supporting the contact has a first side in one of the up and down directions. Only the metal shell is connected to the socket body.

When the memory card is moved in the front-rear direction at the time of card insertion and insertion, external force is applied to the basic body supporting the contact in the forward or rearward direction through the contact in contact with the I / O contact surface of the memory card. However, since the basic body supporting the contact is not fixed to the socket body only on one side (the first metal shell) in the thickness direction, the end of the side which is not fixed to the socket body is There is a possibility that the card may fall forward or backward due to an external force applied when the card is removed.

The present invention has been made in view of the above problems, and an object thereof is to provide a memory card socket which prevents the socket body from being deformed by an external force applied when the card is inserted or removed.

In order to achieve the above object, Claim 1 invention,

A box-shaped socket main body having a card insertion slot into which a memory card is inserted in the front surface,

A contact block provided inside the socket body for supporting a plurality of contacts in contact with a plurality of I / O contact surfaces provided on one surface of a memory card,

A slider which is disposed in the socket body so as to be movable in the front-rear direction, and which moves in the front-rear direction together with the memory card according to the insertion / retraction operation of the memory card from the card insertion hole;

A bushing spring which always biases the slider forward,

After moving to the last position of the slider, when the push force of the memory card is released, the slider is locked at a predetermined position, and after the lock, the push force to the memory card is applied to the slider. Slider locking means for releasing the locking when the vehicle moves backwards,

A socket for a memory card having card locking means for engaging the locking recess of the memory card to lock the memory card when the slider is locked at the predetermined position,

The card locking means is composed of a locking body having one end supported by the socket main body and an elastic member having a coupling part coupled to the locking recess of the memory card at the other end.

The slider has a pressing portion for pressing the locking body toward the memory card when the slider is moved to the predetermined position.

In the state where the slider is moved to the predetermined position, the locking member is pressed by the pressing portion of the slider to elastically deform so that the engaging portion enters into the locking recess of the memory card, and when the memory card is not inserted, In the state where the slider is moved forward, the locking body is moved away from the pressing portion, and the engaging portion is retracted from the locking recess by the elastic return force of the locking body.

Claim 2 In the invention, the memory card socket according to claim 1,

The slider locking means, the heart cam groove portion formed on the surface of the slider, one end is supported by the socket body and the other end is coupled to the heart cam groove portion, when the slider moves to the predetermined position, the heart cam groove portion The other end is inserted into a recessed opening that is provided in the forward direction, and consists of a cam pin that regulates the forward movement of the slider.

From the side formed by folding the front edge of the first metal shell backward, an L-shaped support piece is provided with an axial hole for coupling one end of the cam pin to axially support the cam pin. And a welding piece welded to the support piece in a state in which the second metal shell is in contact with the support piece.

3. In the memory card socket according to claim 2, in the memory card socket according to claim 2, by pressing a portion of the second metal shell, a pressing piece which contacts one end side of the cam pin and attaches one end side of the cam pin to the support piece side is further provided. It is characterized by that.

4. The invention is a memory card socket according to claim 1,

A metal movable contact plate that is pressed by the memory card when the memory card is inserted into the socket body, and a fixed contact plate that contacts the movable contact plate when the movable contact plate is bent.接点 板) is further provided,

The movable contact plate includes a press-fit portion into which both side edges in the width direction of the push-in groove are provided in the base body, and the press-fit portion is fixed to the fixed contact. The contact spring is further provided with a contact spring portion provided on the free end side in contact with the contact separation.

In the press-fitting part of the movable contact plate, a surface mounting terminal surface-mounted on a mounting board is extended from one side edge in the thickness direction of the socket main body. It is formed in the shape which is symmetrical with respect to the central axis of the mounting terminal in the width direction.

5. The invention is a memory card socket according to claim 4,

The contact spring portion of the movable contact plate extends from one end side in the width direction of the press-fit portion, and the movable contact is provided on the tip side thereof.

The basic body is in contact with the other end portion of the contact spring portion in the width direction of the first contact portion and the first contact portion in contact with the front end side portion of the contact spring portion in the direction of pressing the press-in portion into the basic body. It characterized by having a second contact portion.

6. The invention relates to a socket for a memory card according to claim 5, wherein the first contact portion and the second contact portion are formed on a basic body portion other than a portion through which the press-in portion passes when the press-in portion is press-fitted into the press-in groove. Characterized in that installed.

7. In the memory card socket according to any one of claims 4 to 6, the invention provides a guide groove into which the protrusion is fitted, while providing a protrusion projecting in the thickness direction by cutting a portion of the press-fit portion. Characterized in that provided on the basic body.

8. The invention is a socket for a memory card according to claim 1,

The card locking means is provided on the side of the slider which is disposed to face the side of the memory card while the front part of the memory card is in contact with the slider, and the memory card is provided in the locking recess of the memory card. It is characterized by including the 1st fitting protrusion fitted from the side of the.

A nineth aspect of the present invention is the memory card socket according to claim 8, wherein the corner portions of the first fitting protrusion are formed in a curved shape in the insertion direction of the memory card.

10. The invention provides a memory card socket according to any one of claims 8 and 9.

The card locking means is provided on a surface of the slider which is arranged to face one surface in the thickness direction of the memory card while the front portion of the memory card is brought into contact with the slider. And a second fitting protrusion fitted to the locking recess of the memory card from the thickness direction of the memory card.

According to the invention, the card locking means comprises a locking body having one end supported by a socket main body and an elastic locking member provided at the other end coupled to a locking recess of a memory card, and the slider being moved to a predetermined position. When it is moved, the pressing portion for pressing the locking body toward the memory card side is provided on the slider side, and in the state where the slider is moved to the predetermined position, the locking body is pressed by the pressing portion of the slider to elastically deform, and the engaging portion is inserted into the locking recess of the memory card. When entering, the locking body moves away from the pressing part in the state where the slider is moved forward when the memory card is not inserted, so that the engaging portion is retracted from the locking recess by the elastic return force of the locking body. At the time of assembly, we can perform assembling work without locking body, and we put tension on locking body and bend Has the effect of that, it improves the workability of the assembling work as compared to the case of performing the assembly operation.

According to the present invention, the support piece formed by folding the front edge of the first metal shell to the rear is brought into contact with the weld piece provided in the second metal shell, and the support piece and the weld piece are welded and fixed. The welding piece of the other side of the metal shell is welded and fixed to the support piece provided with the shaft hole rotatably pivoted to improve the strength of the support piece, and the cam pin moves in the heart cam groove as the slider moves forward and backward. As a result, the front and rear operations of the slider, that is, the insertion and removal operations of the memory card, are stabilized, and the insertion and life of the memory card is improved.

According to the invention, since one end side of the cam pin is pushed to the support piece side by the pressing piece formed by cutting a part of the second metal shell, the one end side of the cam pin can be prevented from falling out from the shaft hole provided in the support piece. It has the effect that it can be.

According to the invention, since the left and right side edges of the press-fit portion of the movable contact plate formed in a shape symmetrical with respect to the center axis in the width direction of the surface-mount terminal are press-fitted into the basic body press-fit groove, Even if an external force capable of rotating the movable contact plate centering on the mounting position is applied to the press-fitting part, both sides of the press-fitting part are equally applied. Therefore, it has the effect of being able to raise the support strength with respect to the basic body of the press contact part of a movable contact plate.

According to the invention, the contact spring is brought into contact with the distal end portion and the first contact portion in the pressing direction in the contact spring portion provided with the movable contact, and the contact spring is contacted with the other end portion and the second contact portion in the width direction of the pressing portion. We can position the wealth. As a result, even when the position of the movable contact is far from the press-fitting portion, the contact spring portion can be prevented from falling and the positional accuracy of the movable contact can be improved.

According to the sixth aspect of the present invention, when the press-fitting part is press-fitted into the press-fitting groove, the press-fitting part contacts the first contact part and the second contact part, so that the first contact part and the second contact part can be prevented from being cut off, Positioning accuracy can be improved.

According to the seventh aspect of the present invention, when the press-fitting part is temporarily press-fitted into the press-fitting groove, the protruding piece is fitted into the guide groove, so that the press-fitting part can be guided. In addition, when an external force capable of rotating the movable contact plate is applied to the press-fitting portion after the press-fitting, the protruding piece abuts against the end face of the guide groove, thereby having an effect that the collapse of the press-fitting portion can be prevented.

According to the eighth aspect of the present invention, when the memory card is taken out, the first fitting protrusion provided on the slider is fitted to the locking recess of the memory card, so that the memory card can be prevented from popping out. In addition, the dimensional tolerance in the width direction of the memory card (the direction perpendicular to the card insertion direction and the thickness direction) reduces the positional deviation of the I / O contact surface, thereby ensuring electrical connection. The first fitting protrusions provided on the sliders are more rigid than the ones, and the first fitting protrusions are fitted into the locking recesses from the side having a small dimensional tolerance. It can be surely obtained.

According to the aspect of the invention, since the corner portions of the first fitting protrusion are formed in a curved shape, the movement when the locking concave portion passes over the first fitting protrusion can be smoothed, and the operation feeling can be improved. Has the effect.

According to the tenth aspect of the present invention, in addition to the first fitting protrusion, since the second fitting protrusion provided on the slider is engaged in the locking recess from the thickness direction, it has an effect of more reliably preventing the slider from popping out. .

EMBODIMENT OF THE INVENTION Hereinafter, the memory card socket which concerns on one Embodiment of this invention is demonstrated, referring FIGS. In addition, in the following description, unless otherwise indicated, the arrow a-b in FIG. 1 (a) is an up-down direction (thickness direction), the arrow c-d is a left-right direction (width direction), and the arrow e-f is a front-back direction It demonstrates as (depth direction).

Fig. 1A is a perspective view showing the configuration of a memory card MC such as an SD memory card (registered trademark) and the memory card socket of the present embodiment corresponding thereto, and (b) is an enlarged main part thereof. Perspective view. Fig. 2 is an exploded perspective view of the memory card socket of the present embodiment, and Fig. 3 is an exploded perspective view of them viewed from the opposite side.

The memory card socket of the present embodiment includes a flat box-shaped socket body 3 having a card insertion opening 3a formed on the front surface thereof. The socket body 3 is formed of a very thin stainless metal plate. The base shell 1 formed by punching and bending and the base shell 1 formed by punching and bending a very thin stainless metal plate similarly to the base shell 1 are formed. It consists of the cover shell 2 which adheres on (). In the vicinity of the rear end inside the socket body 3, the contact block 4 is mounted, and in front of the contact block 4, L moving the inside of the socket body 3 in the front-rear direction. The slider 5 which consists of a female resin molded article is arrange | positioned.

As shown in Figs. 7A and 7B, the base shell 1 corresponds to the upper side (the socket body 3) inside the upper and lower sides (thickness direction) of the rectangular metal plate. The side piece 6a and the side piece 6b which were bent | folded by () were formed, and the edge part of the front-back direction of the base shell 1 is opened. In the following description, the substantially rectangular plate-shaped part between the side piece 6a and the side piece 6b of the base shell 1 is called the bottom plate 1c. At the rear end of the bottom plate 1c of the base shell 1, protrusion pieces 9 protruding upward are bent at four positions in the left and right directions at predetermined intervals. Further, at the left end of the bottom plate 1c of the base shell 1, the projecting pieces 9 protruding upwards are bent at three locations in the front-rear direction at predetermined intervals. These protruding pieces 9 are press-fitted from below into the press-fitting groove 8 (refer to FIG. 9 (b)) which opened in the lower surface of the resin basic body 7 of the contact block 4. The contact block 4 is press-fitted to the upper surface of the bottom plate 1c of the base shell 1. In addition, at a position slightly forward of the rear end of the bottom plate 1c of the base shell 1, a plurality of holes 11... For inserting the angle contacts 10... Supported by the contact block 4 described later are provided. (Iii) It is formed.

On the right edge of the front side edge of the base shell 1 bottom plate 1c, it protrudes upward from the position outside of the memory card MC, and the front end side thereof The L-shaped support piece 12 is bent from the side to protrude in the rearward direction. The bottom plate 1c of the support piece 12 and the base shell 1 forms a substantially c-shaped cross section. On the upper surface of the support piece 12, a coupling hole 12a into which the shaft portion 16b on one end side of the cam pin 16 to be described later is fitted is formed. As the shaft portion 16b is fitted into the engaging hole 12a and supported, the cam pin 16 is pivotally supported relative to the support piece 12. In addition, at the right edge of the base plate 1 bottom plate 1c, two protrusions which guide the slider 5 into the grooves 27 of the slider 5 to be described later are guided. (13) is formed side by side in the front-rear direction by cutting. In addition, the left side of the front side edge of the base shell 1 bottom plate 1c is coupled to the front end of the arm portion 7b of the basic body 7 of the contact block 4 described later. The joining piece 1a is bent.

As shown in Figs. 9A to 9C, the contact block 4 is disposed along the rear sides of the base shell 1 and the cover shell 2, and the socket body 3 is disposed. An arm part which protrudes forward from the left end of the base part 7a which obstruct | occludes the back surface, and is arrange | positioned along the side piece 6b of the base shell 1 ( 7b) has a basic body 7 composed of an L-shaped resin molded article integrally formed. At the right end of the front surface of the base 7a, a round rod-shaped spring bearing 7c supporting the one end side of the coil spring 14 which pushes (pushes) the slider 5 forward is protrudingly installed. In addition, a rectangular fitting projection 7e protrudes from the right end of the upper surface of the base 7a. In the arm portion 7b, a stepped portion 7d which extends along the slide direction of the memory card MC from the connection portion with the base 7a and faces the rear surface of the memory card MC is formed.

On each corner of the upper side (cover shell 2 side) of the front surface of the base 7a, the engaging recess part 17 which engages with the protrusion piece 20 of the cover shell 2 mentioned later, It is installed in three places at intervals in the left and right directions. Moreover, the engaging recess part 18 which engages with the bending piece 19 of the cover shell 2 mentioned later is formed in the upper corner | angular part of the back surface of the base 7a over substantially the whole of the left-right direction. In addition, nine contacts 10... Which correspond to respective I / O contact surfaces (not shown) formed on the rear surface of the memory card MC in parallel with each other (nine in SD memory) are each contact ( 10... Is press-fitted to the base 7a of the base body 7 so that the contact side of 10... 10 protrudes toward the front surface (card insertion hole 3a) side of the base 7a.

The common terminal board 30, the common terminal board 30, and the press-in groove 33, the press-in groove 34, and the press-in groove 35 (refer to FIG. 14, FIG. 15, etc.) provided on the upper surface of the arm part 7b. The contact for detecting position of the write prevention switch 100 of the memory card MC together with the movable contact plate (switch piece) 31 constituting the mounting detection contact of the memory card MC and the common terminal board 30 together. The movable contact plate (switch piece) 32 constituting the above is press-fitted from the upper surface side. The contact spring portions 31b and 32b of the respective movable contact plates 31 and 32 are formed in the inward direction of the socket body 3 from the concave portion formed in the arm portion 7b (accommodating space of the memory card MC). Protrude to the side). The contact spring part 31b and the contact spring part 32b of the movable contact plate 31 and the movable contact plate 32 are each the fixed contact plate 41 and the fixed contact plate 42 provided in the common terminal board 30, respectively. Contact with Further, the solder terminals 10a of the contacts 10... Protrude upward (mounting board side) from the rear surface of the base 7a, and the solder terminals 30a of the common terminal board 30 and each movable contact plate ( The solder terminals 31a and 32a of 31 and 32 protrude upward from the outer surface of the arm portion 7b, respectively.

As shown in Figs. 17A to 17C, the common terminal board 30 is formed by punching and bending a band-shaped metal plate having elasticity and having one end side in the longitudinal direction above. An L-shaped soldering terminal 30a protrudes from the side and faces upward. In addition, the cantilever-shaped fixed contact plate 41 and the fixed contact plate 42 are formed in the middle part of the longitudinal direction of the common terminal board 30, and the upper edge of the other end side, respectively. The fixed contact 41a and the fixed contact 42a which protrude inwardly of the socket main body 3 are provided in the vicinity of the front end of the free end side of each fixed contact plate 41 and 42, and the middle part of a longitudinal direction is an outer side. Bent towards When the common terminal plate 30 is press-fitted into the press-fit groove 33 of the arm portion 7b of the basic body 7 of the contact block 4, the fixed contact plate 41 and the fixed contact plate 42 are fixed to the fixed contact point. The tip end of the free end side on which the 41a and the fixed contact 42a are formed is disposed in the recess 36 provided in the arm portion 7b (see FIGS. 14 to 16).

Next, the movable contact plate 31 and the movable contact plate 32 will be described. In addition, since the movable contact plate 31 and the movable contact plate 32 are formed in the same shape, the movable contact plate 31 is demonstrated with reference to FIGS. 18 (a)-(c), and the movable contact plate ( 32, illustration and description are omitted.

The movable contact plate 31 is formed by punching and bending a metal plate having elasticity, and has a rectangular indentation groove 34 provided on the upper surface of the arm portion 7b of the basic body 7 of the contact block 4. (In the case of the movable contact plate 32, the press-in portion 31d press-fitted into the press-in groove 35, and the contact spring portion projecting from the press-in portion 31d in a direction orthogonal to the solder terminal 31a ( 31b). Two projections 31g protruding laterally are provided at the lower sides of the left and right side edges of the press-fitting portion 31d, and the maximum width between the two projections 31g is the arm portion 7b of the basic body 7. Since it is larger than the width of the press-in groove 34 provided in the (), the press-in part 31d is press-fitted and fixed to the press-in groove 34. The contact part 31e which protrudes in the same direction is formed above the protrusion part 31g which protrudes on the opposite side to the contact spring part 31b among the two protrusion parts 31g of the press-fit part 31d. Moreover, the projection part 31f which protrudes toward the inside of the socket main body 3 is formed in the center part of the press-in part 31d.

As shown in Figs. 18A and 18C, the contact spring portion 31b has a band shape when viewed from the front, and as shown in Fig. 18B, the free end side vicinity is almost U-shaped in plan view. It is formed to bend. The soldering terminal 31a is almost L-shaped from the side, and is formed to protrude upward from one side edge of the press-fitting portion 31d in the thickness direction of the socket body 3. In addition, the pinch notch 31c which contacts the fixed contact 41a is formed in the site | part immediately before the curved part formed in the front-end | tip side of the contact spring part 31b, and from the site | part in which this pinch notch 31c was formed, The movable contact which separates contact from the stationary contact 41a is comprised.

Here, the soldering terminal 31a of the movable contact plate 31 extends from one side (upper side) edge of the press-fitting portion 31d in the vertical direction (thickness direction) of the socket body 3. In addition, two projections 31g protruding in opposite directions from the lower sides of both side edges of the press-fit part 31d are formed, and the shape of the press-fit part 31d is defined in the width direction of the solder terminal 31a. It is formed in a shape symmetrical with respect to the central axis of. Therefore, in the state where the movable contact plate 31 is press-fitted into the press-in groove 34, the external force which can rotate the movable contact plate 31 centering on the mounting position of the soldering terminal 31a is press-in part 31d. ), Even if both side edges of the press-in part 31d are equally applied, the support strength of the movable contact plate 31 with respect to the base body 7 can be increased. The same applies to the movable contact plate 32.

Further, when the movable contact plates 31 and 32 are press-fitted into the press-in groove 34 and the press-in groove 35 formed on the upper surface of the arm portion 7b of the base body 7 of the contact block 4, respectively, The curved portion provided on the contact spring portion 31b of the contact plates 31 and 32 and the tip side of the contact spring portion 32b is the inner side of the socket body 3 via the recessed portion 36 of the arm portion 7b. It projects in the direction (the storage space side of the memory card MC) (see FIGS. 14 to 16).

As shown in FIG. 16, the contact body part 31b and the contact spring part of the movable contact plate 31 and the movable contact plate 32 are attached to the arm part 7b of the basic body 7 of the contact block 4. Rib (first contact portion) that abuts against the lower edge (front end side portion in the press-in direction) of 32b) and a rib (second contact portion) that contacts the other end side portion in the width direction of the press-in portion 31d. Since the 38 is formed, when the movable contact plates 31 and 32 are press-fitted and fixed to the press-in groove 34 and the press-in groove 35, respectively, the contact spring portion 31b and the contact spring portion 32b are formed. The rib 37 abuts on the lower edge, and the rib 38 is provided at an end opposite to the side where the contact spring portion 31b and the contact spring portion 32b protrude from the press-in portion 31d and the press-in portion 32d. ) Meets. Thereby, the contact spring part 31b and the contact spring part 32b can be positioned, and even when the position of a movable contact is far from the press-in part 31d and the press-in part 32d, the contact spring part 31b is carried out. And the contact spring portion 32b is prevented from falling, and the positional accuracy of the movable contact can be improved. In addition, the rib 37 and the rib 38, when pressing the press-in portion 31d and the press-in portion 23d into the press-in groove 34 and the press-in groove 35, the base body 7 arm portion 7b. Since the indentation part 31d and the indentation part 32d in () are respectively provided in parts other than the part which passes, the rib 37 and the rib 38 when the indentation part 31d and the indentation part 32d are press-fitted ) Can be prevented from being cut, the contact spring portion 31b and the contact spring portion 32b can be reliably positioned, and the positional accuracy of the movable contact can be improved.

In addition, projections 31f and projections 32f formed by cutting out and erecting part of the press-in portion 31d and the press-in portion 32d are fitted into end faces of the press-in groove 34 and the press-in groove 35. The guide groove 34a and the guide groove 35a are formed. Therefore, when the press-fit part 31d and the press-fit part 32d are temporarily press-fitted into the press-in groove 34 and the press-in groove 35, the projection part 31f and the projection part 32f guide the guide groove 34a and guide. By being fitted in the groove 35a, the press-fit part 31d and the press-fit part 32d can be guided. In addition, when the external force which can rotate the movable contact plate 31 and the movable contact plate 32 after press injection is applied to the press fitting part 31d and the press fitting part 32d, the protrusion part 31f and the protrusion part 32f are carried out. Is in contact with the end faces of the guide groove 34a and the guide groove 35a, thereby preventing the indentation portion 31d and the indentation portion 32d (that is, the movable contact plate 31 and the movable contact plate 32) from falling down. Can be.

As shown in Figs. 8A and 8B, the cover shell 2 is formed in such a manner that the trailing edge of the rectangular metal plate is substantially perpendicular to the main surface, that is, the lower surface (socket body). It has the bending piece 19 (2nd contact piece) formed by bending in the side direction (corresponding to the inside of (3)). In the following description, the main surface of the metal plate is referred to as a top plate 2c of the cover shell 2. Three protruding pieces 20 protruding downward while being substantially perpendicular to the top plate 2c near the front end of the bent piece 19 of the top plate 2c of the cover shell 2 (first). A contact piece) is bent. On the right side of the rear face of the top plate 2c of the cover shell 2, a fitting hole 2b through which the fitting protrusion 7e of the basic body 7 is fitted penetrates, and the cover shell 2 is provided. The L-shaped welding piece 2a protruding downward is bent in the front part of the right edge of the top plate 2c.

In addition, the front surface of the top plate 2c of the cover shell 2 is elastically contacted with the surface of the memory card MC to press the memory card MC, and a grand terminal provided on the top surface of the SDIO card for the SDIO card. Two elastic contact spring pieces 21 which are in elastic contact with each other are formed by punching and bending. In addition, at the one end of the front side of the top plate 2c of the cover shell 2 and at the portion of the base shell 1 opposite to the support piece 12, the one end side shaft portion of the cam pin 16 is located. The pressing piece 22 which prevents the fall of the shaft part 16b by pressing 16b is formed by cutting out. In addition, the guide which describes the front-end | tip of the shaft part 16a by pressing the other end side shaft part 16a of the cam pin 16 in the vicinity of the pressing piece 22 while being the front right end part of the cover plate 2 top plate 2c. The T-shaped elastic contact spring piece 23 which abuts against the uneven surface 15c of the groove 15b is formed by performing punching processing and bending processing.

Close to the rear end of the right end of the cover shell (2) top plate (2c), the locking body 24 is coupled to the locking recess 101 of the memory card (MC) at the time of mounting the memory card (MC) to prevent it from falling out It is formed by performing punching processing and bending processing. The locking body 24 has an elongated strip-shaped plate shape, which is substantially parallel to the side pieces 6a of the base shell 1, and its rear end is connected to the cover shell 2, and its front end is bent inwardly. It is comprised by 24a and the engaging piece 24b extended toward the front from the front end part of the lever piece 24a, and the front end side curved in circular arc toward the inner direction (refer FIG. 8 (b)). . Here, the locking body 24 is coupled to the locking concave portion 101 of the memory card MC when the slider 5 is locked at a predetermined position when the memory card MC is mounted. ), A card locking mechanism is formed.

The slider 5 is a synthetic resin molded article formed in an L shape and, as shown in Figs. 10A to 10D, an arm portion 5a which abuts on the right edge of the memory card MC, And a protruding portion 5b which protrudes laterally from the rear end of the arm portion 5a and abuts on the front edge of the memory card MC. In the corner portion surrounded by the arm portion 5a and the protrusion portion 5b of the slider 5, the inclined surface in contact with the inclined cut portion 102 formed on the front right side of the memory card MC is entirely covered. The contact part 5c provided in the front surface is formed. The inner side of the arm portion 5a (the left side in Fig. 10 (b)) extends from the contact portion 5c along the sliding direction of the memory card MC to face the rear surface of the memory card MC. 5d of steps are formed.

And as shown in FIG. 23, in the state which contacted the front part of the memory card MC to the protrusion part 5b of the slider 5, the step part 5d which opposes the side surface of the memory card MC ), The fitting projection 39 (fitted to the locking recess 101 of the memory card MC from the side of the memory card MC (the direction perpendicular to the card insertion direction and the thickness direction respectively) ( The first fitting projection is provided, and the fitting projection 40 is fitted to the locking recess 101 at the bottom of the step portion 5d from the thickness direction of the memory card MC. 2 fitting protrusions protrude. 21 and 22, curved surfaces 39a and curved surfaces 40a are formed on both side portions of each of the fitting protrusions 39 and 40 in the inserting / removing direction of the memory card MC, respectively. have.

On the other hand, as shown in FIG.10 (c), in the lower surface of the arm part 5a of the slider 5, the micro groove in which the cross section which opened the outer side, the lower side, and the rear side from the rear end part to the center part was almost circular arc shape ( 26 is formed, a part of the above-described coil spring 14 is accommodated in the microgroove 26, and the front end face 26a of the microgroove 26 is the elastic repulsive force of the coil spring 14. Is the side that receives the In addition, in the lower surface of the arm portion 5a, the front and rear sides and the lower side are opened, and the groove 27 to which the protruding portion 13 of the base shell 1 is engaged is formed along the front and rear directions.

That is, upon completion of assembling the socket for the memory card, the slider 5 has a main plane, a side piece 6a, and two protrusions 13 and a cover shell 2 of the base shell 1. The movement direction is regulated by the plane, and further movement to the front is regulated by contacting the front end portion of the arm portion 5a to the support piece 12 of the base shell 1. Since the slider 5 is biased forward by the coil spring 14, when the memory card MC is inserted into the socket body 3, the I / O contact surface of the memory card MC contacts the contact 10. The slider 5 slides between the position where the memory card MC and the memory card MC can be pulled out of the socket body 3.

On the upper surface of the front side portion of the arm portion 5a of the slider 5, a heart cam groove portion 15 is formed to which the shaft portion 16a of the cam pin 16 is movably coupled. The groove 25 into which the locking body 24 provided in the cover shell 2 is inserted is formed. The heart cam groove part 15 is comprised from the heart cam 15a and the guide groove 15b formed in the periphery of the heart cam 15a, as shown to FIG. 10 (a) and (d). When the shaft portion 16a of the cam pin 16 is coupled to the guide groove 15b, the relative movement in the guide groove 15b of the shaft portion 16a of the cam pin 16 due to the forward and backward movement of the slider 5 is guided. It guides to the uneven surface 15c formed in the bottom surface of the groove 15b and the guide groove 15b.

The recessed part 15d opened to the front side is formed in the front part of the front side part of the arm part 5a of the slider 5, and the heart cam 15a. After the slider 5 is moved to the rearmost position, when the pushing force of the memory card MC is released, the shaft portion 16a of the cam pin 16 is fitted into the recessed portion 15d. As a result, the movement forward of the slider 5 is regulated, and the slider 5 is supported at a predetermined position.

Moreover, in the right end surface of the groove 25 provided in the upper surface of the arm part 5a of the slider 5, the elongate part 29 which protrudes in the inward direction of the socket main body 3 is provided. It is formed in the front part. When the slider 5 is moved to the predetermined position, as shown in Fig. 24A, the elongated portion 29 pushes the lever piece 24a of the locking body 24 so that the locking body 24 is elastically deformed. Then, the front part (locking piece 24b) of the locking body 24 enters into the locking recess 101 of the memory card MC to lock the memory card MC. On the other hand, as shown in Fig. 24B, when the memory card MC is not attached, in the state where the slider 5 is moved to the ejection position of the memory card MC, the ejecting portion 29 Since the force of bending the locking body 24 disappears away from the locking body 24, the tip of the engaging piece 24b is retracted from the locking recess 101 by the elastic restoring force of the locking body 24. Evacuate (back to the initial position) within 25 to release the locking of the memory card MC.

In addition, since the groove 25 is located above the fitting protrusion 39, the locking body 24 disposed in the groove 25 engages with the upper portion of the locking recess 101 and the fitting protrusion is provided. 39 is engaged with the lower portion of the locking recess 101.

In assembling the memory card socket, first, each contact 10... Is pressed into a press-fitting hole which is opened in the back of the base body 7 of the contact block 4, and the common terminal board 30 and the movable terminal are pressed. The contact block 4 is assembled by press-fitting the contact plate (switch piece) 31 and the movable contact plate 32 into the press-fit groove 33 of the base body 7 from above. Thereafter, the base body 7 of the contact block 4 is placed on the base shell 1, and the press-fitting groove for opening the protruding piece 9 of the base shell 1 to the lower surface of the base body 7 ( 8), the basic body 7 is fixed to the base shell 1 (see Fig. 6 (b)). At this time, the front end portion of the arm portion 7b of the base body 7 engages with the engaging piece 1a of the base shell 1 to regulate the positional shift of the front end portion of the arm portion 7b.

Next, the other end side of the coil spring 14 is inserted into the microgroove 26 while the one end side of the coil spring 14 is inserted into and supported by the spring bearing 7c of the basic body 7. The slider 5 is placed on the base shell 1 by fitting the protrusion 13 of the base shell 1 into the groove 27. Then, the shaft portion 16b on one end side of the cam pin 16 is engaged with the engagement hole 12a formed in the support piece 12 of the base shell, and the shaft portion 16a on the other end side of the cam pin 16 is coupled. It is coupled in the heart cam groove 15 of the slider (5). Thereafter, in the state where the fitting projection 7e of the basic body 7 is fitted into the fitting hole 2b of the cover shell 2, between the tip portions of both side pieces 6a and 6b of the base shell 1. The cover shell 2 is mounted on the cover shell 2 so that the base shell 1 and the cover shell 2 are joined to each other (the left and right edges of the cover shell 2 and the two side pieces 6a and 6b of the base shell 1). Abutment with the tip) is joined by laser welding. As a result, a box-shaped socket main body 3 having a card insertion opening 3a formed on its front surface is completed, and the assembling of the memory card socket is completed (see Figs. 1 (a) and 3 (a)).

Here, when assembling the cover shell 3, the slider 5 is urged by the coil spring 14 to be pushed forward (toward the card insertion hole 3a side) and moved to the arm 5a of the slider 5. The front end portion abuts against the support piece 12 of the base shell 1, and further movement of the slider 5 forward is restricted. In that state, since the elongate part 29 provided in the slider 5 is arrange | positioned in the position away from the locking body 24 provided in the cover shell 2, the cover shell 2 is tensioned with the locking body 24. There is no need to assemble the structure, and the workability of the assembling work of the locking body 24, that is, the cover shell 3 is improved. In this state, one end of the cam pin 16 is moved to the rear end position A of the guide groove 15b (see Fig. 10 (a)).

Moreover, the narrow protrusion 12b which protrudes toward the side protrudes and is formed in the upper surface of the support piece 12 formed by bending from the front edge of the base shell 1, The cover shell 2 is formed in this protrusion 12b. ), The down stair step of the welding piece 2a (see Fig. 1 (b)) is joined by laser welding. Thereby, since the support piece 12 is connected to the cover shell 2, the strength of the support piece 12 can be raised. Therefore, when the shaft part 16a of the cam pin 16 moves in the heart cam groove part 15 with the movement of the slider 5 to the front-back direction, the operation | movement of the shaft part 16a can be stabilized, As a result, The forward and backward operation of the slider 5, that is, the insertion / removal operation of the memory card MC, is stabilized, so that the number of times of internal / interval insertion of the memory card MC can be improved. In addition, as shown to Fig.12 (a) and (b), the axial part 16b of the one end side of the cam pin 16 is supported by the pressing piece 22 which cut | disconnected and formed a part of the cover shell 2, and was formed. Since it pushes to the piece 12 side, the shaft part 16b of the one end side of the cam pin 16 can be prevented from falling out from the shaft hole 12a formed in the support piece 12. As shown in FIG.

In the assembled state of the socket for the memory card, the slider 5 is urged by the coil spring 14 to be pushed forward (toward the card insertion opening 3a), and the front end of the arm portion 5a is moved to the base shell 1. By contacting the support piece 12 of, the slider 5 is restricted so that it cannot move further forward. In this state, one end of the cam pin 16 moves to the rear end position A of the guide groove 15b (see Fig. 10 (a)).

Here, in the left-right direction (width direction), between the support piece 12 of the base shell 1 and the arm portion 7b of the basic body 7 of the contact block 4 corresponds to the card insertion hole 3a. The dimension between the step portion 5d of the arm portion 5a of the slider 5 and the inner edge of the upper side of the step portion 7d of the arm portion 7b of the basic body 7 of the contact block 4 is a memory. It is set slightly larger than the maximum width dimension on both sides of the card MC. Further, the back surface (the surface on which the I / O contact surface is formed) of the memory card MC is opposed to the top surface of the bottom plate 1c of the base shell 1, so that the memory card MC is removed from the card insertion opening 3a. Assuming insertion, between the step 5d of the arm 5a of the slider 5 and the inner edge of the lower side of the step 7d of the arm 7b of the basic body 7 of the contact block 4. The dimension of is lower than both of the down staircase portions 103 (see Figs. 1A, 4 and 5) formed over the entire length in the front-rear direction along both side edges of the back surface of the memory card MC. It is set slightly larger than the width dimension. In addition, in the up-down direction (thickness direction), the height dimension between the upper surface of the bottom plate 1c of the base shell 1 and the upper surface of these step portions 5d and 7d is a downward stepped portion of the memory card MC. It is set to the dimension slightly smaller than the downward height dimension of (103).

By such a configuration, the down staircase 103 of the memory card MC is moved by the slider 5 while the rear surface side of the memory card MC faces the upper surface side of the bottom plate 1c of the base shell 1. Can pass through the step portion 5d of the arm portion 5a of the arm portion 5a and the step portion 7d of the arm portion 7b of the base body 7 of the contact block 4, and the card insertion opening 3a. The memory card MC from can be inserted. On the contrary, when the surface of the memory card MC (the surface opposite to the surface on which the I / O contact surface is formed) is directed toward the upper surface of the bottom plate 1c of the base shell 1, the maximum width portion of the memory card MC ( The lower part passes between the step portion 5d of the arm portion 5a of the slider 5 and the inner edge of the step portion 7d of the arm portion 7b of the basic body 7 of the contact block 4. In this case, misinsertion by mistake between the front and back directions of the memory card MC can be prevented.

As shown in Fig. 7 (b), the contact 10b (see Fig. 9 (a)) on the right end of the contact block 4 is also located on the bottom plate 1c of the base shell 1. The stopper piece 11a is formed in the inner edge of the front side (card insertion opening 3a side) of the right end hole 11b formed by cutting. When the memory card MC is inserted into the card insertion opening 3a with the front-back direction as a normal direction, a groove provided on the rear surface of the memory card MC to attract each contact 10 to the I / O contact surface ( (Not shown), the respective contacts 10 can be moved to the contact position relative to the memory card MC. On the other hand, when the memory card MC is inserted with the front and rear directions reversed, the front part in the insertion direction of the memory card MC collides with the stopper piece 11a, and the memory card (more than The movement of the MC is regulated. As a result, deformation of the front portion of each contact 10 can be prevented by contacting the front surface of the insertion side of the memory card MC without hitting the front surface of the insertion side of the memory card MC. have.

Next, an operation of inserting and inserting the memory card MC into the memory card socket according to the present embodiment will be described. In the state where the memory card MC is not attached, the front end of the arm portion 5a of the slider 5 is in contact with the support piece 12 of the base shell 1 by receiving the elastic repulsive force of the coil spring 14. To the position, the slider 5 is moved forward. In this state, the engaging piece 24b of the locking body 24 is retracted in the groove 25, so that the distal end portion of the engaging piece 24b does not protrude inward from the inner surface of the arm portion 5a.

From this state, the memory card MC is inserted into the card insertion opening 3a of the socket body 3 with the front and back and front and back directions of the memory card MC being the normal direction, so that the memory card MC is the arm portion 5a of the slider 5. Enters between the arm portion 7b of the basic body 7 of the contact block 4, and the down staircase portions 103 on both sides of the lower surface of the memory card MC are arm portions 5a of the slider 5; And a step portion 5d formed on the arm portion 7b of the basic body 7 of the contact block 4 and the upper portion of the step portion 7d. When the memory card MC is further inserted into the socket body 3, the inclined cutting portion 102 formed on the right side of the front end portion of the memory card MC abuts against the contact portion 5c of the slider 5, so that the slider ( Push back 5) (see FIG. 13 (a)). In this state, no load is applied to the cam pin 16.

When the memory card MC is further pushed inward against the elastic repulsion force of the coil spring 14 applied to the slider 5, the slider 5 retreats as the memory card MC moves. By the retreat of the slider 5, the axial part 16a of the cam pin 16 is guided by the uneven surface 15c of the bottom part of the guide groove l5b of the heart cam groove part 15, and guide grooves. (B) and move to the position B in Fig. 10 (a) (actually, the slider 5 is moved backwards, while swinging the shaft portion 16a of the cam pin 16 in the width direction, The guide groove 15b moves backwards). When the memory card MC is pushed to a position close to the position where the rear surface of the protrusion 5b of the slider 5 touches the front surface of the base 7a of the basic body 7 of the contact block 4, the cam pin ( The shaft portion 16a of 16 reaches the position C that reaches the front end portion of the guide groove l5b, and the memory card MC cannot be pushed further. At this time, the extension part 29 formed in the inner end surface of the groove 25 of the arm part 5a of the slider 5 is the locking body 24 of the cover shell 2 as the slider 5 moves backward. In contact with the lever piece 24a of the lock piece 24a, the lever piece 24a is bent in the inward direction of the socket body 3, so that the engaging piece 24b of the locking piece 24 is the arm portion 5a of the slider 5. It protrudes inward from the inner side of the inner side and engages with the locking recess 101 of the memory card MC. As a result, the memory card MC is locked to prevent the memory card from falling off.

When the push force applied to the memory card MC is released at the position, the slider 5 is returned to the front side together with the memory card MC by receiving the elastic repulsive force of the coil spring 14. At that time, the shaft portion 16a of the cam pin 16 is guided to the guide groove 15b and moves to the position D to be fitted into the recessed portion 15d of the heart cam 15a. Thus, the shaft 16a of the cam pin 16 abuts against the recess 15d of the heart cam 15a, whereby further movement of the slider 5 is restricted, and the memory locked by the locking body 24 is locked. The card MC also stays in the socket body 3 at that position (see Fig. 13 (b)). At this time, the spring load of the coil spring 14 is hung on the support piece 12 via the cam pin 16, but as described above, the welding piece 2a having the support piece 12 installed on the cover shell 2 and Since the support piece 12 is reinforced by welding, the support piece 12 does not deform | transform even if the spring load of the coil spring 14 is applied, and the cam pin 16 can be operated stably.

When the memory card MC is moved to a predetermined position by pushing, the front portion of each contact 10... Projecting forward from the base 7a of the basic body 7 of the contact block 4 is located in the memory card. The respective I / O contact surfaces formed on the rear surface of the MC are sequentially contacted. In addition, a movable contact plate (switch piece) 31 protruding inward from the inner surface of the arm portion 7b of the basic body 7 of the contact block 4 is pushed by the distal end of the memory card MC, and is common. In contact with the terminal plate 30, the movable contact plate (switch piece) 31 and the common terminal plate 30 (that is, a contact for detecting detection) are conductive. By using this switch signal, it is possible to detect that the memory card MC is inserted into the normal position by an external detection circuit (not shown).

In addition, one side of the memory card MC corresponding to the movable contact plate (switch piece) 32 is provided with a recess 105 exposed by the handle 104 of the write-protect switch 100, so that the recess Depending on the position of the handle 104 in the portion 105, the front portion of the movable contact plate (switch piece) 32 may rise on the handle 104 or fall into the recess 105. As a result, since the movable contact plate (switch piece) 32 and the common terminal plate 30 (that is, the position detection contact of the write-protect switch 100) are turned on or off, external detection is performed using this switch signal. The circuit (not shown) can detect whether or not the memory card MC is in the write-protect state.

In addition, in this embodiment, as shown in FIG. 20, the convex fixed contact 41a and the fixed contact 41b formed in the fixed contact plate 41 and the fixed contact plate 42, and the contact spring part ( 31 b) and the notch 31c and the notch 32c formed in the contact spring part 32b are two-point contact, and contact stability can be improved. In addition, since the portion where the notch 31c and the notch 32c are formed in the contact spring portion 31b and the contact spring portion 32b is inclined at an angle with respect to the card insertion direction, the pin notch 31c at the time of card insertion. ) And the amount of displacement of the portion where the notch 32c is formed can be increased, and the wiping effect can be enhanced. In addition, in the standard of the memory card (MC), the dimensional tolerance in the width direction is smaller with respect to the dimensional tolerance in the thickness direction, and the contact spring portion 31b and the contact of the movable contact plate 31 and the movable contact plate 32 are in contact with each other. Since the spring portion 32b is in contact with the card surface or the write protection switch from the width direction of the memory card MC, the contact stability is greater than the case where the spring portion 32b is in contact with the card surface or the write protection switch from the thickness direction having a large size difference. Can improve.

To remove the memory card MC from the socket, first, the rear portion of the memory card MC exposed to the outside from the card insertion opening 3a of the socket body 3 is pushed in the insertion direction, and the slider (with the memory card MC) Move 5) in the insertion direction. By this movement, the shaft portion 16a of the cam pin 16 is separated from the recessed portion 15d of the heart cam 15a, guided to the guide groove 15b, and comes out to the right front than the recessed portion 15d, It moves to the position E in the guide groove 15b.

After that, when the pushing force of the memory card MC is released, the slider 5 moves forward by the elastic repulsive force of the coil spring 14. When the slider 5 is moved forward, the shaft portion 16a of the cam pin 16 is guided to the guide groove 15b in accordance with the movement of the slider 5, and the inside of the guide groove l5b on the right side of the heart cam 15a is moved. Through the position F, it moves to the rear-end position A of the guide groove 15b.

In addition, since the elongated portion 29 of the slider 5 moves away from the lever piece 24a of the locking body 24 of the cover shell 2 as the slider 5 moves forward. There is no force to bend 24a, and the lever piece 24a returns to the initial position, and the tip of the engaging piece 24b retracts into the groove 25 of the arm part 5a. Therefore, the engaging state of the engaging piece 24b and the locking recess 101 is released, and the locking of the memory card MC is released. Since the rear part of the memory card MC is largely exposed to the outside from the card insertion opening 3a of the socket body 3, the memory card MC can be taken out of the socket body 3.

Here, the heart cam groove portion 15 and the cam pin 16 lock the slider 5 at a predetermined position when releasing the pushing force of the memory card MC after moving to the rearmost position of the slider 5, The locking device constitutes a slider locking means for releasing the locking when the slider 5 is moved back by applying a pushing force to the memory card MC after the locking.

When the memory card MC is removed, the locked state of the slider 5 is released, and the slider 5 moves forward by the spring force of the coil spring 14, and together with the slider 5, the memory card ( The MC moves forward. At that time, the fitting projection 39 and the fitting projection 40 formed on the side and bottom of the step 5d of the slider 5 are fitted in the locking recess 101 of the memory card MC. Even when the locking of the memory card MC by the locking body 24 is released, the edge of the locking recess 101 abuts against the fitting protrusion 39 and the fitting protrusion 40, It is possible to prevent the memory card MC from popping out. Further, since the curved surface 39a and the curved surface 40a are formed in each of the fitting protrusion 39 and the fitting portions 40 in the insertion direction of the memory card MC, the memory card ( At the time of insertion and removal of the MC, the movement when the locking concave portion 101 passes over the fitting protrusion 39 and the fitting protrusion 40 can be smoothed, and the operation feeling can be improved.

As described above, the dimension tolerance of the memory card MC in the width direction (the direction perpendicular to the card insertion direction and the thickness direction) reduces the positional deviation of the I / O contact surface, thereby ensuring electrical connection. As a result, the fitting projection 39 formed in the slider 5 is fitted into the locking recess 101 from the side having a small dimensional tolerance. Therefore, by fitting the fitting projection 39 and the locking recess 101 to each other, it is possible to reliably prevent the jumping out. Moreover, since the fitting projection 39 fitted from the side with respect to the locking recessed part 101 is fitted with the lower part in the thickness direction of the locking recessed part 101, it is for locking in the whole thickness direction. As compared with the case where the recess 101 is fitted with the recess 101, the resistance generated by the locking recess 101 and the fitting protrusion 39 can be reduced. As a result, the resistance at the time of taking out the memory card MC can be prevented from becoming too large.

In addition, in this embodiment, in addition to the fitting projection 39 fitted to the locking recess 101 from the side, the fitting projection 40 fitted to the locking recess 101 from the thickness direction is provided. Since both of the fitting protrusion 39 and the fitting protrusion 40 are fitted with the locking recess 101, it is possible to prevent the memory card MC from protruding more reliably. In addition, since only the fitting protrusion 39 which fits into the locking recess 101 in the width direction from which the dimensional tolerance is tight may be formed, since the gap of the dimensional accuracy in the width direction of the memory card MC is small, The gap during the engagement of the fitting protrusion 39 and the locking recess 101 can be made small, so that the effect of preventing the memory card MC from protruding even if only the fitting protrusion 39 is obtained can be sufficiently obtained.

In the memory card socket of the present embodiment, only one base shell 1 of the upper and lower metal shells (base shell 1 and cover shell 2) is press-fitted to the base body 7 of the contact block 4. The other cover shell 2 is bonded to the base shell 1 by laser welding. Therefore, as in the conventional example in which the cover shell 2 is press-fitted to the base body 7 to which the base shell 1 is press-fitted, the force for pressing the cover shell 2 into the base body 7 is applied to the base shell 7. Since it is not added to 1), deformation of the base shell 1 can be prevented. In addition, since the cover shell 2 is not press-fitted to the basic body 7 of the contact block 4, the torsional force generated by the positional displacement of the press-fitting place as in the case of press-fitting is applied to the cover shell 2. Since it is not applied, the deformation of the cover shell 2 can be prevented. As a result, deformation of the socket body 3 can be suppressed, and the flatness of the socket body 3 can be improved.

In addition, although the cover shell 2 is not directly fixed to the base body 7 of the contact block 4, the bending piece 19 provided in the rear end of the cover shell 2 is the back side of the base body 7 The engaging concave portion 17 provided on the front side of the base body 7 has a protruding piece 20 provided on the front side of the base body 7 while abutting against the joining concave portion 18 formed at the rear side. We are facing from the front. Therefore, when the memory card MC is pulled out, when a force pushing the basic body 7 forward by the friction force generated between the I / O contact surface of the memory card MC and the contact 10 occurs, the contact is made. Since the force pushing the upper part of the basic body 7 of the block 4 forward is received by the protruding pieces 20 of the cover shell 2, the fall of the basic body 7 to the front can be suppressed. Further, even when the memory card MC is inserted, the force pushing the basic body 7 of the contact block 4 backward by the frictional force generated between the I / O contact surface of the memory card MC and the contact 10 is prevented. Although generated, the bending force of the cover shell 2 is received by the force pushing the upper portion of the base body 7 backward, so that the fall of the base body 7 to the rear can be suppressed. In addition, since the cover shell 2 is welded to the base shell 1 only by the left and right sides thereof, the strength of the center portion is weakened, but the bending piece 19 protruding downward to the rear edge of the cover shell 2 is provided. Since the bending piece 19 is bent, the strength of the cover shell 2 can be increased by the bending piece 19.

In addition, in this embodiment, since the joining part of the metal base shell 1 and the cover shell 2 is bonded by laser welding, the base shell 1 and the cover shell 2 can be made to be completely the same electric potential. Since the base shell 1 is grounded, the entire socket body 3 is firmly grounded, so that it is resistant to static electricity and external noise, thereby improving EMI performance.

In the present embodiment, the base shell 7 is press-fitted and fixed to the base shell 1, and the cover shell 2 is bonded to the base shell 1 by laser welding. One of the two metal shells disposed on the front and rear surfaces of the MC, respectively, may be press-fitted and fixed to the base body 7 of the contact block 4, and the other may be bonded to one of the metal shells by laser welding. The cover shell 2 and the base shell 1 may be joined to each other by press-fitting the base body 7 by laser welding.

In addition, the memory card socket of the present embodiment has a corner of each contact 10..., A common terminal board 30, a movable contact plate (switch piece) 31, and a movable contact plate 32. The stepped portions of the soldering terminals 10a, 30a, 31a and 32a and the mounting protrusions 6c protruding upward from the upper edges of both side pieces 6a and 6b of the base shell 1 are covered by the cover shell 2. It is a stand-off type socket which protrudes upward from the top surface of the top surface, and the surface is mounted on the mounting board while floating from the substrate surface, whereby the component mounting can be performed on the lower side of the socket body 3. However, the present invention is not limited to this configuration, and needless to say, the terminal structure may be in another form.

In this embodiment, the SD memory card (registered trademark) has been described as an example of the memory card. However, the size of the portion inserted into the socket is the same as that of the SD memory card (registered trademark). With a terminal arrangement similar to that of a registered trademark, a SDIO card equipped with a functional unit such as an I / O interface, a PHS module, or a GPS module can be mounted and used. That is, the memory card socket of the present embodiment can be applied to an SD card socket corresponding to both a SD memory card (registered trademark) and a SD card.

Fig. 1A is a perspective view showing the external configuration of a memory card socket and a memory card according to an embodiment of the present invention, and Fig. 1B is an enlarged perspective view of the main portion thereof.

Fig. 2 is an exploded perspective view showing the configuration of the memory card socket according to the present embodiment.

3 is an exploded perspective view of the memory card socket of the present embodiment as seen from the side opposite to FIG.

4A to 4E are a front view, a right side view, a left side view, a top view, and a bottom view respectively showing a state in which a memory card is mounted in the memory card socket of the present embodiment.

Fig. 5 is a rear view showing a state where a memory card is mounted in the memory card socket of the present embodiment.

Fig. 6A is an external perspective view seen from the right side of the memory card socket of the present embodiment, and Fig. 6B is an external perspective view seen from the back side of the memory card socket of the present embodiment.

Fig. 7 (a) is a plan view showing a base shell constituting the memory card socket of the present embodiment, and Fig. 7 (b) is a perspective view thereof.

Fig. 8 (a) is a perspective view seen from the front side showing the cover shell constituting the memory card socket of the present embodiment, and Fig. 8 (b) is a perspective view seen from the back side thereof.

9 (a) to 9 (c) are perspective views seen from the front side, and perspective and rear views respectively seen from the front side showing the contact block constituting the socket for the memory card of the present embodiment described above.

10A to 10D are respectively a front view, a side view, a back view, and a perspective view showing a slider constituting the memory card socket of the present embodiment.

11 (a) and 11 (b) are cross-sectional perspective views showing the welded portions of the base shell (first metal shell) and cover shell (second metal shell) in the memory card socket according to the present embodiment, respectively. to be.

12A and 12B are enlarged perspective views showing the configuration of the bearing portion of the cam pin in the memory card socket according to the present embodiment, respectively.

Fig. 13 (a) is a plan view showing a state in which the cover shell is removed while the memory card is mounted in the memory card socket of the present embodiment, and Fig. 13 (b) shows the state when the memory card is mounted. It is a top view showing.

Fig. 14 is a plan view showing a state in which the cover shell is removed in a state where a memory card is attached to the memory card socket of the present embodiment (omitted memory card).

Fig. 15 is an enlarged perspective view showing the main part of the structure (state in which the cover shell is removed) of the switch piece for memory card mounting detection and write prevention switch detection of the memory card socket according to the present embodiment.

Fig. 16A is an enlarged plan view showing the main part structure shown in Fig. 15, and Fig. 16B is a C-C cross-sectional view thereof.

17A to 17C are respectively a front view, a top view, and a back view showing the configuration of a common terminal board used for the memory card socket of the present embodiment described above.

18A to 18C are a front view, a top view and a back view respectively showing the structure of the movable contact plate used for the memory card socket of the present embodiment.

Fig. 19 is a perspective view showing a state in which the movable contact plate is press-fitted into the basic body in the memory card socket of the present embodiment.

20 is a sectional view showing the principal parts of the contact spring portion of the movable contact plate and the contact state of the stationary contact.

Fig. 21 is a perspective view showing a card locking mechanism (cover shell removed) provided in the slider of the memory card socket of the present embodiment.

Fig. 22 is an enlarged perspective view showing the principal parts of the card locking mechanism (with the cover shell removed) provided in the slider of the memory card socket according to the present embodiment.

Fig. 23 is a plan view showing the structure of the card locking mechanism (with the cover shell removed) in the state where the memory card is mounted in the memory card socket of the present embodiment.

Fig. 24A is a plan view showing a state when the memory card is mounted in the card locking mechanism of the memory card socket of the present embodiment, and Fig. 24B is a plan view showing the state when the memory card is taken out. to be.

[Description of the code]

1 ... base shell (first metal shell)

2.cover shell (second metal shell)

3... Socket body

3a... Card slot

4… Contact block

5... Slider

7... Basic body

10... Contact

15... Heart Cam Groove (Slider Locking Means)

16... Cam pin (slider locking means)

16a, 16b... Shaft

17... Combined recess

18... Combined recess

19... Bending piece (second contact piece)

20... Protruding piece (first contact piece)

24... Locking body (card locking means)

24a... Lever

24b... Joining Piece (Joint Part)

29... Jangbu (press)

30... Common terminal board

31,32... Movable Contact Plate

31a, 32a... Soldering Terminal

31b, 32b... Contact Spring

31c, 32c... ＶNotch

31 d, 32 d. Indent

33,34,35... Press-In Groove

39... Fitting protrusion (first fitting protrusion)

40... Fitting protrusion (2nd fitting protrusion)

101... Locking recess

MC… Memory card

Claims (10)

A box-shaped socket main body having a card insertion slot into which a memory card is inserted in the front surface, A contact block provided inside the socket body for supporting a plurality of contacts in contact with a plurality of I / O contact surfaces provided on one surface of a memory card, A slider which is disposed in the socket body so as to be movable in the front-rear direction, and which moves in the front-rear direction together with the memory card according to the insertion / retraction operation of the memory card from the card insertion hole; A bushing spring which always biases the said slider forward, After moving to the last position of the slider, when the push force of the memory card is released, the slider is locked at a predetermined position, and after the locking, the push force to the memory card is applied to the slider. Slider locking means for releasing the locking when the vehicle moves backwards, When the slider is locked at the predetermined position, the slider is provided with a card locking means for locking the memory card is coupled to the locking recess of the memory card, The card locking means is composed of a locking body having one end supported by the socket main body and an elastic member having a coupling part coupled to the locking recess of the memory card at the other end. The slider has a pressing portion for pressing the locking body toward the memory card when the slider is moved to the predetermined position, In the state where the slider is moved to the predetermined position, the locking member is pressed by the pressing portion of the slider to elastically deform so that the engaging portion enters into the locking recess of the memory card, and when the memory card is not inserted, And the locking body is moved away from the pressing part in the state where the slider is moved forward, so that the engaging portion is retracted from the locking recess by the elastic return force of the locking body. The method of claim 1, The slider locking means, the heart cam groove portion formed on the surface of the slider, one end is supported by the socket body and the other end is coupled to the heart cam groove portion, when the slider moves to the predetermined position, the heart cam groove portion The other end is inserted into a recessed opening provided in the forward direction, and is composed of a cam pin for regulating the movement of the slider forward, From the side formed by folding the front edge of the first metal shell to the rear, an L-shaped support piece is provided with an axial hole for coupling one end side of the cam pin to axially support the cam pin. And a welding piece welded to the support piece in contact with the support piece in the second metal shell. The method of claim 2, And a pressing piece for contacting one end side of the cam pin and biasing one end side of the cam pin to the support piece side by cutting a part of the second metal shell up. The method of claim 1, When the memory card is inserted into the socket body, a metal movable contact plate that is pushed and bent by the memory card, and a fixed contact plate that contacts the movable contact plate when the movable contact plate is bent.接点 板) is further provided, The movable contact plate is in contact with a stationary contact with a press-fitting portion in which both side edges of the width direction are press-fitted into a press-fit groove provided in the base body, and the press-fitting portion as a fixed end. The movable contact which detachably contacts is further provided with the contact spring part provided in the free end side, In the press-fitting part of the movable contact plate, a surface mounting terminal surface-mounted on a mounting board is extended from one side edge in the thickness direction of the socket main body. A memory card socket, characterized in that formed in a shape symmetrical with respect to a central axis in the width direction of a mounting terminal. The method of claim 4, wherein The contact spring portion of the movable contact plate extends from one end side in the width direction of the press-fit portion, and the movable contact is provided on the tip side thereof. The basic body is in contact with the other end portion of the contact spring portion in the width direction of the first contact portion and the first contact portion in contact with the front end side portion of the contact spring portion in the direction of pressing the press-in portion into the basic body. And a second contact portion. The method of claim 5, The first contact portion and the second contact portion, the memory card socket, characterized in that installed in the main body portion other than the portion through which the indentation portion passes when the indentation portion in the indentation groove. The method according to any one of claims 4 to 6, A memory card socket, comprising: providing a protrusion projecting in a thickness direction by cutting a portion of the press-fitting portion, and providing a guide groove into which the protrusion is inserted, in the basic body. The method of claim 1, The card locking means is provided on the side of the slider which is disposed to face the side of the memory card while the front part of the memory card is in contact with the slider, and the memory card is provided in the locking recess of the memory card. A socket for a memory card, characterized in that it comprises a first fitting protrusion fitted from a side of the groove. The method of claim 8, A memory card socket according to claim 1, wherein corner portions of the first fitting protrusion are formed in a curved shape in the insertion direction of the memory card. The method according to claim 8 or 9, The card locking means is provided on the surface of the slider which is arranged to face one surface in the thickness direction of the memory card in a state where the front portion of the memory card is brought into contact with the slider, thereby concave for locking the memory card. And a second fitting protrusion fitted to the portion from the thickness direction of the memory card.

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