KR100999873B1 - Memory card connector - Google Patents

Abstract

In the push-in push-out type connector, the housing itself is hardly deformed even when the board is reflowed.

In the housing 110 covered by the shield cover 120, the slide member 150 is arranged to be slidably movable in the insertion direction and the discharge direction of the card 200 together with the card 200. The slide member 150 is elastically biased in the discharge direction by the coil spring 160. The slide member 150 is connected to the heart cam groove portion 180 of the housing 110 by the locking pin 170, and moved from the discharge position by the card portion 190 of the upper shield cover 120 to the cam groove portion. It is pressed by the cam groove part 180 side during the movement of 180. As shown in FIG. A clearance G is formed between the locking pin 170 and the upper surface portion 121 of the shield cover 120 at the discharge position.

Memory card, electrode, terminal, housing, shield cover, slide member, elastic bias member, cam groove, locking pin, memory card connector

Description

Memory Card Connector {MEMORY CARD CONNECTOR}

The present invention relates to a push-in push-out type memory card connector which is held in a mounting position and is electrically connected to a terminal of the memory card.

A card-type memory as a recording medium for storing image data captured by a mobile phone or digital camera having a conventional camera function, a recording medium for storing music digital data reproduced by a portable music player, or a storage medium for storing created sentence data. The card is known.

The memory card generally accommodates a read-write semiconductor memory (RAM) inside a small resin package formed in a rectangular thin plate shape and has a plurality of electrodes electrically connected to an end portion of one side of the back side of the package. It is done.

Memory cards are formed in dimensions and shapes determined for each type, and electronic devices to which digital cameras, portable music players, notebooks, mobile phones, and the like are mounted are mounted through memory card connectors corresponding to the dimensions and shapes for each type of memory card. .

As a memory card connector (hereinafter referred to as a "connector"), for example, as disclosed in Patent Document 1, a push-in push-out type connector for a memory card having a notch portion formed at one side of the tip side is known.

Generally, the so-called push-in push-out type connector has a locking mechanism for locking the memory card to the insert mounting position when the memory card is inserted, and releasing the lock to eject the memory card from the insert mounting position upon ejection. do.

The locking mechanism is a lock in which one end is engaged with a heart-shaped cam (heart cam) provided in a housing having a memory card accommodating portion, and a slide groove around the heart cam, and the other end is rotatably supported by the slide member. With pins. As the slide member is moved in the insertion direction in accordance with the insertion of the memory card, one end of the locking pin slides the slide groove so that locking and unlocking are performed. In this locking mechanism, when the memory card is moved in the insertion direction, the locking pins sliding in the heart-shaped slide grooves are engaged with the locking recesses provided in the slide grooves so that they are locked in the insertion mounting position. Then, to release the lock, the locking pin is released from the concave groove of the slide groove by pressing the memory card locked in the insertion position once in the insertion direction. Then, the memory card is discharged in the discharge direction by the elastic bias force of the coil spring which elastically biases the slide member in the discharge direction.

In such a locking mechanism, it is necessary to circularly move the locking pin in one direction in the heart-shaped slide groove. Therefore, a plurality of steps are formed on the bottom surface of the slide groove for preventing the return of the locking pin, or the shape of the inner wall surface or the outer wall surface of the slide groove is devised so that the locking pin rotates only in one direction.

In addition, in Patent Document 1, the locking pin is slide-out from the top by a release preventing spring part which cuts a part of the cover 2 downward in a tongue shape so that the locking pin does not escape from the slide groove around the slide groove during movement. It is slidably pressed against the bottom surface of the.

The connector thus constructed is provided with a reflow step (260 ° C peak) which is placed on a substrate by placing a fixing piece provided to extend horizontally on the lower sides of both sides of the cover on a pattern on the substrate and being heated together with the substrate. Then, it is mounted by soldering.

[Patent Document 1] Japanese Unexamined Patent Publication No. 2003-317861

In the connector having the locking mechanism of the conventional configuration, the locking pin is pressed into the slide groove portion of the resin housing by the release preventing spring portion provided as part of the metal cover.

Therefore, in mounting the board, when the connector is mounted on the board and reflowed, pressure is applied from the locking pin in a state where the bottom portion of the resin is softened in the housing. Therefore, after the end of the reflow, the deformation of the state swelled downward by pressing the locking pin remains as it is, and the entire plane of the housing including the slide groove is cured, so that the terminal of the fixing piece disposed on the side of the connector is lifted from the mounting surface. There is a problem that it becomes difficult to perform soldering.

SUMMARY OF THE INVENTION The present invention has been made in view of this point, and an object of the present invention is to provide a push-in push-out type memory card connector which can be preferably mounted because the housing itself is not deformed even when the board is reflowed. do.

The memory card connector of the present invention includes a housing made of resin containing a terminal for connecting a memory card to be inserted and connected to an electrode of the memory card, and the housing in a state in which an insertion port for inserting the card is opened. And a shield cover covering upwards from the upper side, the housing being slidably movable in the inserting direction and the ejecting direction of the memory card, and pressed against the memory card in accordance with the insertion of the memory card into the housing. And a slide member which moves deeply to the mounting position of the inner side, and at the time of ejection, moves to the ejection position of the insertion port side together with the memory card to hold the memory card protruded outward from the insertion port at the ejection position; Elasticity of the slide member in the discharge direction An ear biasing member, a heart-shaped cam groove portion formed in any one of the housing and the slide member, and installed in the other one of the housing and the slide member, are engaged with the cam groove portion, and press operation of the memory card. A locking pin which moves in the cam groove part according to the movement of the slide member to move the slide member to a position for holding and releasing the holding against the elastic biasing force of the elastic biasing member; And a portion of the shield cover is cut down and formed to rise, and presses the locking pin downward, and has a pressing member that prevents the locking pin from being pulled out of the cam groove, and the pressing member is connected to the shield cover. The locking pin is moved from the discharge position during the cam groove It is formed in the position which pushes toward the said cam groove part, and the structure which has the clearance gap formed between the said lock pin in the said discharge position and the said shield cover of upper part is employ | adopted.

According to the present invention, in the push-in push-out type connector, even when reflow is carried out in mounting the board, the housing itself is not deformed well, and thus it can be preferably mounted.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail with reference to drawings.

1 is a perspective external view showing a configuration of a memory card connector according to an embodiment of the present invention. 1 is shown in the state of seeing the upper surface portion of the memory card connector for convenience. The memory card connector shown in Fig. 1 is a push-in push-out connector and has a locking mechanism. In FIG. 1, the coil spring (refer FIG. 2) as an elastic biasing member which elastically biases a slider in the locking mechanism is abbreviate | omitted. In the present embodiment, the front means the card insertion port side on the memory card connector side.

The memory card connector (hereinafter referred to as a "connector") 100 shown in FIG. 1 forms a substantially rectangular flat box shape when viewed in plan, and has a memory card 200 inserted therein from the card insertion hole 102. A receiving portion (card mounting area) 104 is provided.

In the present embodiment, since the memory card (hereinafter also referred to as "card") 200 is formed in the size and shape determined for each type, the memory card connector corresponds to the size and shape of the memory card used. do.

In the present embodiment, the memory card 200 mounted on the connector 100 is cut by one side of the tip portion (the right side with the insertion direction of the connector 100 as the tip side when viewed from the memory card 200). The notch part 210 is formed. Here, the notch portion 210 includes a corner portion at one side (right side) of the front end portion of the rectangular memory card, and is cut out into a quadrangle at one side parallel to the other side and two sides inclined and intersecting the one side. Therefore, the tip portion of the memory card 200 is narrower than the rear end side by the notch portion 210.

In addition, in one side of the memory card 200 (the right side having the insertion direction side at the front end side), a jaw groove 220 is formed in which one side (the right side) is opened at the proximal side than the notch 210. . Accordingly, a protrusion 230 protruding to one side (right side) is formed between the notch 210 and the jaw groove 220 on one side of the memory card 200. The outer surface of the distal end side of the protrusion 230, that is, the proximal end surface forming the notch 210 is an inclined surface 212 that rises from the distal end side of the memory card 200 toward the proximal side. In this case, the memory card 200 has a rectangular plate shape, the outer dimension of which is 11 mm x 5 mm x 1 mm, and the width of the front end side is narrower than the width of 11 mm of the rear end side. Use an SD card (registered trademark).

The connector body of the connector 100 is formed by punching a plate-shaped conductive material (here, a metal plate) into a rectangular housing 110 when viewed in a plane formed of an insulating material (here, an insulating synthetic resin material), It is comprised by covering the shield cover 120 formed by bending in an L shape. In addition, in FIG. 1, the part bent from the both side parts of the upper surface part 121 of the shield cover 120 is shown as the side plate parts 123 and 124. As shown in FIG.

2 is a plan view of a housing in a state where the shield cover 120 is removed in the memory card connector according to an embodiment of the present invention, FIG. 3 is a bottom view of the housing shown in FIG. 2, and FIG. 4 is shown in FIG. 2. Right side view of one housing.

The housing 110 shown in FIGS. 2 to 4 has a card insertion opening in the bottom plate portion (plate-shaped body portion) 112 and the bottom plate portion 112 having a substantially rectangular shape when viewed from a plane in which the contacts 130 are arranged. It is set up from the front side part 112a used as the edge of opening 102, and the both side parts adjacent to each other, and has the guide side wall part 113 and the side wall part 114 which mutually oppose each other. Further, in the bottom plate portion 112, rear end wall portions 115a and 115b which are set up from the rear end portion opposite to the card insertion port 102 are arranged in an arrangement.

The bottom plate portion 112 holds a contact 130 (cantilever contact or the like) that is in electrical contact with the electrode of the card 200 to accommodate. Specifically, a plurality of contacts 130 are protruded while being inclined upward from the portion near the rear end side (deep inside) to the rear side (deep inside) from the substantially center of the bottom plate portion 112.

In detail, the contact 130 is formed here as a leaf spring contact, and is integrally formed in the housing 110 by insert molding with the electrically-conductive member which functions as another wiring etc. which are hold | maintained in the housing 110, and the like. The contact 130 is formed as a part of the insert which is formed by punching a conductive metal plate.

The contact 130 is disposed to protrude rearward from the upper surface of the bottom plate portion 112 along the insertion direction of the card 200 to be inserted, and has a lever portion 134 whose tip is a contact portion 132.

The lever portion 134 has a predetermined distance to the bottom plate portion 112 from the front end wall portion 115 side of the housing 110 to the bottom plate portion 112 in the direction perpendicular to the insertion direction of the card 200. Arranged in a state in which plural pieces are arranged. As a result, in the contact 130, the tip portion, which is the contact portion 132, is arranged in a state facing the card insertion port 102. As shown in FIG.

In this case, the contact 130 is formed by processing a long strip-shaped metal plate into a V or U shape when viewed in plan view. The lever part 134 is surfaced with respect to the fixing piece 136 by making the one side part bent at the bending part of this metal plate as the lever part 134, and the other side part being the fixing piece 136 arrange | positioned at the bottom plate part 112. It is formed by bending to the side.

The lever part 134 and the part parallel to the lever part 134 and the width direction (left-right direction) of the fixing piece 136 are arrange | positioned at the site | part opened in the bottom plate part 112, and the fixed piece 136 of the The proximal end portion and the distal end portion (folded portion of the contact 130) are fixed to the bottom plate portion 112 of the housing 110.

The fixing piece 136 is held along the bottom surface in the bottom plate portion 112, and one end portion extending rearward (deeply inwardly) protrudes outward (backward) from the rear end surface of the rear end wall portion 115, and this protrusion This part is the lead portion 138 soldered to the mounting substrate.

In addition, the bottom plate part 112 is arranged in one side of the housing part 104, and is provided with a locking mechanism part 140 including a slider 150 which is movable along the sidewall part 114 along the insertion direction. It is. Between the locking mechanism portion 140 and the guide side wall portion 113 is opposed to one side of the front end portion of the memory card 200 (specifically, a surface extending in the insertion direction defining the notch portion 210); In addition, the guide small wall part 116 which regulates the movement to the depth inside of the slider 150 is provided. In addition, the guide small wall portion 116 is inserted into the heart cam groove portion 180 of the locking mechanism portion 140 when the tip portion of the card 200 is inserted into the receiving portion 104 when the card 200 (see FIG. 1) is inserted. Regulate what happens.

In these bottom plate portions 112, the locking mechanism portion 140, the portion facing the guide side wall portion 113 and the guide small wall portion 116, together with the guide side wall portion 113, are open toward the upper surface side of the housing 110. A mold is formed and both side portions and bottom plate portions of the housing portion 104 are defined.

In the guide side wall portion 113, a reinforcing plate 139 made of metal is arranged along the inner wall surface in a portion (hereinafter referred to as an "insertion side" portion) 113a on the card insertion port 102 side. Thereby, the opening edge part of the guide side wall part 113 is reinforced.

The rear end wall 115 is disposed close to the distal end of the card 200 accommodated in the accommodating portion 104 by insertion, and moves in the insertion direction of the card 200 inserted into the accommodating portion 104. Regulate.

The locking mechanism part 140 is arrange | positioned along the insertion / removing direction to the side of the area | region which becomes the accommodating part 104 (here, the side wall part 114 side with respect to the accommodating part 104). The locking mechanism 140 includes a slider 150, a coil spring 160, a locking pin 170, having a protruding portion 156 engaged with the notch 210 of the card tip portion to be inserted. It has a heart cam groove 180.

The slider 150 is disposed on the bottom plate portion 112 so as to be movable along the insertion direction of the card 200 on one side of the housing portion 104, and is provided by the coil spring (elastic bias member) 160. The card 200 is elastically biased toward the half insertion direction (extraction direction). Here, the slider 150 is guided by the slit 117 formed in the bottom plate part 112, and is movable in the insertion / removal direction.

The slider 150 moves the locking jaw portion 155 at the tip side of the memory card 200 to the locking jaw portion 155 at the distal end thereof at the position (card insertion opening side position) of the connector main body when moved to the card insertion opening 102 side. (See Fig. 1), the card 200 is inserted / removable with respect to the connector body. This holding state is called half lock, and the position (card insertion port side position) at the time of moving to the card insertion port 102 side in the connector main body is also called a half lock position.

The slider 150 is formed by a slider main body 152 having a protruding portion 156 protruding toward the receiving portion 104 side, and protruding from the front end side (front side) of the slider main body 152, and having a card (at the front end). It has a neck portion 153 is provided with a locking jaw portion 155 to enter and exit the jaw groove 220 of the side of the 200.

In the protruding part 156 of the slider main body 152, the side surface 156a of the accommodating part 104 side is the accommodating part 104 side, ie, the guide side wall toward the proximal end side from the front end part which is continuous with the neck part 153. The inclined surface protrudes toward the side 113 and is inclined.

The inclination of this side surface (also called inclined surface) 156a forms the protruding portion 156 in the slide main body 152, and is an inclined surface intersecting with the insertion direction. This inclined surface 156a corresponds to the inclination of the proximal end surface (inclined surface 212) that forms the notch portion 210 of the card 200.

Slider body 152 is protruding when the locking jaw portion 155 is caught in the jaw catching groove 220 of the card 200 is correctly inserted into the notch portion 210 and interlocked with each other of the card 200 It is located on the side of the tip (right side when the insertion direction is called forward). Furthermore, the card 200 is inserted into the receiving portion 104 so that the protruding portion 156 is pressed by the card 200 in the insertion direction. Accordingly, by simply inserting the memory card 200 deeply into the accommodation portion 104, the slider 150 itself is also followed to move deeply into the accommodation portion 104 so that the card 200 is moved into the accommodation portion ( It is moved to the card loading position that is fully received at 104.

In addition, the locking jaw portion 155 is formed to protrude toward the guide sidewall portion 113 in a triangular shape when viewed in plan from the distal end of the neck portion 153. The locking jaw portion 155 faces the inner end of the neck portion 155b on the rear end side (deep inside) so as to securely engage the rectangular jaw groove 220 of the card 200 toward the rear end side (deep inside). Hasty gradient is formed. In addition, a gentle gradient is formed on the front surface 155a of the locking jaw portion 155 to facilitate entry and exit of the jaw locking groove 220.

As shown in FIG. 3, the lower surface of the slider 150 (the lower surface of the slider body 152) protrudes downward to form a guide protrusion 151, and the guide protrusion 151 is attached to the bottom plate portion 112. It is loosely fitted to the formed slit 117 to be movable.

The guide protrusion 151 forms a protrusion extending in the insertion direction (front and rear direction) longer in the front-rear direction than the length in the width direction on the lower surface of the slider body 152, and the slit extending in the front-rear direction in the housing 110. 117 moves while guided inside the slit 117.

As shown in FIG. 3, the slit 117 on which the guide protrusion 151 is loosely fitted extends in the front-rear direction of the housing 110 to the bottom plate 112, and at the end of the card insertion port 102 side, the receiving portion. It is formed to extend to the opposite side to the 104 side.

Here, in the slit 117, the distal end portion 117a on the card insertion port side is formed in a fan shape extending toward the side, and the guide projection portion 151 is located at this distal end portion (hereinafter also referred to as a fan shape portion) 117a. In this case, the guide protrusion 151 is capable of swinging around the proximal end side. When the guide protrusion 151 is located in this sector 117a, the slider 150 itself is located in the card insertion opening side position.

The locking jaw portion 155 is arranged to swing in the separation direction with respect to the receiving portion 104 side when the slider 150 is located at the half lock position (insertion side side position shown in FIG. 1) on the bottom plate portion 112. It is. Accordingly, in the half lock position, the slider 150 is guided by the slit 117 formed in the bottom plate portion 112 so as to be movable in the insertion / removal direction. That is, the slider 150 is arranged so as to be able to swing horizontally around the proximal end at the position (card insertion port side position) at the time of moving to the card insertion port 102 side in the connector body, and the locking jaw portion at the front end side ( The 155 can be held in a half lock so as to be hooked or peeled off from the jaws 220 (see FIG. 1) of the memory card 200.

Further, when the guide protrusion 151 moves deeply into the slit 117, the guide protrusion 151 moves linearly along the long hole portion 117b. At the end of the deep hole portion 117b, the guide protrusion 151 moves to the proximal side. Movement is regulated. By this configuration, the slider 150 is restricted in the moving range of the insertion / removal direction in the housing 110.

In addition, as shown in FIG. 2, the spring support protrusion 157 protrudes backward from the base end surface of the slider main body 152 opposite to the rear end wall 115.

An end portion of the coil spring 160, which is a compression coil spring, is provided on the spring support protrusion 157 and a protruding portion 115g protruding forward from the rear end wall portion 115b so as to face the spring support protrusion 157. Each one is externally fitted.

As a result, the coil spring 160 is arranged along the insertion direction between the slider 150 and the rear end wall portion 115b. By this coil spring 160, the slider 150 is always elastically biased forward (card insertion port side) together with the connected locking pin 170, and the locking jaw portion 155 at the position of the insertion port side, which is the front end end position. ) Is disposed to protrude into the receiving portion 104.

FIG. 5 is a partial longitudinal cross-sectional view showing the locking pin when the slide is located at the half lock position in the connector shown in FIG.

As shown in FIG. 2 and FIG. 5, the pin holding part 158 which cuts the upper surface of the protruding end part 156b to the proximal end (deep inside of a connector) in the protruding part 156 of the slider main body 152. As shown in FIG. ) Is formed.

The pin holding portion 158 has a bearing hole portion that opens upward from the cut upper surface. By bending both ends of the round rod at right angles to the bearing hole, the bent shaft as the other end (tip) 174 of the U-shaped locking pin 170 is rotatably inserted, and the locking pin from the pin holding portion 158 is rotated. 170 extends itself in the insertion direction.

The base end (one end) 172 of the locking pin 170 is loosely fitted to the heart cam groove 180 in a state where the tip of the base end 172 is brought into contact with the bottom surface of the heart cam groove 180.

Specifically, the bent shaft portion constituting one end (base end) 172 of the lock pin 170 is inserted into the heart cam groove portion 180, the lock pin 170 is driven by the heart cam groove portion 180 There is a clause. Accordingly, the slider 150 changes relative to the trajectory of the movement of the locking pin 170 moving along the heart cam groove 180.

The locking pin 170 is disposed between the bottom plate portion 112 of the housing 110 and the upper surface 121 of the shield cover 120 covering the housing 110 together with the slider 150, and moves in a horizontal direction. It is possible.

In addition, when the locking pin 170 slides on the bottom surface of the heart cam groove 180, the heart cam is formed by a pin pressing portion (hereinafter referred to as a “card portion”) 190 of the upper shield cover 120. Although it is press-contacted to the bottom surface side of the groove part 180, when the slider 150 is in the half lock position which is a state position, ie, the position of the card insertion opening 102 side, it is a structure which is not pressed downward.

In a state where the memory card 200 shown in FIG. 5 is not mounted on the connector 100, an end portion 172 of the locking pin 170 is formed between the locking pin 170 and the upper surface 121. Clearance G is formed so that it does not protrude from the cam groove part 180. FIG.

Here, the upper end of the locking pin 170, the base end 191a of the card portion 190 for pressing the locking pin 170 downward when the heart cam groove portion 180 is moved through a clearance G at a predetermined interval. It is arranged. In addition, the card unit 190 is to press the locking pin 170 moved from the half lock position downward, specific details will be described later.

Here, the heart cam groove unit 180 will be described.

6 is an enlarged view of a heart cam groove. The heart cam groove part 180 shown in FIG. 6 is formed along the circumference | surroundings of a heart-shaped cam, and is arranged in the bottom plate part 112 of the housing | casing 110 in deep inside of one side part. On the bottom surface of the heart cam groove 180, a plurality of stepped slopes and stepped portions are provided to guide the base end portion 172 of the locking pin 170 in which the tip portion 174 is pivotally connected to the slider 150 in a predetermined direction. 182a to 182f are formed.

The height relationship between the slopes 182a to 182f until the base end 172 of the locking pin 170 starts from the half lock position and returns to the half lock position is formed as shown in FIG. Fig. 7 is a diagram showing the height relationship in the vertical direction of the memory card connector between the stepped slope and the stepped portion in the heart cam groove portion.

Here, the slopes and the stepped portions 182a to 182f are formed so that the other end of the locking pin 170 abuts against the reverse trajectory.

6 and 7, the bottom surface 182a serving as the starting point of the trajectory in the heart cam groove 180 is a plane parallel to the bottom surface of the slider 150. And the slope 182b which is a slope is formed so that it may rise up from the bottom surface 182a.

Passing the slope 182b which is a bottom surface as a slope, it becomes the bottom surface 182c which has a plane higher than the bottom surface 182a. Passing the bottom surface 182c becomes a step, resulting in a curved bottom surface 182d having a plane lower than the bottom surface 182c.

That is, the proximal end 172 of the locking pin 170 may return to the bottom surface 182c when the slider 150 reaches the bottom surface 182d in the process of moving the slider 150 from the card insertion hole side position to the card fixing position. There is no. Then, passing through the bottom surface 182d becomes a step to become a bottom surface 182e having a plane lower than the bottom surface 182d.

The bottom surface 182e forms a V-shaped groove by a V-shaped inner wall when viewed from a plane projecting toward the card insertion port side. The proximal end 172 of the locking pin 170 may return to the bottom surface 182d when the slider 150 reaches the bottom surface 182e in the process of moving the slider 150 from the card insertion position to the card fixing position. none. The state where the base end 172 reaches the bottom surface 182e of the V-shaped groove 34 is a locked state or a mounted state of the card 200. In addition, the trajectory from which the base end 172 reaches the bottom surface 182e to the bottom surface 182e becomes the trajectory of a royal path.

Then, when the card 200 is further inserted into the deep inside of the connector 100, that is, the rear side, against the elastic biasing force of the coil spring 160, the proximal end 172 of the locking pin 170 is V-shaped groove 34. ), The step is lowered through the bottom surface 182e and positioned on a bottom surface 182f of a plane lower than the bottom surface 182e. That is, the proximal end 172 which reached the bottom surface 182f cannot return to the bottom surface 182e.

Further, a bottom surface (slope) 182g, which is a slope inclined toward the card insertion side, is formed so as to rise from the bottom surface 182f in succession to the bottom surface 182f.

On the insertion opening side of the slope 182g, a bottom surface 182h having a plane higher than the slope 182g is formed. A step is formed on the card insertion port 102 side of the bottom surface 182h, and a bottom surface 182a having a plane lower than the bottom surface 182h is disposed.

As described above, the heart cam groove 180 draws a partially irreversible trajectory in the height direction while the contact point (the tip of the proximal end 172) of the locking pin 170 sliding on the bottom surface draws a heart-shaped plane trajectory. It is formed to be.

The locking pin 170 slides while being pressed from above by the card portion 190 formed on the shield cover 120 with respect to the bottom surface of the heart cam groove 180.

8 is a perspective view of the memory card connector according to the present embodiment.

The shield cover 120 is viewed from an approximately front view having the upper surface portion 121 and the side portions 120R and 120L facing in parallel to each other formed by bending a metal plate to be orthogonal to each other from both sides of the upper surface portion 121. It is shaped like a c. In addition, the side surface portion 120L covers the guide side wall portion 113, and the side surface portion 120R covers the side wall portion 114, and the lower side portions of the respective opposite ends of the side surface portions 120L and 120R are horizontally outward. It is bent, the fixing piece 120a for fixing the connector 100 to the substrate is formed.

Slider contact piece 122 which contacts the upper surface portion 121 of the shield cover 120 by applying pressure from above to the slider 150 (see FIGS. 1 and 2) moving in the insertion direction in the shield cover 120. Is installed. This slider press piece 122 always elastically biases the slider main body 152 (refer FIG. 1 and FIG. 2) of the slider 150 which moves to an insertion direction, and sets the slider 150 to the bottom plate part 112. FIG. Squeezed on.

Here, in the upper surface part 121 of the shield cover 120, the slider press-contact piece 122 processes the site | part which forms the upper surface part of the movement area | region of the slider 150, and extends downward from the back toward the front side. It is formed leaf spring material.

As a result, the slider 150 is always pressed downward to be movable in the front-rear direction in the housing 110 (see FIG. 1).

In addition, the locking jaw portion 155 is pushed on the side surface portion 120R of the shield cover 120 by pressing the slider 150 (refer to FIGS. 1 and 5) positioned horizontally in the position near the insertion hole toward the receiving portion 104. Jaw pressing piece 128 is installed to engage the notch groove portion 220 of the card 200.

The jaw pressing piece 128 is formed of an elongated strip-like inertia member formed by processing a part of the side surface portion of the shield cover 120, here, by a leaf spring. Specifically, the jaw pressing piece 128 is a portion of the card insertion port side at the side surface portion 120R of the shield cover 120 formed by processing a metal plate, and is formed from the rear end side toward the card insertion port side of the shield cover 120. It is formed by cutting out to protrude inward.

The tip end of the jaw pressing piece 128 is bent so as to protrude toward the inside, that is, the receiving portion 104 side, and the bending piece 129 (see FIG. 1) formed by this bending is placed on the card insertion opening side at the side wall portion 114. It protrudes in the housing 110 through the formed window part 114a (refer FIG. 1). The side of the slider 150 is pressed toward the receiving portion 104 side at the top end portion of the bent piece 129 protruding therein through the window portion 114a.

In this way, the jaw pressing piece 128 presses the slider 150 pushed forward by the coil spring 160 to the receiving portion 104 side at the position of the card insertion port side. Therefore, the slider 150 positioned at the position of the card insertion slot is swingably arranged against the pressing force of the jaw pressing piece 128 while the locking jaw portion 155 protrudes into the receiving portion 104. It is.

Furthermore, the heart cam groove 180 of the bottom plate portion 112 of the housing 110 is located on the upper surface portion 121 of the shield cover 120 inward from the slider card contact portion 122. Corresponding to the shape of is extended to the rear and is inclined downward.

The card unit 190 applies a pressure from above to the locking pin 170 (see FIG. 2) moving in conjunction with the slider 150 to press the heart cam groove 180 to the bottom surface of the heart cam groove 180. Slid the phase.

Fig. 9 is a view showing the relationship between the wide portion of the card portion and the heart cam groove portion, and is a partial sectional view of the card portion seen from the rear side of the connector.

The card portion 190 is formed by processing a portion of the upper surface portion 121 of the shield cover 120 that faces upward from the heart cam groove portion 180 positioned behind the portion where the slider contact piece 122 is formed. have.

The card portion 190 is a leaf spring which is inclined downward from the upper surface portion 121 of the shield cover 120, and the one end portion 172 of the locking pin 170 does not fall out of the heart cam groove portion 180. It is formed in a shape corresponding to the trajectory of the locking pin 170 to move along the cam groove 180.

Here, as shown in FIG. 8, the card part 190 is arrange | positioned so that it may overlap with the arrangement | positioning area | region of the heart cam groove part 180, when it sees from a plane, The card | shape card main part 191 and the card main part It is formed continuously to the tip of 191 and has the wide part 193 extended toward the tip side.

The heart cam groove 180 has a bottom surface having a plurality of heights different from each other, and a bottom surface (particularly the bottom surface 182d) constituting a path between the bottom surface 182e engaged with the V-shaped groove 34. The bottom surface (particularly the bottom surface 182f) that constitutes the return path has a lower level of height (see FIG. 7). Therefore, corresponding to the heights of these bottom surfaces 182c to f, the tip portion 194 of the wide portion 193 of the card portion 190 moves to the bottom surface side constituting the return side in the heart cam groove portion 180. It is inclined (see FIG. 9).

That is, in the plate-shaped card portion 190, the wide portion is formed around the axis of the card body portion 191 with respect to the card body portion 191 extending inclined downward from the rear surface of the upper surface portion 121 in the insertion direction. The front end portion 194 of 193 is twisted so that the end side of the bottom surface side which forms a return is located below. Accordingly, the tip portion 194 of the wide portion 193 is formed to be disposed in a twisted position with respect to the upper surface portion 121.

The card portion 190 is particularly the heart cam groove 180, when the one end 172 of the locking pin 170 is located near the step by the bottom surface (182a ~ 182h), the locking pin 170 The heart cam groove portion 180 is provided so as not to fall out.

As described above, the card unit 190 has a lock pin 170 on any bottom surface when the one end 172 of the lock pin 170 slides each of the bottom surfaces 180a to 180h of the heart cam groove 180. It is configured to press to give approximately the same load.

Next, with the relationship between the locking pin for moving the detachable operation of the card 200 to the memory card connector configured as described above and the operation of the locking mechanism along the heart cam groove, and the card portion for pressing the locking pin to the heart cam groove. Explain.

10 is a view showing the positional relationship between the heart cam groove, the locking pin and the pin pressing portion moving along the heart cam groove, Figure 11 to Figure 18, Figure 10, one end of the locking pin is the height of the heart cam groove Fig. 11 is a sectional side view showing the main portion showing the relationship with the card portions when they are located on different bottom surfaces. FIGS. 11-18 are main sectional side views which show the locking pin in which one end part is located in M1-M8 position on the bottom surface 182a-182h, respectively in FIG.

19 is a plan view of the housing showing the state in which the card is inserted into the connector according to the embodiment of the present invention in stages. In FIG. 19, the coil spring is omitted for convenience. FIG. 19 (a) is a plan view of the housing corresponding to FIG. 13, and FIG. 19 (b) is a plan view of the housing showing the state where the slider is in the card mounting position in the connector, and FIG. 19 (c). ) Is a plan view of the housing corresponding to FIG. 17. 20 and 21 are top plan views showing the relationship between the locking pin and the card portion corresponding to the position of one end of the locking pin shown in FIG. 20 (a) to 20 (c) show the positional relationship between the locking pin 170 and the card portion 190 in which one end portion 172 is positioned at the positions M2 to M4, respectively, and FIG. 21 (d). (G) shows the positional relationship between the locking pin 170 and the card part 190 in which the one end part 172 is located in the position M5-M8, respectively.

As shown in FIGS. 2 and 11, in the connector 100 in which the card 200 is not inserted, the slider 150 is the bottom plate portion of the housing 110 by the coil spring 160 (see FIG. 2). It is located at the card insertion port side on 112, and is elastically biased to the accommodating part 104 side by the jaw pressing piece 128. As shown in FIG.

Accordingly, in the slider 150 disposed between the bottom plate portion 112 and the upper surface portion 121 of the shield cover 120, the guide protrusion 151 of the lower surface is pressed on the front end of the slit 117, The tip portion 117a of the slit 117 is pressed toward the receiving portion 104 side. Therefore, the slider 150 is able to swing in the horizontal direction on the opposite side to the accommodating portion 104 in a state where the interference locking jaw portion 155 protrudes into the accommodating portion 104 at the position of the card insertion port side.

At this time, the locking pin 170 is disposed below the proximal end of the card main body 191 of the card 190 with the clearance G interposed therebetween. That is, the lock pin 170 is the front end side end portion of the bottom surface 182a of the base end 172 inserted into the heart cam groove 180 in the state of the connector 100 in which the card 200 is not inserted. It is arrange | positioned, without being pressed from the upper side in the state located in the side (refer FIG. 5 and FIG. 11).

The card 200 is inserted and pushed into the connector 100 in such a state from the card insertion hole 102. Then, the end of the card 200 is pressed in the insertion direction by the end of the opening 104 of the locking jaw portion 155 existing in the accommodation portion 104, that is, in the insertion region, and the slider 150 itself is accommodated in the accommodation portion 104. Rotate in the horizontal direction to the opposite side of). Accordingly, the locking jaw portion 155 is displaced in the direction away from the card 200 while sliding the side surface of the protrusion 230 of the side of the card 200 inserted into the receiving portion 104 in the jaw engaging groove 220. Enter Accordingly, the card 200 itself is held in the insertable / removable half lock state (see FIG. 1).

At this time, the protruding portion 156 is disposed to face the notch portion 210 of the card 200, and the notch portion 210 and the protruding portion 156 are engaged with each other.

Thereafter, by inserting the coil spring 160 in the insertion direction (A direction) of the card 200 against the elastic biasing force, the slider 150 moves the locking jaw 155 to the jaw recess 220. It is pressed by the inclined surface 156a by the inclined surface 212 which forms the notch part 210 in the engaged state. Accordingly, the slider 150 is guided by the slit 117 to move toward the rear end side of the connector 100. At this time, since the proximal end 172 (bending shaft) of the locking pin 170 is disposed in the heart cam groove 180, the locking pin 170 itself moves upward from the bottom surface (from the bottom surface 182a). It moves toward the bottom surface 182d via the slope 182b and the bottom surface 182c.

When the end portion 172 of the locking pin 170 moves inwardly from the bottom surface 182a in the insertion direction, from the middle portion of the bottom surface 182a, the locking pin 170 itself is from above and the upper surface of the upper portion. The card portion 190 abuts toward the insertion direction from the portion 121. Accordingly, the one end 172 slides on the bottom surface 182c while sliding under pressure on the bottom surface 182a, and moves to the position M2 shown in FIG. In the case where the one end 172 is located at the position M2 of the bottom surface 182c, as shown in FIG. 20 (a), the main body portion of the locking pin 170 is located below the card portion 190. , The card portion 190 is pressed against the bottom surface 182c.

Furthermore, when the slider 150 is deeply inserted inward, one end 172 of the locking pin 170 falls from the stepped bottom surface 182c to the bottom surface 182d, and M3 shown in FIG. Move to the location. The insertion degree of the card 200 to the connector 100 at this time is shown in Fig. 19A. Further, the positional relationship between the locking pin and the card portion 190 when the one end portion 172 is positioned at the position M3 of the bottom surface 182d is in the state shown in FIG. 20 (b).

Then, when the pushing of the card 200 pushed up to the position M3 is released, the base end portion 172 of the locking pin 170 returns to the card insertion hole side by the elastic biasing force of the coil spring. Pushed. At this time, the base end portion 172 of the locking pin 170 is moved to the bottom surface 182e side without returning to the bottom surface 182c side of the position higher than the bottom surface 182. In FIG. 14 and FIG. 20 (c), in the bottom surface 182d having a lower level than the bottom surface 182c, the step surface with the bottom surface 182c is guided toward the bottom surface 182e. The state located in M4 position of the step part as a boundary part with the bottom surface 182e is shown.

The locking pin 170 whose one end portion 172 is positioned at the position M4 of the stepped portion between the bottom surface 182d and the bottom surface 182e is reliably pressed from above by the card portion 190. In the card portion 190, the front end portion 194 (here center portion) of the wide portion 193, which presses the locking pin 170 at which one end 172 is positioned at position M4, is the bottom surface 182d. Corresponding to the bottom surface 182e having a lower height level, the inclination is inclined downward from the end portion at the bottom surface 182d side. Accordingly, the card portion 190 provides the lock pin 170 with approximately the same load as when the one end portion 172 is located on the bottom surface 182d.

As shown in FIG. 15, one end 172 of the locking pin 170 moves to the bottom surface 182e by the elastic biasing force of the coil spring 160, and thus the position on the bottom surface 182e ( In M5) it is caught and fixed to the V-shaped groove (34).

In a state where the proximal end 172 of the locking pin 170 is engaged with the V-shaped groove 34, as shown in FIG. 19B, the slider 150 is pulled out by the elastic biasing force of the coil spring. The movement in the direction is regulated and fixed to the mounting position of the card 200. That is, the card 200 is in a mounted state. At this time, the card portion 190, as shown in Fig. 21 (d), the locking pin 170 in the center portion of the front end portion 194 of the wide portion 193, the bottom surface of the V-shaped groove portion 34 The one end 172 is pressed by the substantially same load as the case where the one end part 172 is located in position M4 on the side of 182e.

Thus, as shown in Figs. 15 and 19 (b), while the slider 150 is located at the mounting position, the electrodes on the front lower surface of the mounted card 200 are connected to a plurality of contacts (cantilever contacts) ( 130 (see FIG. 2), data of the card 200 can be read and written. In addition, at this time, since the locking jaw portion 155 enters and is engaged with the jaw groove 220 of the card 200, it is possible to prevent the card 200 from easily exiting from the connector 100 by vibration or the like. Can be.

On the other hand, when the card 200 is removed by releasing the locked state, the card 200 in the card mounted state is pushed deep into the connector 100. That is, in the state in which the card 200 is mounted, the card 200 is further inserted in the insertion direction against the elastic biasing force of the coil spring 160, so that the base end 172 of the locking pin 170 (bending shaft) ) Is released from the V-shaped groove 34.

Then, the base end 172 of the locking pin 170 on the bottom surface 182e does not return to the adjacent bottom surface 182d with a step higher than the bottom surface 182e, and is shown in Figs. 16 and 21 (e). As shown in the figure, the plate moves to the bottom surface 182f side.

The locking pin 170 whose one end 172 is located at the position M6 of the boundary portion between the bottom surface 182e and the bottom surface 182f is the tip portion 194 of the wide portion 193 of the card portion 190. It is pressed by the site | part on the bottom surface 182f side rather than the center part of (). In this case, the load applied to the locking pin 170 of the card portion 190 at the distal end portion 194 of the wide portion 193 is placed downward at the end side of the bottom surface 182f with the center portion therebetween. Since it is inclined, the one end portion 172 has approximately the same force as the case where it is located at the position M2, the position M4, or the like.

Then, one end 172 of the locking pin 170 slides from the bottom surface 182e to the bottom surface 182f side while leaving the V-shaped groove 34 and passing through the position M6, as shown in FIG. It moves on the bottom surface 182f. As described above, the locking pin 170 having the one end 172 positioned at the position M7 of the bottom surface 182f has a wide portion 193 of the card portion 190. It is pressed by the end portion of the bottom surface 182 side of the tip portion 194 of. In addition, the load applied to the locking pin 170 at this time is located in the distal end portion 194 of the wide portion 193 so as to be positioned below the end on the bottom surface 182d side of the portion that abuts the locking pin 170. Therefore, the one end 172 is substantially the same force as the case where it is located in the position M2, the position M4, etc.

In this way, the card 200 is pushed deep into the connector 100, and when the pushed state is released, the movement of the slider 150 is followed by the elastic biasing force of the coil spring 160, thereby inserting the card insertion hole 102. ) Side. Specifically, one end 172 of locking pin 170 passes from bottom surface 182f to bottom surface (slope) 182g, bottom surface 182h (see FIG. 18), and bottom surface 182a. Move to draw the return trajectory.

Specifically, one end 172 of the locking pin 170 rides on the bottom surface (slope) 182g and is referred to the position M8 (see FIG. 21 (g)) from the position M7 (see FIG. 21 (f)). Even in the case of moving to), the card portion 190 is disposed directly above the one end portion 172.

Therefore, the lock pin 170 is always in a state of being pressed on the bottom surface 182f, 182g, 182h side rather than the card part 190. As shown in FIG. In addition, the movement of the one end 172 of the locking pin 170 becomes a movement to the position of high height by raising the bottom surface 182g, and also the movement to the base end side of the card part 190. The protruding degree with respect to the upper surface part 121 of the card part 190 is slower than the distal end part 194 of the wide part 193 of the front end side. Therefore, even if one end part 172 moves to the height direction approaching the upper surface part 121, the pressing force from upper direction is substantially the same as the case where it is located in the bottom surface 182f.

The locking pin 170 guided and moved to the heart cam groove 180 is always the bottom surface 182a to 182h, as shown in FIGS. 11 to 18, particularly in the stepped portion of the heart cam groove 180. Is pressed against the heart cam groove portion 180 side by the card portion 190 formed corresponding to the height level.

As described above, even if the locking pin 170 is provided with the card part 190 in the shield cover 120, the bottom of the heart cam groove part 180 having a different height level at approximately the same pressure is always provided by the card part 190. The surface 182a to 182h is pushed to slide on each bottom surface. Therefore, the locking pin 170 can be slid without falling out without scraping the bottom surfaces 182a to 182h of the heart cam groove 180, and can accurately pass the trajectory by the heart cam groove 180.

With the movement of the locking pin 170, the slider 150 moves in the disengaging direction due to the elastic biasing force of the coil spring 160, so that the inclined surface 212 of the card 200 abuts on the inclined surface 156a is removed. Direction to move the card 200 in the release direction.

In the connector 100 of this embodiment, the slider 150 which is a slide member is covered with the shield cover 120 from the upper side, and is a slide member in the resin housing 110 which accommodates the card 200. It is arranged so that the slide can be moved in a direction and a discharge direction. Slider 150 is pressed by the card 200 in accordance with the insertion of the card 200 into the housing 110 to move deep inside the housing 110 to the mounting position of the inside, together with the card 200 when discharged It moves to the ejection position (card insertion opening side position) by the insertion port 102 side, and is hold | maintained in the state which protruded the card 200 outward from the insertion hole 102 in a discharge position. The slider 150 is elastically biased in the discharge direction by the coil spring 160. In the connector 100, the heart cam groove 180 is formed in the housing 110, and the locking pin 170 is engaged with the heart cam groove 180 in the slider 150. The locking pin 170 moves within the heart cam groove 180 according to the slide movement of the slider 150 by pressing the card 200, thereby counteracting the slider 150 against the elastic biasing force of the coil spring 160. To move it to the position to be held at the mounting position and the position to release the holding. The locking pin 170 is pushed downward by the card portion (pressing member) 190 formed by cutting a portion of the shield cover 120 downward, thereby preventing the cam pin 180 from being pulled out. The card portion 190 is formed at the position where the locking pin 170 is moved to the shield cover 120 from the discharge position and pressed toward the cam groove portion 180 during the movement of the cam groove portion 180. In addition, a clearance G is formed between the locking pin 170 at the discharge position and the upper surface portion 121 of the upper shield cover 120.

According to the present embodiment, when the card 200 is not inserted, the locking pin 170 is disposed with the clearance G interposed below the proximal end of the card main body 191 of the card unit 190. The base end portion 172 inserted into the heart cam groove portion 180 is arranged without being pressed from above in a state of being positioned on the tip side end portion side of the bottom surface 182a.

Accordingly, in the state where the card 200 is not inserted, no load is applied to the locking pin 170 at all. Therefore, reflow heating at the time of mounting the connector 100 on a board | substrate can be performed in the state which does not apply the load to the locking pin 170. FIG. That is, in the connector 100 in a state, the locking pin 170 and the card part 190 which is a part of the metal shield cover 120 are separated. Therefore, the force pressed by the locking pin 170 by the card unit 190 and the heat heated by the reflow are not transmitted to the locking pin 170. Thus, the card 190 allows the locking pin 170 to heat the reflow heat without pressing it with respect to the resin housing 110 (in detail, the bottom plate portion 112) having the heart cam groove 180. This is done.

That is, unlike the prior art, in the reflow, the center portion of the bottom surface portion of the housing, which is generated by applying pressure from the locking pin while the bottom surface portion (bottom plate portion 112) of the resin housing is softened. Deformation improvement at the time of high-temperature deformation which expanded to below affects the whole plane (including a heart cam groove part) of the housing 110 as it is, and it does not harden in the state which the fixing piece 120a of the side lifted.

Therefore, unlike the related art, deformation of the housing 110 after reflow such as lifting of the fixing piece 120a on both sides can be prevented, and the connector terminal flatness (coplanarity) after reflow can be improved.

In addition, the position card portion 190 that the locking pin 170 moves from the discharge position and presses toward the cam groove portion 180 during the movement of the cam groove portion 180 is formed corresponding to the shape of the heart cam groove portion 180. Specifically, corresponding to different height levels of the bottom surfaces 182a to 182h on which one end 172 of the locking pin 170 slides, the degree of protrusion downward from the shield cover 120 and the width of the protrusion The tip portion 194 elongated in the width direction of the portion 193 is inclined along the height of the bottom surfaces 182d to 182f so as to intersect the insertion direction. As a result, the conventional locking mechanism using the heart cam groove is not provided, and the same pressing force is applied to one end portion 172 that slides certain bottom surfaces 182a to 182h.

Moreover, in this connector 100, when ejecting the card 200, the jaw pressing piece (plate spring) 128 (plate spring) 128 of the locking jaw part 155 of the slider 150 in the carding groove 220 of a card (FIG. 1), the card is prevented from being pulled out by elastic biasing. Further, when ejecting the memory card 200, when the card in the locked state is released by pressing with a fingertip (pressing in the inserting direction), the slider increases the acceleration and moves in the card ejection direction (ejection direction) together ( 150 and the force of the memory card 200 are suppressed by the pusher piece 128 (refer FIG. 1) and the slider press-contact piece 122 (refer FIG. 1) which elastically biases the slider 150 itself downward. Accordingly, since the memory card 200 discharged from the connector is not directly pressed, it is possible to prevent the card 200 from popping out without leaving a trace of pressing the card 200 itself. Since the locking pin 170 is connected to the slider 150, the pressing force by the card unit 190 also attenuates the elastic biasing force in the disengaging direction of the slider 150 by the coil spring 160.

In addition, in the connector 100, the heart cam groove portion 180 has a right end when the front end portion of the memory card accommodated in the housing portion 104 and one side of the connector 100 (the card insertion hole 102 are viewed from the front). It is disposed between the coil spring 160 extending in the insertion direction along the side). That is, in the connector 100, the locking mechanism 140 including the housing 104, the coil spring 160 and the heart cam groove 180 that elastically bias the slider 150 on the housing 110. Is reasonably arranged to be water-soluble.

Therefore, in the connector 100, the width of the connector 100 is formed to have a length close to the width of the sum of the width of the memory card itself and the width of the locking mechanism 140, and the size of the connector 100 is reduced. Saving of mounting space is also planned.

Moreover, the slider press-contact piece 122 is press-contacted to the slider 150 located in the card insertion port side. Therefore, when the slider 150 returns to the position of the card insertion port side from the card holding position, which is the position of the rearmost side in the receiving portion, by the elastic biasing force of the coil spring 160, that is, at the time of the card ejection operation, The slider contact piece 122 may mainly reduce the moving force of the slider 150 due to the elastic biasing force together with the jaw pressing piece 128.

The memory card connector according to the present invention is not limited to the above embodiments, and various modifications can be made. In addition, the present invention may make various schematic modifications without departing from the spirit of the present invention, and the name is natural for the present invention.

The memory card connector according to the present invention has an effect that the housing itself is not deformed well even when the board is reflowed in the board mounting, and thus can be preferably mounted. It is useful as a push-in push-out memory card connector for mounting a memory card.

1 is a perspective external view showing the configuration of a memory card connector according to an embodiment of the present invention;

2 is a plan view of a housing in a state where a shield cover is removed in a memory card connector according to an embodiment of the present invention;

3 is a bottom view of the housing shown in FIG. 2;

4 is a right side view of the housing shown in FIG. 2;

FIG. 5 is a partial longitudinal cross-sectional view showing the locking pin when the slide is located at the half lock position in the connector shown in FIG. 1; FIG.

6 is an enlarged view of a heart cam groove;

7 is a view showing the height relationship in the vertical direction of the memory card connector between the stepped slope and the stepped portion of the heart cam groove;

8 is a perspective view of the memory card connector according to the present embodiment;

9 is a view showing a relationship between the tip portion of the wide portion of the card portion and the heart cam groove portion;

10 is a view showing the positional relationship between the heart cam groove, the locking pin and the pin pressing portion moving along the heart cam groove,

FIG. 11 is a side cross-sectional view showing a relationship with a card part when one end of the locking pin is located on a bottom surface having a different height in the heart cam groove part in FIG. 10;

FIG. 12 is a side cross-sectional view showing a relationship with a card part when one end of the locking pin is located on a bottom surface having a different height in the heart cam groove part, respectively;

FIG. 13 is a sectional side view of the main part showing a relationship with a card part when one end of the locking pin is located on a bottom surface having a different height in the heart cam groove part;

FIG. 14 is a sectional side view of the main part showing a relationship with a card part when one end of the locking pin is located on a bottom surface having a different height in the heart cam groove part;

FIG. 15 is a side cross-sectional view showing a relationship with a card part when one end of the locking pin is located on a bottom surface having a different height in the heart cam groove part in FIG. 10;

FIG. 16 is a cross-sectional view of a main portion showing a relationship with a card portion when one end of the locking pin is located on a bottom surface having a different height in the heart cam groove portion;

FIG. 17 is a side cross-sectional view showing a relationship with a card part when one end of the locking pin is located on a bottom surface having a different height in the heart cam groove part in FIG. 10;

FIG. 18 is a sectional side view of the main portion showing the relationship with the card portion in the case where one end portion is respectively located on the bottom surface having different heights in the heart cam groove portion;

19 is a plan view of the housing showing the state in which the card is inserted into the connector according to an embodiment of the present invention in stages,

20 is a plan view of a main portion showing the relationship between the locking pin and the card portion corresponding to the position of one end of the locking pin shown in FIG.

21 is a plan view of a main part showing the relationship between the locking pin and the card portion corresponding to the position of one end of the locking pin shown in FIG. 10;

<Description of the code>

100... Connector 102... Card slot,

104... Receiving portion, 110... housing,

112... Bottom surface portion 113. Guide sidewalls,

114... Side wall portion 120... Shield Cover,

121... Upper surface portion, 130... Contact,

140... Lock mechanism 150... Slider,

152... Slider body 155... Locking Jaw,

156... Protruding part, 158... Pin retainer,

160... Coil spring, 170... Lock Pin,

172... One end (base end), 174... Tiptoe,

180... Heart Cam Home, 182... Bottom View,

190... Card portion 191... Body,

193... Wide section, 200... Memory card

Claims (2)

A housing made of resin having a memory card to be inserted and having terminals connected to electrodes of the memory card to be accommodated, a shield cover which covers the housing from above with the insertion opening for inserting the card open; Arranged in the housing so as to be slidably movable in the inserting direction and the ejecting direction of the memory card, and pressed into the memory card according to the insertion of the memory card into the housing to move the inside of the housing to the mounting position deep inside; And a slide member which, together with the memory card, moves to the discharging position on the insertion opening side to hold the memory card in a state in which the memory card protrudes outward from the inserting opening at the discharging position, and the slide member in the discharging direction. An elastic bias member for elastically biasing And a heart-shaped cam groove portion formed in any one of the housing and the slide member, installed in the other one of the housing and the slide member, and engaged with the cam groove portion, A locking pin for moving the inside of the cam groove to move the slide member to a position where the slide member is held in the mounting position against the elastic biasing force of the elastic bias member and to release the holding portion; A pressing member is formed by cutting a portion downward, and presses the locking pin downward, and corresponds to a pressing member which prevents the locking pin from being pulled out of the cam groove, and a movement area of the slide member among upper surfaces of the shield cover. Is formed in the upper surface portion, and the pressure welding to elastically bias the slide member downward Have a side, The pressing member is formed in the shield cover at a position where the locking pin is moved from the discharge position and pressed toward the cam groove portion during movement of the cam groove portion. A memory card connector, wherein a gap is formed between the locking pin and the shield cover above in the discharge position. The slide member of claim 1, wherein the slide member is disposed to be slidably movable in the insertion direction and the discharge direction along one side surface of the housing, The cam groove portion is formed in the housing deeper than the slide movement region of the slide member, And the locking pin is engaged with the cam groove and installed in the slide member.

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