JP4717359B2 - Card connector - Google Patents

Description

  The present invention relates to a card connector that accepts a card-like medium such as a memory card (hereinafter also simply referred to as “card”).

  Conventionally, a card connector that accepts a card-like medium such as a memory card has a card receiving cavity, a plurality of terminals with contact pieces facing the card receiving cavity, and a card ejection mechanism for the card received in the card receiving cavity. And. When a card-like medium such as a memory card is inserted into the card receiving cavity, the contact pads of the card-like medium and the contact pieces of the terminals are engaged in a one-to-one relationship and are electrically connected. The card-like medium inserted into the card receiving cavity can be taken out by operating the card discharge mechanism.

  The plurality of terminals are supported by an insulating housing. This insulating housing has an elongated block-like terminal support part, and further has a side wall extending in an arm shape so as to face each other from both ends of the terminal support part, and a bottom plate between both side walls. ing. A metal shell is assembled on the upper side of the insulating housing, and the metal shell and the insulating housing cooperate to define the card receiving cavity (see Patent Documents 1 and 2).

Various mechanisms have been adopted as the card ejection mechanism. As the card connector has been miniaturized, so-called push / push type card ejection mechanisms have been increasingly used (Patent Documents). 2). This push / push-type card ejection mechanism is a slide member that engages with a card-like medium so as to be able to slide integrally with the card-like medium, and has a heart-shaped cam groove formed on the side surface. The main components are a cam slider, a spring for urging the slide movement of the cam slider, and a cam pin that engages with a cam groove formed on the cam slider to control the slide of the cam slider. The cam slider is guided by a guide rail provided on the side wall or bottom plate of the insulating housing.
In recent years, electronic devices such as video cameras, digital still cameras, mobile phones, and PDAs (Personal Digital Assistants) have made remarkable progress in miniaturization and functionality, but the card connectors mounted on these electronic devices The push / push type card discharge mechanism has become the mainstream.

  A card connector 300 as shown in FIG. 18 has also been proposed. In the card connector 300, the insulating housing 310 and the metal shell 320 cooperate to define a card receiving cavity and receive the card 330. A card discharge mechanism 340 supported by the side wall 311 of the insulating housing 310 and the metal shell 320 is installed on one side of the card receiving cavity. The card ejection mechanism 340 is configured as a push / push type having a cam slider 341, a cam pin 342, and a coil spring 343 as main components. The cam slider 341 has an initial position (the illustrated position) where the insertion of the card 330 is awaited, and a connection position where the contact pad 331 of the card 330 is engaged with the terminal 350 mounted on the terminal support wall 312 of the insulating housing 310. It is possible to slide between. The cam slider 341 has a locking hook 344 that protrudes toward the card receiving cavity and can be engaged with the notch recess 332 of the card 330, and a back surface 345 that faces the side plate 321 of the metal shell 320. On the side plate 321 of the metal shell 320, a plate-like spring 322 having a doubly-supported spring structure is cut and raised at a portion substantially corresponding to the initial position of the cam slider 341 so as to back up the back surface 345 of the cam slider 341. When the locking hook 344 is pushed outward by the insertion of the card 330, the cam slider 341 can be tilted while elastically deforming the plate spring 322.

JP 2002-329553 A (paragraphs 0004 to 0010, FIGS. 6 to 9) JP 2002-343468 A (paragraphs 0004-0011, FIGS. 8-11, paragraphs 0013-0048, FIGS. 1, 6, 7)

In the case of the card connector having the push / push type card ejection mechanism, when the card is used, the card is set at the initial position of the card receiving cavity and inserted to the back connection position. Further, when the card is taken out, the push / push type card ejection mechanism is operated through the card. When the card ejection mechanism is operated, the cam slider integrated with the card is urged by the spring in the removal direction so that the card at the connection position is ejected to the initial position and the card can be taken out therefrom.
The problem here is the card pop-out phenomenon when the card is removed. When the elasticity of the spring urging the cam slider is strong, the card pops out of the cam slider due to inertia, regardless of whether the cam slider stops at the initial position. There is a risk that the card may be lost or damaged due to the card popping out.

  An object of the present invention is to provide a card connector that prevents a card from jumping out of a card receiving cavity when the card is taken out.

The card connector according to the present invention made for such an object includes a card receiving cavity and a card for discharging the card inserted into the card receiving cavity from the initial position to the back connection position to the initial position. A card connector having a discharge mechanism,
The card ejection mechanism, and the cam slider is installed at one side of the card-receiving cavity, slides in the card receiving cavity becomes card integrated with the insertion and direction of withdrawal of the card,
A push / push type card ejection mechanism comprising a cam pin that engages with the cam groove of the cam slider and controls the sliding of the cam slider, and a spring for biasing the cam slider in the card removal direction. In the card connector,
The cam slider has a locking hook that engages or disengages with a notch recess formed in the side edge of the card, on the side facing the side edge of the card, On the back side, a plate-like spring that backs up the cam slider is opposed to it,
A protrusion is formed on the plate spring,
When the card is in said initial position, when the projecting portion of the plate spring is against the rear surface of the locking hook, cam slider to the locking hook is cutout recess engage or disengage the card is tilted The load is larger than when the card is in the connection position .

  In the card connector of the present invention having the configuration as described above, when the card and the cam slider (slide member) are both in the initial position, the protruding portion of the plate spring is in contact with the back surface of the cam slider (slide member). Therefore, when the cam slider (sliding member) tilts at the initial position, the elastic force set on the plate spring can be applied directly from the beginning of the tilting. Also, the elastic force of the plate spring is set so that the load against the tilt of the cam slider (sliding member) in which the locking hook at the initial position retracts away from the side edge of the card is larger than that at the connection position. The degree of freedom is high. As a result, the frictional force between the card and the cam slider (sliding member) is strengthened to maintain the integrity of both at the initial position, and the card can be reliably prevented from jumping away from the cam slider (sliding member). it can. Therefore, the risk of loss or damage of the card can be eliminated.

  Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings. First, the overall structure of the card connector according to the embodiment will be described, and then the features according to the present invention will be described in detail.

  FIG. 1 shows a card connector 10 according to an embodiment in a state where a card 12 is received. (A) of the figure is a perspective view of the card connector 10 as viewed from above, and (b) is a perspective view of the card connector 10 as viewed from below.

  The card connector 10 includes a metal shell 20, a terminal support block 30, a plurality of terminals 40 mounted in parallel to the terminal support block 30, and a push / push type card ejection mechanism 50. .

  The metal shell 20 is formed by forming a thin metal plate such as stainless steel as shown in FIG. 3, and defines a card receiving cavity 14 (see FIG. 2) for receiving the card 12. That is, the metal shell 20 has a substantially rectangular top plate 21 facing one surface (upper surface) of the card 12 and a box bend formed in a substantially U-shaped cross-section in a continuous manner on opposite side edges of the top plate 21. The card receiving cavity 14 is formed on the lower side of the top plate 21. The lower side of the card receiving cavity 14 is open between the box bending portions 22 and 23, and one end which is the front side in FIG. 1A is opened as a card insertion slot 141.

  The structure of the box bends 22 and 23 will be described with reference to FIGS. 1 and 2. One box bend 22 located on the right side in FIG. And a bottom plate 222 which is bent at a substantially right angle from the side plate 221 and is continuous and opposed to the top plate 21, and has a substantially U-shaped cross section between the side edge of the top plate 21 and the bottom plate 222. ing.

  The other box bending portion 23 facing the one box bending portion 22 is also substantially the same, and is bent continuously at a substantially right angle from the top plate 21 and continuously bent at a substantially right angle from the side plate 231. The bottom plate 232 is opposed to the top plate 21, and the cross section between the side edge of the top plate 21 and the bottom plate 232 is substantially U-shaped.

  As shown in FIGS. 1B and 2, the bottom plate 232 of the other box bending portion 23 is wider than the bottom plate 222 of the one box bending portion 22. Both side plates 221 and 231 have the same height, and are slightly thicker than the thickness of the card 12 because of the card receiving cavity 14 defined below the top plate 21. ing.

  In the box bending portions 22 and 23, the respective bottom side plates 222 and 232 do not extend over the entire length of the side plates 221 and 231. The bottom side plate 222 of one box bending portion 22 is partially provided in the middle of the side plate 221. An outwardly facing nail piece 223 and an inward guide piece 224 are provided on the card insertion slot 141 side from the bottom side plate 222 so as to be substantially perpendicular to the side plate 221 in the same plane as the bottom side plate 222. ing.

  The bottom side plate 232 of the other box bending portion 23 extends over the entire length of the side plate 231 except for the end portion on the card insertion port 141 side. At the end of the side plate 231 where the bottom side plate 232 is not provided, an outwardly facing nail piece 233 is provided in the same plane as the bottom side plate 232, and the card insertion guide component 24 is attached. This card insertion guide component 24 is formed by molding an insulating plastic into a block shape as shown in FIG. 4, and is an engagement piece 211 (see FIG. 3) suspended from the top plate 21 side of the metal shell 20. ) Into the engagement hole 242 so that the card insertion guide component 24 can be integrated with the metal shell 20. The card insertion guide component 24 attached to the end of the side plate 231 is opposed to the U-shaped portion formed by the guide piece 224 of the box bending portion 22, the side plate 221 and the side edge of the top plate 21. In cooperation, the insertion of the card 12 into the card receiving cavity 14 is guided.

  As shown in FIG. 5, the terminal support block 30 is formed by molding an insulating plastic into a substantially square bar shape. The length is substantially equal to the distance between the opposing side plates 221 and 231 of the metal shell 20, and a plurality of mounting holes 31 for the terminals 40 are formed in parallel in the middle part. The terminal support block 30 is attached to the back of the card receiving cavity 14 defined by the metal shell 20, that is, the end facing the card insertion slot 141. One end face of the terminal support block 30 and the side plate 221 of the metal shell 20 facing the end face are provided with engagement means such as an engagement window 225 and an engagement protrusion 32 so that the metal shell 20 and the terminal support block 30 are provided. Can be integrated. Further, as shown in FIG. 2, the engagement piece 25 also hangs down from the edge of the top plate 21 of the metal shell 20, and is formed by the engagement window 251 and the engagement protrusion 32 formed in the engagement piece 25. Engagement means are also provided. The engaging piece 25 is provided with a nail piece 252 continuously. The nail pieces 252 are provided in the same plane as the nail pieces 223 and 233 of the side plates 221 and 231.

  The plurality of terminals 40 mounted in the mounting holes 31 of the terminal support block 30 are formed by punching a thin metal plate having high spring properties such as phosphor bronze, and have a contact piece 41 at one end and at the other end. A nail piece 42 is provided. The contact piece 41 faces the back of the card receiving cavity 14 in a cantilever shape (FIG. 2). The nail piece 42 extends in an L shape outside the terminal support block 30 (FIGS. 1B and 2). The nail pieces 42 are also arranged in the same plane as the nail pieces 223, 233, 252 provided on the metal shell 20, and these nail pieces 42, 223, 233, 252 are mounted with the card connector 10. Surface soldering can be performed simultaneously on a mounting board such as a printed board.

  The card discharge mechanism 50 is installed in the inner space of the box bending portion 23 of the metal shell 20. The card discharge mechanism 50 is a known push / push mechanism, and includes a cam slider 51, a coil spring 52, and a cam pin 53 as main components as shown in FIG. A cam slider 51 is placed on the bottom plate 232 of the box bending portion 23, and a projecting guide rail 234 formed by cutting and raising in the bottom plate 232 and a slide groove 511 formed on the lower surface of the cam slider 51. And the cam slider 51 is guided by the guide rail 234 in the direction in which the card 12 is inserted into and removed from the card receiving cavity 14 as indicated by the arrow 15 in FIG. Yes.

  The cam slider 51 is provided with a cam groove 512 (a heart cam, see FIGS. 7 to 10) with which the cam pin 53 engages, and an inclined wall surface 513 that is in contact with the front end side portion of the card 12 in the insertion direction. And a notch recess 121 (see FIGS. 7 to 10) formed on the side edge of the card 12 and a locking hook 514 that can be engaged and disengaged.

  The coil spring 52 is installed in a resilient state between the cam slider 51 and a spring receiving wall 33 provided at one end of the terminal support block 30 so that the cam slider 51 is always in the direction of the arrow 521 (the card 12 is It is designed to be biased in the direction of removal.

  The cam pin 53 has a shape in which both ends of a round metal bar are bent at a substantially right angle, and one end of the cam pin 53 is attached to one side of the card insertion slot 141, and the pin engagement recess 243 of the card insertion guide component 24 (see FIG. 4). ) And the other end is engaged with the cam groove 512 of the cam slider 51. By such engagement of the cam groove 512 and the cam pin 53, the sliding operation of the cam slider 51 is controlled to be a push / push type operation as described below.

  Next, the operation of the cam slider 51 when the card 12 is inserted into the card receiving cavity 14 of the card connector 10 configured as described above will be described with reference to FIGS. In addition to the notch recess 121 being formed on the card 12, contact pads 122 are provided in parallel on the upper surface of the front end in the insertion direction, as shown in FIGS. On one side of the front end, there is provided a polarity determining corner 123 having a shape obtained by obliquely cutting off a corner of a square plate. The contact piece 41 of the terminal 40 corresponds to the contact pad 122 in a one-to-one relationship, and the inclined wall surface 513 of the cam slider 51 faces the polarity determining corner 123. It can be contacted without a gap.

FIG. 7 shows an initial state in which the card 12 is correctly inserted into the card receiving cavity 14 through the card insertion slot 141. At this time, the cam slider 51 is in a no-load state and is located at a position closest to the card insertion slot 141 by the urging force of the coil spring 52. That is, FIG. 7 shows the initial positions of the card 12 and the cam slider 51. When the card 12 is inserted, the polarity determining corner 123 of the card 12 comes into contact with the inclined wall surface 513 of the cam slider 51, and the locking hook 514 of the cam slider 51 is engaged with the notch recess 121 of the card 12 to be locked. The card 12 and the cam slider 51 are integrated. The manner in which the locking hook 514 and the cutout recess 121 are engaged will be described later.

  FIG. 8 is a view showing a state in which the card 12 is advanced from the initial state of FIG. 7 to a position where the front end of the card 12 comes into contact with the terminal support block 30. This is called an overstroke state. The insertion force applied to the card 12 is released at this overstroke state. As the card 12 enters the overstroke state, the cam slider 51 is also guided by the guide rail 234 and slides into the back of the card receiving cavity 14 together with the card 12.

  When the card 12 is inserted to the overstroke state and the insertion force is released, the cam slider 51 is moved as shown by the arrow 16 in FIG. The card 12 and the cam slider 51 are slid to the position shown in FIG. 9 and stopped. This state is called a locked state. The slide of the card 12 and the cam slider 51 stops in the locked state because of the shape of the cam groove 512 of the cam slider 51 with which the cam pin 53 is engaged.

  The slide of the cam slider 51 from the overstroke state to the locked state is also guided by the guide rail 234 of the bottom side plate 232 constituting the box bending portion 23. In the locked state of the card 12, each contact piece 41 of the plurality of terminals 40 is engaged with the contact pad 122 of the card 12 with a predetermined contact pressure, and the contact pad 122 and the contact piece 41 are electrically connected. It becomes a state. The position of the cam slider 51 and the card 12 in the locked state is the connection position.

  When removing the card 12 inserted into the card receiving cavity 14 as shown in FIG. 9, the insertion force is applied again to the card 12 to release the insertion force as shown in FIG. Then, the engaging position of the cam pin 53 in the cam groove 512 is moved away from the position where the sliding of the cam slider 51 is stopped (see FIGS. 9 and 10), and the cam slider 51 and the card 12 are moved as shown in FIG. Up to the initial position, the card spring 52 is pushed back in the direction of the arrow 17 by the repulsive force, and the card 12 can be taken out. The slide of the cam slider 51 from the position of the overstroke in FIG. 10 to the initial position in FIG. 7 is also guided by the guide rail 234 of the bottom side plate 232.

  In order for the locking hook 514 of the cam slider 51 to engage and disengage from the notch recess 121 of the card 12, the locking hook 514 needs to be retracted away from the side edge of the card 12. Therefore, the outer surface of the cam slider 51, that is, the back surface 515 of the locking hook 514 is backed up by a plate spring 235 punched out on the side plate 231 of the metal shell 20, as shown in FIGS. This plate-like spring 235 is in the form of a double-supported spring. As shown in the figure, the intermediate portion is bent and formed with a protruding portion 236 near one end (on the card insertion port 141 side). It protrudes toward the cam slider 51.

  The positional relationship and the opposing relationship between the back surface 515 of the cam slider 51 and the protruding portion 236 of the plate spring 235 are such that when the cam slider 51 is in the initial position, the protruding portion 236 and the back surface 515 are just opposite to each other as shown in FIG. When the cam slider 51 is in the connection position, the back surface 515 is on the other end (the back side of the card receiving cavity 14) of the plate spring 235 as shown in FIG. It moves so as to face each other.

  When the notch recess 121 of the card 12 and the locking hook 514 of the cam slider 51 are engaged or disengaged, as shown by the arrow 17 in FIGS. The lock hook 514 can be retracted in a direction away from the side edge of the card 12 by being deformed. A reference numeral 212 shown in FIG. 11 is a presser spring that is cut and raised on the top plate 21 of the metal shell 20 and biases the cam pin 53 toward the cam groove 512.

  When the card 12 and the cam slider 51 are in the initial position (FIG. 12), when the cam slider 51 tilts in the direction of arrow 17, the protrusion 236 of the plate spring 235 extends from the side plate 221 of the metal shell 20 to the card receiving cavity. 14 protrudes into contact with the back surface 515 so that the gap 323 as seen in the conventional card connector 300 shown in FIG. 19 is almost eliminated, and the elastic force of the plate spring 235 is extremely small at this initial position. Therefore, the cam slider 51 is immediately backed up by the strong elastic force of the plate spring 235. On the other hand, when the card 12 and the cam slider 51 are in the connection position (FIG. 13), the cam slider 51 is tilted by itself or by the elasticity of the plate spring 235 even if the back surface 515 is in contact with the plate spring 235. It can be tilted as before. In this position, the setting is such that no strong elastic force is generated as in the initial position, and tilting is relatively easy. That is, the load when the cam slider 51 is tilted is larger at the initial position than at the connection position. In other words, the engagement or disengagement between the locking hook 514 and the notch recess 121 is relatively difficult when the card 12 and the cam slider 51 are in the initial position compared to when they are in the connected position.

  As described above, the back surface 515 of the cam slider 51 is backed up by the plate-like spring 235 on the metal shell 20 side as described above. As a result, the integrity of the card 12 and the cam slider 51 is compared at the initial position. Is maintained strongly and frictional force is also increased. When the card 12 is ejected from the connection position to the initial position by the elasticity of the coil spring 52, the card 12 is stopped together when the cam slider 51 is stopped at the initial position. Thus, it is possible to reliably prevent the cam slider 51 from jumping out toward the card insertion slot 141.

  When the card 12 is inserted into the cam slider 51 in the initial position and the notch recess 121 and the locking hook 514 are engaged, a relatively strong force against a relatively large tilt load as described above ( Insertion force) is required, which is effective in obtaining a clear click feeling. Further, when the card 12 at the connection position is directly pulled out without using the card ejection mechanism 50 (forced removal), the cam slider 51 can be tilted relatively easily because the load is smaller than the initial position. Accordingly, it is possible to safely cope with unreasonableness, and it is possible to prevent a situation in which the card connector 10 is destroyed due to unreasonableness.

  14 and 15 show a modification of the protrusion provided on the plate spring 235. In FIG. 14, the protruding portion 237 is formed by bending in an inverted V shape. Further, in FIG. 15, the protruding portion 238 is formed by reverse U-shaped bending. Further, FIG. 16 shows a modification in which a cantilevered plate spring 239 is formed on the side plate 231 of the metal shell 20 and a protruding portion 240 is provided in the vicinity of the tip. As described above, the protrusions 237, 238, and 240 make it difficult to engage and disengage the notch recess 121 of the card 12 and the locking hook 514 of the cam slider 51 at the initial position. The load against tilting can be increased at the initial position compared to the connection position.

  In the above embodiment, the box bending portions 22 and 23 are formed in the metal shell 20 and the card discharging mechanism 50 is provided in one box bending portion 23. However, the card receiving cavity as shown in FIG. Is formed in cooperation with the insulating housing 310 and the metal shell 320, and the side wall 311 of the insulating housing 310 and the metal shell 320 cooperate to support the card discharge mechanism 350 (similar to the configuration in FIG. 18). ), The same implementation is possible. That is, the plate spring 322 is provided by cutting and raising the side plate 321 of the metal shell 320, and the protrusion 324 provided on the plate spring 322 is in contact with the back surface 345 of the cam slider 341 at the initial position.

It is the perspective view of the state where the card connector of this embodiment of the invention received the card, (a) is a perspective view seen from the upper part, (b) is a perspective view seen from the lower part. It is the perspective view seen from the downward direction of the connector for cards of embodiment similarly. It is a perspective view which shows independently the metal shell which comprised the connector for cards of embodiment similarly. It is a perspective view which shows independently the card insertion guide component which comprised the connector for cards of embodiment similarly. It is a perspective view which shows the terminal support block which comprised the connector for cards of embodiment similarly in the state in which the terminal was mounted | worn. It is the expansion perspective view which cuts off and shows a part of connector for cards of embodiment similarly. It is explanatory drawing when a card | curd is inserted in the connector for cards of embodiment, and is a partially expanded perspective view showing the initial state. It is explanatory drawing when inserting a card | curd similarly, and is a partially expanded perspective view showing the overstroke state at the time of insertion. It is explanatory drawing when inserting a card | curd similarly, and is a partially expanded perspective view showing the locked state. It is explanatory drawing when removing the inserted card | curd, and is a partially expanded perspective view showing the overstroke state. It is the perspective view which expanded and showed the part which the plate-shaped spring backs up the back surface of a cam slider. It is explanatory drawing which showed the relationship between the cam slider and plate spring in an initial position. It is explanatory drawing which showed the relationship between the cam slider and plate spring in a connection position. It is explanatory drawing which shows the other example of the protrusion part provided in a plate-shaped spring. It is explanatory drawing which shows the further another example of the protrusion part provided in a plate-shaped spring. It is the perspective view which expanded and showed a part of embodiment which used the plate-shaped spring as the cantilever spring. It is a perspective view which shows the form which implemented this invention in the connector for cards in which an insulating housing and a metal shell cooperate and define a card receiving cavity. It is a disassembled perspective view showing the structure of the conventional card connector. It is explanatory drawing which shows the relationship between the cam slider and plate spring in the card connector of FIG.

Explanation of symbols

10 Card connector 12 Card-like medium (card)
121 Notch recess 122 Contact pad 123 Polarity determining corner 14 Card receiving cavity 141 Card insertion slot 20 Metal shell 21 Top plate 211 Engaging piece 212 Pressing spring 22 Box bending part 221 Side plate 222 Bottom side plate 223 Nail piece 224 Guide piece 225 Engagement window 23 Box bending portion 231 Side plate 232 Bottom side plate 233 Nail piece 234 Guide rail 235 Plate spring 236 Projection portion 237 Projection portion 238 Projection portion 239 Plate spring 240 Projection portion 24 Card insertion guide component 241 Guide piece 242 Engagement hole 243 Pin engagement Joint recess 25 Engagement piece 251 Engagement window 252 Nail piece 26 Spring piece 30 Terminal support block 31 Mounting hole 32 Engagement projection 33 Spring receiving wall 40 Terminal 41 Contact piece 42 Nail piece 50 Card discharge mechanism 51 Cam slider 511 Slide groove 512 Groove 513 Slanted wall 514 Lock hook 515 Back surface 52 Coil spring 53 Cam pin 300 Card connector 310 Insulating housing 311 Side wall 312 Terminal support 320 Metal shell 321 Side plate 322 Plate spring 323 Clearance 324 Projection 330 Card 331 Contact pad 332 Notch recess 340 Card ejection mechanism 341 Cam slider 342 Cam pin 343 Coil spring 344 Lock hook 345 Rear 350 Terminal

Claims (4)

A card connector comprising: a card receiving cavity; and a card ejecting mechanism for ejecting the card inserted into the card receiving cavity from the initial position to the back connection position to the initial position,
The card ejecting mechanism is installed on one side of the card receiving cavity, and a cam slider that slides in the card receiving cavity in the card receiving cavity together with the card;
A cam pin that engages with the cam groove of the cam slider to control the sliding of the cam slider;
In the card connector, which is a push / push type card ejecting mechanism whose main component is a spring for biasing the cam slider in the card removal direction,
The cam slider has a locking hook that engages or disengages with a notch recess formed in the side edge of the card, on the side facing the side edge of the card, On the back side, a plate-like spring that backs up the cam slider is opposed to it,
A protrusion is formed on the plate spring,
When the card is in the initial position, the protruding portion of the plate spring contacts the back surface of the locking hook, and the load when the cam slider tilts because the locking hook engages or disengages from the notch recess of the card. Is larger than when the card is in the connection position. The card receiving cavity is formed through a metal shell having a substantially square top plate facing one surface of the card, and box bending portions formed continuously on both side edges of the top plate facing each other, The card connector according to claim 1, wherein the cam slider is guided by one box bending portion, and the plate-like spring is cut and raised by a side plate constituting the box bending portion. The card receiving cavity is defined by the cooperation of an insulating housing and a metal shell, and the side wall of the insulating housing and the metal shell cooperate to support the card discharge mechanism. The card connector according to claim 1, wherein a spring is cut and raised on a side plate of the metal shell. 4. The card connector according to claim 2, wherein the plate-like spring is cut and raised on the side plate in a form of a cantilever spring or a cantilever spring, and the protruding portion is formed on one base side.

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