JP5497717B2 - Card connector - Google Patents

Description

  The present invention relates to a card connector, and more particularly to a card connector compatible with a thin card such as a micro SD card.

  In recent years, with a reduction in the thickness of a card, a reduction in the thickness of a card connector has been demanded. Generally, in a card connector, a resinous housing is used in order to electrically separate and arrange a plurality of terminals. By reducing the thickness of the bottom wall of the resin housing, the card connector is used. The thickness is reduced. Such a resin housing is molded by injecting a molten synthetic resin into a mold, filling it and solidifying it, but if you try to make it thin, it will harden before the resin spreads in the mold. It has been difficult to mold a thin housing.

  Moreover, even if the bottom wall of the housing can be formed thin with resin, sufficient strength cannot be obtained, and there is a problem that the housing is easily deformed during reflow, for example. As a card connector that solves this problem, a connector in which the entire bottom wall of the housing is formed of a thin metal plate is known (for example, see Patent Document 1). This card connector achieves thinning while ensuring sufficient strength by assembling a resin block holding a plurality of connection terminals on a metal bottom plate of the housing.

JP 2003-217713 A

  However, in the conventional card connector as described above, since the entire bottom wall of the housing is formed by a metal bottom plate, a plurality of connection terminals cannot be integrated into the housing, and the number of parts increases. At the same time, there is a problem that the assembly becomes complicated and the manufacturing cost increases.

  The present invention has been made in view of such a situation, and an object of the present invention is to provide a card connector that can be reduced in thickness while securing sufficient strength with an inexpensive configuration.

The card connector according to the present invention has a housing in which a card insertion slot is formed and a connection terminal connected to the card is embedded, a slide member that slides in the housing together with the card in the card insertion direction, A discharge spring that urges the slide member in the card discharge direction; and a lock mechanism that locks the slide member in the housing in the housing against the urging force of the discharge spring. A metal member is provided on a portion of the bottom wall of the housing where the slide member comes into sliding contact, and the thickness of the metal member is smaller than the thickness of the bottom wall of the housing, and the thickness of the bottom wall of the housing The slide of the slide member is guided.
Further, the present invention provides the card connector, wherein the metal member has a bent portion that is bent, and the bent portion of the metal member is embedded in the housing so as to follow a direction in which the slide member slides. Has been.
In the card connector according to the present invention, a side wall and a guide wall for guiding the slide of the slide member are provided in the housing, and both end portions of the metal member along the side wall and the guide wall are formed in the housing. Buried.
Further, the present invention provides the card connector, wherein the metal member has a bent portion that is bent, and the bent portion of the metal member extends along the side wall and / or along the direction in which the slide member slides. It is embedded in the guide wall.
In the card connector according to the present invention, the bent portion of the metal member is a plurality of bent portions.
Another connector for a card according to the present invention includes a housing in which a card insertion slot is formed and a connection terminal connected to the card is embedded, and a slide member that slides in the housing together with the card in the card insertion direction. A discharge spring that urges the slide member in the card ejection direction, and a lock mechanism that locks the slide member at the card mounting position in the housing against the urging force of the ejection spring. A bottom wall of the housing that is in contact with the bottom surface of the card in the housing. The thickness of the metal member is thinner than the thickness of the bottom wall of the housing,
The slide of the slide member is guided by the thickness of the bottom wall of the housing.

  According to this configuration, since the connection terminal is embedded in the bottom wall of the housing and the metal member is partially embedded, the connection terminal is separated even when the housing is thinned. In addition, the strength of the housing can be increased. Therefore, since the number of parts is not increased, the assembly can be simplified and the manufacturing cost can be reduced. In addition, when the thickness direction dimension of the entire card connector is defined by the slide member or the locking mechanism, the metal member is embedded in the portion where the slide member is in sliding contact, so that the strength can be increased by using a thin metal member. The card connector can be thinned in a state where the above is secured. Further, when the slide member is pushed down by the discharge spring while being pushed down to the bottom wall side of the housing, the slide member is pushed down by the metal member, so that deformation during reflow can be prevented. .

  In the card connector according to the present invention, the lock mechanism includes a heart cam groove formed in the slide member or the housing, and a latch pin that slides in the heart cam groove, and the heart cam groove and the latch pin It has a push-push type discharge structure that switches between locking and unlocking of the slide member in accordance with the sliding position of the slide member.

  According to this configuration, it is possible to reduce the thickness of the card connector in which the slider member has a thickness capable of forming the heart cam groove and secures the latch pin accommodating space while ensuring the strength.

  According to the present invention, in the card connector, the metal member has a ground connection portion.

  According to this configuration, static electricity generated by sliding contact between the slide and the metal member can be released to the ground. Further, when the biasing spring and the metal member are in contact, static electricity generated by the biasing spring can be released.

  In the card connector, the metal member has a ground connection portion, and the housing has a ground connection portion of the metal member passing through a region between the connection terminal and the insertion port. An extension portion extending in the direction is embedded.

  According to this configuration, noise from the insertion port can be reduced by the extension portion, and signal exchange between the card connector and the card can be stably performed via the connection terminal.

  According to the present invention, in the card connector, the extension portion has a soldering portion to be soldered on the insertion port side of the housing.

  According to this configuration, when the soldering portion is soldered, the strength on the insertion port side of the card connector can be increased, and the warpage of the card connector can be prevented.

  According to the present invention, in the card connector, the extension portion has a contact that contacts a card inserted from the insertion port on the insertion port side of the housing.

  According to this configuration, when the card is inserted, the card and the contact are brought into contact with each other on the insertion port side of the housing, so that the static electricity charged on the card can be released to the ground and the malfunction of the card can be prevented.

  In the card connector according to the present invention, the housing includes the extension portion, the connection terminal, and a switch for detecting the card mounting in the insertion direction, the extension portion, The connection terminal and the switch are separated by resin.

  According to this configuration, since the extension portion, the connection terminal, and the switch are electrically separated by the resin, an electrical malfunction of the card connector can be prevented.

  According to the present invention, a card connector having a push-push type discharging structure can be reduced in thickness while securing sufficient strength with an inexpensive configuration.

It is a figure which shows embodiment of the connector for cards which concerns on this invention, and is a perspective view of the connector for cards. It is a figure which shows embodiment of the connector for cards which concerns on this invention, and is an exploded perspective view of the connector for cards. It is a figure which shows embodiment of the connector for cards which concerns on this invention, and is a top view of a housing. It is a figure which shows embodiment of the connector for cards which concerns on this invention, and is a top view of the conductor part embed | buried under the housing. It is a figure which shows embodiment of the connector for cards which concerns on this invention, and is explanatory drawing of the mounting | wearing operation | movement of the card | curd with respect to the connector for cards. It is a figure which shows embodiment of the connector for cards which concerns on this invention, and is a top view of a card | curd.

  The card connector to which the present invention is applied is required to be thinner as the card is thinner. As such a card connector, one having a push-push type discharging structure is known. This card connector has a slide member that slides with the card in the card insertion / ejection direction, and the latch pin slides in the heart cam groove formed in the slide member, whereby the card insertion position via the slide member The discharge position is determined.

  In the push-push type card connector, a heart cam groove is formed on either the slide member or the housing, and one end of the latch pin is engaged with the wall of the cam groove to selectively lock the other end of the latch pin. It has a structure that is pivotally supported on the other member not provided with the heart cam groove. Since the latch pin is latched through the slide member and the housing, the slide member needs to have a space for accommodating the latch pin so that the latch pin does not come out. Further, in the case where the heart cam groove is provided on the slide member, it is necessary to give the slide member a thickness capable of forming a heart cam groove with a difference in height. Therefore, the dimension in the thickness direction is set according to the discharge structure. Therefore, when the push-push type card connector is thinned, it is important to reduce the thickness of the slide area in which the slide member slides on the bottom wall of the housing.

  Further, the slide member is biased in the discharge direction in a state where a part thereof is pushed down to the bottom wall side of the housing by the discharge spring. In this case, since the portion of the bottom wall of the housing that is in sliding contact with the slider is easily deformed by the depression of the slide member, it is necessary to ensure sufficient strength in this portion. The essence of the present invention is a card connector having a push-push type discharging structure, wherein the portion of the bottom wall of the housing that is in sliding contact with the slider is made of a thin metal plate, while ensuring sufficient strength and thickness reduction. Is to realize.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following, the case where the present invention is applied to a card connector for a micro SD card will be described. However, the application target of the card connector according to the present embodiment is not limited to this and can be appropriately changed.

  First, before explaining the card connector according to the embodiment of the present invention, a card to be mounted will be explained. 6A and 6B are plan views of the card according to the embodiment of the present invention, in which FIG. 6A is a top view and FIG. 6B is a side view.

  As shown in FIGS. 6A and 6B, the card 46 is a so-called micro SD card, and is formed in a substantially rectangular shape when viewed from above. One side portion of the card 46 is formed in a step shape in which the substantially half portion on the front end side in the insertion direction is narrower than the substantially half portion on the rear end side in plan view. Further, a notch 47 is partially formed on one side of the card 46, and an engaging portion 48 that engages with a slide member 6 described later is formed by the notch 47. The card 46 has a substantially constant thickness from the front end portion to the vicinity of the rear end portion, and is formed in a step shape in which the thickness increases at the rear end portion.

  The thickness of the front end portion of the card 46 is formed so as to be inserted into the insertion port 4 of the card connector 1, and the thickness of the rear end portion of the card 46 is not large enough to be inserted into the insertion port 4 of the card connector 1. Is formed. Therefore, since the card 46 is attached to the card connector 1 only when inserted from the front end side, erroneous insertion of the card 46 is prevented. A plurality of pads (not shown) that come into contact with the plurality of connection terminals 11 of the card connector 1 are provided on the back surface of the card 46 on the front end side.

  Next, the overall configuration of the card connector will be described with reference to FIGS. FIG. 1 is a perspective view of a card connector according to an embodiment of the present invention. FIG. 2 is an exploded perspective view of the card connector according to the embodiment of the present invention.

  As shown in FIGS. 1 and 2, the card connector 1 according to the present embodiment is mounted on a synthetic resin housing 2 whose upper surface and front surface are opened, and an opening on the upper surface of the housing 2 to mount a card. The housing 2 and the cover 3 are combined to form a box-like body having the insertion port 4. A plurality of connection terminals 11 are provided at the central portion of the bottom wall 2 a of the housing 2. Each connection terminal 11 provided on the bottom wall 2a extends from the central portion of the bottom wall 2a toward the back wall 2b.

  On the back wall 2b of the housing 2, a switch 5 for detecting the mounting of the card 46 is provided. The switch 5 includes a spring portion 13 that is bent from the back wall 2 b side to the insertion port 4 side, and a switch head portion 14 that is provided at the free end of the spring portion 13. A movable contact portion connected to the spring portion 13 is exposed on the lower surface of the switch head portion 14, and the movable contact portion is configured to be detachable from a fixed contact portion 15 provided on the bottom wall 2a.

  When the switch 5 is pushed into the back wall 2b side by insertion of the card 46, the switch head 14 rides on the fixed contact 15 and detects the mounting of the card 46. In this case, since the fixed contact portion 15 is inclined so as to increase from the insertion port 4 side toward the back wall 2b side, as the switch 5 is pushed into the back wall 2b side, The contact property is improved.

  One side wall 2c of the housing 2 is provided with a synthetic resin slide member 6 slidable along the side wall 2c and a coiled discharge spring 7 which expands and contracts as the slide member 6 slides. One end of the discharge spring 7 is in contact with the back wall 2b and the other end is in contact with the slide member 6, and urges the slide member 6 in the discharge direction. A guide wall 2e for guiding the slide member 6 in the insertion direction together with the side wall 2c is provided on the bottom wall 2a of the housing 2 so as to slightly protrude from the upper surface.

  A metal plate 21 is provided in the slide region of the slide member 6 formed by the guide wall 2e and the side wall 2c. The metal plate 21 extends in the sliding direction of the sliding member 6 and enhances rigidity against bending in the insertion direction of the card connector 1. The metal plate 21 is formed to be thinner than the thickness of the bottom wall 2a of the housing 2, and allows the slide member 6 to slide at a position lower than the portion of the bottom wall 2a where the card 46 is inserted. The metal plate 21 can be fitted and attached so as to close the opening of the housing 2 surrounded by the guide wall 2e and the side wall 2c, but when forming the synthetic resin housing 2, the metal plate 21 is insert-molded. It is possible to embed it integrally.

  Further, since the metal plate 21 has a lower frictional resistance than the resin material, the slide member 6 can be smoothly slid as compared with the configuration in which the metal plate 21 is slid onto the slide member 6. Further, even when the slide member 6 is urged while being pushed down to the bottom wall 2 a side of the housing 2 by the discharge spring 7, the strength of the slide region is ensured by the metal plate 21. Can be prevented.

  The slide member 6 is configured to be slidable in the insertion and discharge directions while being urged by the discharge spring 7. A heart cam groove 23 is formed on the front end side of the slide member 6, and the position of the slide member 6 is defined by the heart cam groove 23 and a latch pin 24 provided on the back wall 2b. The latch pin 24 extends along the side wall 2c, and both ends are bent at a substantially right angle toward the bottom wall 2a. One end of the latch pin 24 is rotatably supported on the back wall 2 b, and the other end is slid on the heart cam groove 23 of the slide member 6.

  The heart cam groove 23 is formed in a heart-shaped annular shape having a plurality of steps and slopes, and slides the other end of the latch pin 24 in one direction in accordance with the slide of the slide member 6. When the slide member 6 is pushed into the mounting position in the vicinity of the back wall 2b, the other end of the latch pin 24 is locked to the locking portion of the heart cam groove 23, and the return of the slide member 6 due to the bias of the discharge spring 7 is restricted. . When the slide member 6 is further pushed in from this state, the latched state of the latch pin 24 and the heart cam groove 23 is released, and the slide member 6 is returned by the urging of the discharge spring 7. Thus, the latch pin 24 and the heart cam groove 23 have a holding function at the mounting position of the slide member 6.

  In this case, the slide member 6 has a thickness that allows the heart cam groove 23 to be formed, and an accommodation space for the latch pin 24 is formed above the slide member 6. Height is required. For this reason, the thickness of the card connector 1 is designed on the basis of the slide area. However, as described above, the slide member 6 is slid at a low position by the metal plate 21, so that the card connector 1 is thinned. It becomes possible.

  Further, an engagement recess 26 that is engaged with the engagement portion 48 of the card 46 is formed on the rear end side of the slide member 6. When the engaging portion 48 of the card 46 is engaged with the engaging recess 26, the slide member 6 is slid integrally with the card 46. Further, the engagement recess 26 has a claw portion 27 that slightly protrudes toward the center of the housing 2. When the engaging portion 48 is engaged with the engaging concave portion 26, the claw portion 27 enters the cutout portion 47 of the card 46 and suppresses the card 46 from being removed in the ejection direction.

  The cover 3 is formed by bending a metallic plate material, and a pin presser 31 for pressing the latch pin 24 is formed on one side of the upper surface. The pin presser 31 is a cantilever spring cut and raised toward the bottom wall 2 a, pressing the intermediate portion of the latch pin 24 downward and pressing the other end of the latch pin 24 against the heart cam groove 23. A pair of braking pieces 32 for preventing the card 46 from popping out are formed in a substantially half portion of the upper surface of the cover 3 on the insertion port 4 side. The pair of braking pieces 32 are cantilever springs that are slightly cut and raised toward the bottom wall 2 a, and come into contact with the upper surface of the card 46 to suppress the jumping out of the card 46 when ejected.

  With reference to FIGS. 3 and 4, the housing and the conductor portion embedded in the housing will be described in detail. FIG. 3 is a top view of the housing according to the embodiment of the present invention. FIG. 4 is a top view of the conductor portion embedded in the housing according to the embodiment of the present invention.

  As shown in FIG. 3, the housing 2 has an opening corresponding to the slide region, and the substantially rectangular metal plate 21 is buried in the opening. At both ends of the metal plate 21 in the short direction, a plurality of bent portions 34 bent upward are aligned and formed so as to cut vertically between the insertion port 4 side and the back wall 2b (see FIG. 4). The plurality of bent portions 34 are embedded in the side wall 2c and the guide wall 2e, and reinforce the side wall 2c and the guide wall 2e formed around the opening of the housing 2. In embedding, the metal plate 21 is held in a mold attached to an injection molding machine, and a molten synthetic resin is injection-molded, filled in the mold, and solidified to be integrated with the housing 2. It can be manufactured by insert molding.

  A concave relief portion 35 that allows the slide member 6 to swing is formed in a substantially half portion of the side wall 2c on the insertion port 4 side. By allowing the slide member 6 to swing by the escape portion 35, the card 46 is allowed to be extracted at the ejecting position, and the card 46 is not allowed to be extracted from the mounting position. The details of the swinging motion of the slide member 6 will be described later.

  A convex portion 36 that supports one end of the discharge spring 7 is provided on the back wall 2 b of the housing 2. An opening 37 is formed below the convex portion 36 so as to avoid the metal plate 21. The opening 37 is provided with a mold for forming the convex portion 36 on the back wall 2b when the housing 2 is molded.

  As shown in FIGS. 3 and 4, the housing 2 includes a first extension 41 extending in the width direction from the insertion port 4 side of the metal plate 21, and a rear wall from the distal end side of the first extension 41. A second extension 42 extending toward 2b is embedded. The first extension 41 is disposed in a region between the plurality of connection terminals 11 and the insertion port 4, and the second extension 42 is disposed on the side of the plurality of connection terminals 11.

  That is, the first and second extending portions 41 and 42, together with the metal plate 21, extend so as to surround three sides of the plurality of connection terminals 11. With this configuration, the rigidity against bending in the insertion direction and the width direction of the card connector 1 is increased, noise from the insertion port 4 side is reduced, and the card connector 1 and the card 46 are connected via the plurality of connection terminals 11. It is possible to stabilize signal exchange.

  The first extension portion 41 is provided with a pair of soldering portions 43 that project from an intermediate portion in the extending direction toward an opening 39 formed on the insertion port 4 side of the housing 2. The pair of soldering portions 43 are connected to the ground and allow static electricity generated in the card connector 1 to escape to the ground. Further, by soldering the soldering portion 43, it is possible to increase the rigidity against bending in the width direction on the insertion port 4 side of the card connector 1 and to prevent the card connector 1 from warping.

  The first extension 41 is exposed to the insertion port 4, and a pair of contacts 44 extending from the middle part in the extending direction toward the insertion port 4 are provided. When the card 46 is inserted, the pair of contacts 44 come into contact with the front end portion of the card 46 together with the first extension portion 41 extending in the width direction, and the static electricity charged in the card 46 is passed through the soldering portion 43. Escape to the ground. In this case, since the card 46 is neutralized in two stages by the pair of contacts 44 and the first extension portion 41, a high static elimination effect can be obtained. Therefore, malfunction of the card 46 due to static electricity charged on the card 46 can be prevented.

  Furthermore, since the first extension 41 connects the metal plate 21 and the ground, the static electricity generated between the metal plate 21 and the slide member 6 is released to the ground via the soldering portion 43. Yes. Further, since the discharge spring 7 is also in contact with the metal plate 21, static electricity generated by the expansion and contraction of the discharge spring 7 is released to the ground via the soldering portion 43. As described above, since static electricity charged in the card connector 1 is also released to the ground, malfunction of the card 46 due to the static electricity charged in the card connector 1 can be prevented.

  In the housing 2 configured as described above, the first extension 41 for removing electricity from the card 46 and the card connector 1, the plurality of connection terminals 11 connected to the pads of the card 46, and the switch 5 for detecting the attachment of the card 46 are provided. Each conductor part which comprises is divided with insulating resin. Accordingly, the first extending portion 41, the connection terminal 11 and the conductor portion constituting the switch 5 are electrically separated, so that an electrical malfunction of the card connector can be prevented.

  With reference to FIG. 5, the card mounting operation with respect to the card connector will be described. FIG. 5 is an explanatory diagram of a card mounting operation with respect to the card connector according to the present embodiment.

  As shown in FIG. 5A, when the card 46 is inserted into the card connector 1, the claw portion 27 of the slide member 6 is pressed sideways by the engaging portion 48 formed on one side portion of the card 46. Is done. When the claw portion 27 of the slide member 6 is pressed by the engaging portion 48 of the card 46, the slide member 6 swings toward the escape portion 35 formed on the side wall 2c of the housing 2 with the other end of the latch pin 24 as a fulcrum. Moved.

  When the card 46 is further pushed in from the state of FIG. 5A, the engaging portion 48 of the card 46 is engaged with the engaging recess 26 of the slide member 6 at the ejection position as shown in FIG. 5B. The In this case, the claw portion 27 of the slide member 6 enters the cutout portion 47 of the card 46, and the pressure on the claw portion 27 of the slide member 6 by the engaging portion 48 of the card 46 is released. With the other end as a fulcrum, it swings from the escape portion 35 to the original position.

  At this discharge position, the slide member 6 can be swung by the escape portion 35, so that the card 46 can be removed. Specifically, when a force is applied to the card 46 in the ejection direction, the slide member 6 is swung toward the escape portion 35 with the other end of the latch pin 24 as a fulcrum. As the slide member 6 swings, the slide member 6 is detached from the notch 47 of the card 46 and the card 46 is allowed to be removed.

  When the card 46 is further pushed in from the state of FIG. 5B, the other end of the latch pin 24 is locked to the locking portion of the heart cam groove 23 as shown in FIG. 6 is held in the mounting position. At this time, the slide member 6 is guided in the insertion direction in a state where the swinging is restricted by the side wall 2c and the guide wall 2e. When the card 46 is inserted to the mounting position, the switch 5 is pushed in and the mounting of the card 46 is detected.

  In this mounting position, the swing of the slide member 6 is restricted by the side wall 2c and the guide wall 2e, and therefore the card 46 is prohibited from being extracted. Specifically, even if a force is applied to the card 46 in the ejecting direction, the swing of the slide member 6 is restricted, so that the claw portion 27 does not come off from the notch portion 47 of the card 46 and the card 46 cannot be removed. Is done. In this case, since the side wall 2c is reinforced by the plurality of bent portions 34 of the metal plate 21, deformation of the side wall 2c is strongly suppressed. Therefore, the swing of the slide member 6 is strongly restricted, and the forceful removal of the card 46 at the mounting position is prohibited.

  When the card 46 is further pushed from the state of FIG. 5C, the latched state of the latch pin 24 and the heart cam groove 23 is released, and the slide member 6 is pushed back to the discharge position by the discharge spring 7.

  As described above, according to the card connector 1 according to the present embodiment, the connection terminal 11 is embedded in the bottom wall 2a of the resin housing 2, and the metal plate 21 is partially embedded. Even when the housing 2 is thinned, the strength of the housing 2 can be increased without making the connection terminal 11 separate. Therefore, since the number of parts is not increased, it is possible to simplify the assembly and reduce the manufacturing cost. When the thickness of the entire card connector 1 is defined by the slide member 6 and the latch pin 24, the metal plate 21 is embedded in the slide area of the slide member 6, so that the card is secured in a strength state. The connector 1 can be made thin.

  In the above-described embodiment, the present invention is applied to the card connector corresponding to the micro SD card. However, the present invention is not limited to this configuration. You may make it apply to the connector for cards which can respond | correspond to a card | curd other than a micro SD card.

  In the above-described embodiment, the present invention is applied to the card connector corresponding to one type of card. However, the present invention is not limited to this configuration. The present invention may be applied to a combine-type card connector that can handle two or more types of cards and a card connector that can handle three or more types of cards.

  In the embodiment described above, the lock mechanism is configured by the heart cam groove and the latch pin of the slide member. However, the present invention is not limited to this configuration. It is good also as a structure which provides the fulcrum of a latch pin in a slide member, and provides a heart cam groove in a housing. Any configuration is possible as long as the slider member can be locked to the card mounting position.

  Further, in the above-described embodiment, the slide member is urged in the discharge direction while being pushed down to the bottom wall side of the housing by the discharge spring. However, the present invention is not limited to this configuration. Any configuration may be used as long as the slide member is biased in the discharge direction by the discharge spring, and the slide member may not be pushed down.

  In the above-described embodiment, the extension portion is provided on the metal plate. However, the present invention is not limited to this configuration. Any metal plate may be used as long as the thickness can be reduced while ensuring sufficient strength, and the extension portion may not be provided.

  In the above-described embodiment, a contact is provided in the extension and the card is neutralized by the extension and the contact. However, the present invention is not limited to this configuration. It is good also as a structure which removes a card | curd only by an extension part, without providing a contactor, and it is good also as a structure which removes a card | curd only by a contactor by exposing only a contactor.

  Further, in the above-described embodiment, the metal plate is grounded to the ground via the extension portion. However, the present invention is not limited to this configuration. The metal plate only needs to be grounded to the ground. For example, the metal plate may be directly grounded to the ground.

  The embodiment disclosed this time is illustrative in all respects and is not limited to this embodiment. The scope of the present invention is shown not by the above description of the embodiments but by the scope of the claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of the claims.

  As described above, the present invention has an effect that it is possible to reduce the thickness while securing sufficient strength with an inexpensive configuration, and in particular, for a card compatible with a thin card such as a micro SD card. Useful for connectors.

DESCRIPTION OF SYMBOLS 1 Card connector 2 Housing 3 Cover 4 Insertion slot 6 Slide member 7 Discharge spring 11 Connection terminal 21 Metal plate 23 Heart cam groove (lock mechanism)
24 Latch pin (locking mechanism)
26 Engaging concave portion 27 Claw portion 34 Bending portion 35 Escape portion 41 First extension portion (extension portion)
42 Second extension (extension)
43 Soldering part 44 Contact 46 Card

Claims (12)

A housing in which a card insertion slot is formed and a connection terminal connected to the card is embedded;
A sliding member that slides in the housing together with the card in the insertion direction of the card;
A discharge spring for urging the slide member in the card discharge direction;
A locking mechanism that locks the slide member at the mounting position of the card in the housing against the biasing force of the discharge spring;
A metal member is provided on a portion of the bottom wall of the housing where the slide member comes into sliding contact,
The thickness of the metal member is thinner than the thickness of the bottom wall of the housing,
A card connector characterized in that the slide of the slide member is guided by the thickness of the bottom wall of the housing. The metal member has a bent portion that is bent;
The card connector according to claim 1 , wherein the bent portion of the metal member is embedded in the housing so as to be along a direction in which the slide member slides. The card connector according to claim 2 , wherein the bent portion of the metal member is a plurality of bent portions. The housing is provided with a side wall and a guide wall for guiding the slide of the slide member,
The card connector according to claim 1 , wherein both end portions of the metal member along the side wall and the guide wall are embedded in the housing. The metal member has a bent portion that is bent;
The card connector according to claim 4 , wherein the bent portion of the metal member is embedded in the side wall and / or the guide wall so as to follow a direction in which the slide member slides. The card connector according to claim 5 , wherein the bent portion of the metal member is a plurality of bent portions. The metal member has a ground connection portion, and the housing is embedded with an extension portion that extends to the ground connection portion of the metal member through a region between the connection terminal and the insertion port. The card connector according to any one of claims 1 to 6 . The card connector according to claim 7 , wherein the extension portion has a soldering portion to be soldered on the insertion port side of the housing. The extension card connector according to claim 7 or claim 8 characterized in that it has a contact which contacts the card inserted from the insertion port at the insertion port side of the housing. In the housing, the extension, the connection terminal, and a switch for detecting attachment of the card are arranged in the insertion direction, and the extension, the connection terminal, and the switch are divided by resin. The card connector according to claim 7 , wherein the card connector is a card connector. The lock mechanism includes a heart cam groove formed in the slide member or the housing, and a latch pin that slides on the heart cam groove, and the locking mechanism is configured so that the slide member moves in accordance with the sliding position of the heart cam groove and the latch pin. the card connector according to any one of claims 1 to 10, characterized in that it comprises a discharge structure of push - push to switch the locking and unlocking. A housing in which a card insertion slot is formed and a connection terminal connected to the card is embedded;
A sliding member that slides in the housing together with the card in the insertion direction of the card;
A discharge spring for urging the slide member in the card discharge direction;
A locking mechanism that locks the slide member at the mounting position of the card in the housing against the biasing force of the discharge spring;
A metal member is provided on a portion of the bottom wall of the housing where the slide member comes into sliding contact,
The portion of the metal member that the sliding member is in sliding contact with is positioned lower than the height of the bottom wall facing the bottom surface of the card in the housing,
The thickness of the metal member is thinner than the thickness of the bottom wall of the housing,
A card connector characterized in that the slide of the slide member is guided by the thickness of the bottom wall of the housing.

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