JP2009231254A - Push-on/push-off mechanism and push type memory card connector using this mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a push-on/push-off mechanism in which a loss of a reverse movement prevention effect of a guide pin can be prevented and has an extended service life. <P>SOLUTION: A pin guide composing a push-on/push-off mechanism is mounted upward on a bottom surface of a housing 10. A guide pin 16 is provided downward at a free end side of a spring arm 18a made of an elastic body of which one end side is fixed on a slider 13 and is inserted into the pin guide. The spring arm 18a energizes the guide pin 16 to pressure-contact with the pin guide rising sliding surface of each groove portion on a side of an outward trip guide portion 15A and on a side of a return trip guide portion 15B in a horizontal direction. The outward trip guide portion 15A is provided a guide pin locking portion 19 on this side of an end portion of a slider 13 in a pushing-in direction. At an end portion of the slider in a pushing-in direction, there is provided a return trip side introduction portion 15Ab for introducing the guide pin 16 to a side of the return trip guide portion 15B. At a top end of the return trip side introduction portion 15Ab, there is provided a reverse movement prevention mechanism 40. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention mainly pushes the memory card in a predetermined pushing position by pushing it against the elasticity of the return spring, and pushes back by the return spring after the detent is released by pushing again. The present invention relates to a push-on / push-off mechanism (also called “momentary / alternate operation mechanism”) used for a memory card connector and a push memory card connector using the same.

  In the push-type memory card connector, a slider that reciprocates in the insertion / ejection direction of the card inserted into the memory card insertion space of the housing, a return spring that biases the slider in the card ejection direction, and the slider A push comprising a pin guide groove for pushing the card together with the card to detent the slider at the predetermined pushing position, and releasing the detent by pushing again, and a guide pin sliding in the pin guide groove. Those equipped with an on-push-off mechanism are widely used.

  As shown in FIGS. 7 and 8, the conventional push-type memory card connector has a card stopper portion 2 that receives the leading end of the card on the leading end side in the sliding direction of the slider 1, and the leading end in the sliding direction of the slider 1. A return spring tip receiving portion 3 that receives the tip of the return spring that pushes back the slider 1 is provided on the surface, a pin guide groove 4 is provided on the surface of the slider 1, and a card is provided on one side surface of the slider 1 in the sliding direction. The card lock claw 5 for temporarily fixing the card is provided.

  The pin guide groove 4 is provided with an outward guide groove 4A and a return guide groove 4B on both side surfaces of a heart-shaped heart cam 6, and both ends of the forward guide groove 4A and the return guide groove 4B are connected to each other. It has a structure.

  The tip of the guide pin 7 is inserted into such a pin guide groove 4 and circulates along the forward path guide groove 4A and the backward path guide groove 4B. The pin guide groove 4 and the guide pin 7 that slides in the pin guide groove 4 constitute a push-on / push-off mechanism 8.

  In this example, a reciprocating common groove portion 4C is provided at one junction of the forward path guide groove portion 4A and the backward path guide groove portion 4B. In order to prevent the guide pin 7 from returning backward during circulation along the forward path guide groove part 4A, the backward path guide groove part 4B, and the reciprocating common groove part 4C, the bottom surface of the forward path guide groove part 4A, the backward path guide groove part 4B, and the reciprocating common groove part 4C is The height steps 9a, 9b, 9c and 9d descending at the top are provided at four locations.

  The step portion 9a is provided so that the guide pin 7 reaching the distal end side of the forward path guide groove 4A goes to the recess 6a at the base of the heart cam 6 without returning to the forward path guide groove 4A. The step 9b is provided so that the guide pin 7 that has passed the step 9a goes to the recess 6a at the base of the heart cam 6 without returning to the step 9a side. The step portion 9 c is provided so that the guide pin 7 that goes from the recess 6 a at the base of the heart cam 6 to the return guide groove 4 B does not return to the recess 6 a at the base of the heart cam 6. The step 9d is provided so that the guide pin 7 that has entered the forward guide groove 4A and the reciprocating common groove 4C from the end of the return guide groove 4B at the tip 6b of the heart cam 6 does not return to the return guide groove 4B. .

  The guide pin 7 in the forward path guide groove 4A, the return path guide groove 4B, and the reciprocating common groove 4C is initially in the standby pin stop position a in FIG. 5 and is pushed when the memory card is inserted. By going to the pin stop position b at the end, releasing the pushing operation force at that position, going to the pin stop position c at the time of detent locking, and again by the memory card pushing operation for unlocking, that is, the off push operation When the innermost portion is pushed in, the pin stop position d is reached, and at that position, the pushing operation force of the slider is released to return to the standby pin stop position a. This is repeated every time a memory card is inserted or removed.

  That is, first, the guide pin 7 is at the standby pin stop position a at the tip of the reciprocating common groove 4C (in this position, the slider 1 is present and locked at the standby position by the bias of the return spring). I'm in. The card is inserted into the memory card insertion space of the housing, the card locking claw 5 enters into the concave portion on the side of the card, the card is temporarily fixed to the slider 1, and the card hits the card stopper portion 2 of the slider 1. When the card is further pushed in such a state, the guide pin 7 reaches the pin stop position b through the step 9a of the forward guide groove 4A, and reaches the pin stop position c through the step 9b by releasing the pushing operation force. In this state, the card and the slider 1 are pushed into the back, and the card stops at a predetermined position electrically connected to the connector. In this state, the slider 1 is locked and the return spring is in a compressed state.

When it is necessary to return the card after completion of the predetermined work, when the slider 1 is further pushed through the card, the guide pin 7 reaches the pin stop position d through the step 9c, and then the return operation guide groove is released by releasing the pushing operation force. Passes 4B, enters the forward guide groove 4A and the reciprocating common groove 4C through the step 9d, returns to the pin stop position a through the reciprocating common groove 4C (for example, Patent Document 1).
Japanese Patent Laid-Open No. 2003-317861 FIG.

  However, recent push memory card connectors have been reduced in size and thickness. In the conventional push-type memory card connector that is reduced in size and thickness, the push-on / push-off mechanism 8 including the pin guide groove 4 and the guide pin 7 that slides in the pin guide groove 4 is also reduced in size and thickness. Has been. In the pin guide groove 4 reduced in size and thickness, the stepped portions 9a, 9b, 9c, and 9d are inevitably lowered. In the conventional push-type memory card connector, the tip of the guide pin 7 slides in contact with the bottom surfaces of the forward guide groove portion 4A, the backward guide groove portion 4B and the reciprocating common groove portion 4C constituting the pin guide groove 4. There is a problem that the step portions 9a, 9b, 9c, and 9d having the height difference on the bottom surface of the groove 4 are worn and the height difference is lowered, and the effect of preventing the guide pin 7 from returning is lost. Further, the downsized and thin pin guide groove 4 has a problem in that it is difficult to make a difference in height on the bottom surface, and the push-on / push-off mechanism 8 is difficult to assemble.

  It is an object of the present invention to provide a push-type memory card connector that can prevent the effect of preventing the guide pin from reversing from being lost, can easily manufacture a pin guide groove, and can easily assemble a push-on / push-off mechanism. is there.

The feature of the invention described in claim 1 for solving the conventional problems as described above and achieving the intended object is that the slider is capable of reciprocating in a linear direction with respect to the support portion, and that the slider is moved backward. A return spring urging to the side, a guide pin supported by either the slider or the support, and a pin guide to which the guide pin slidably contacts the other, and moving the slider from the backward movement end position to the forward movement direction. When the push-in operation is performed, the guide pin moves along the pin guide, and at a position just before the forward end of the slider, the guide pin engages with a detent locking portion installed on the pin guide, and the slider moves. By depressing the slider again from the detent state, the detent is released, and the return spring is released by depressing the push operation. Therefore, in push-on push-off mechanism which is formed by a return to the backward operation end position,
The pin guide is installed on a virtual plane parallel to the reciprocating motion direction of the slider, and a pin sliding contact surface which is a rising wall surface from the virtual plane where the side surface of the guide pin abuts by the reciprocating motion of the slider The guide pin is biased in one direction by a lateral biasing means so as to abut against at least one pin sliding contact surface, on one side between both ends of the forward path guide portion and the backward path guide portion. Is provided with a back-reverse prevention mechanism that does not return in the reverse direction after the guide pin passes from one side to the other side against the horizontal lateral biasing force of the lateral biasing means. The operation causes the guide pin to circulate along the pin guide, and the pin sliding contact surface in the middle of the forward path guide portion is urged against the urging force of the return spring. Dopin in that is provided with a guide pin engaging portion to be engaged.

  According to a second aspect of the present invention, in addition to the configuration of the first aspect, the lateral biasing means includes a spring arm having a proximal end fixed to a guide pin support side of either the support portion or the slider. , A guide pin is provided in an orthogonal arrangement at the tip of the spring arm.

  According to a third aspect of the present invention, in addition to the configuration of the second aspect, the spring arm is configured by one end side of a helical spring.

  The invention according to claim 2 is characterized in that, in addition to the configuration of any one of claims 1 to 3, a guide pin is provided on the forward path guide portion when the slider moves forward. The slider abuts on the slider forward movement side from the position to prevent the slider forward movement, and the guide pin is guided to the detent locking portion by the return of the slider due to the urging force of the return spring by releasing the slider forward movement force. This is because it has a folding guidance guide portion.

  According to a fifth aspect of the present invention, in addition to the structure of any one of the first to fourth aspects, the pin guide is a concave groove formed on a surface of a support portion or a pin guide installation portion of a slider. It has a configuration with an inner rising surface.

  According to a sixth aspect of the present invention, in addition to the configuration of any one of the first to fifth aspects, the reverse return preventing mechanism includes the guide at a boundary portion between the forward path guide portion and the backward path guide portion. A stepped portion for preventing reversal of the guide pin at the bottom of the pin passing portion at the bottom of the front portion, and the guide pin at the position of the stepped portion at a position lower than the higher side of the stepped portion. It is composed of downward biasing means for biasing.

  According to a seventh aspect of the present invention, in addition to the configuration of any one of the first to fifth aspects, the reverse return prevention mechanism has a flap valve type door that opens only in the traveling direction side of the guide pin. It is in the composition.

  The feature of the invention described in claim 8 is that the slider is reciprocally slid in the insertion / ejection direction of the memory card inserted in and removed from the memory card insertion space, and the slider is attached in the ejection direction of the memory card. A return spring to be biased, a pin guide for pushing the slider together with the memory card to stop returning the slider at the predetermined pushing position, and releasing the detent by pushing again, and a guide to the pin guide And a push-on / push-off mechanism composed of a guide pin that moves in such a manner that the slider is pushed in by pushing the memory card in the pushing direction, and the memory card is ejected by pushing the slider in the pushing direction. Push type memory card In Kuta, it lies in using the push-on push-off mechanism according to any one of claims 1 to 7 as the push-on push-off mechanism.

In the push-on / push-off mechanism according to the present invention and the push-type memory card connector using the same, the pin guide is installed on a virtual plane parallel to the reciprocating direction of the slider, and the guide pin is moved by the lateral biasing means. By urging in one direction, the pin guide comes into contact with at least one pin sliding contact surface, and the pin guide is a pin sliding surface that is a rising wall surface from the virtual plane where the side surface of the guide pin comes into contact with the reciprocating motion of the slider. After the guide pin passes from one side to the other side against the horizontal lateral biasing force of the lateral biasing means on one side between both ends of the forward path guide part and the guide part. Is equipped with a back-reverse prevention mechanism that does not return in the reverse direction, so that the guide pin circulates along the pin guide by the pushing / returning operation of the slider In addition, the pin sliding contact surface in the middle of the forward path guide portion is provided with a guide pin engaging portion for locking the guide pin against the biasing force of the return spring. The side instead of the surface moves in contact with the pin slide contact surface of the pin guide, so that frictional contact at the tip of the guide pin can be eliminated or reduced. The life of the mechanism can be extended. Even if the push-on / push-off mechanism is reduced in size and thickness, the pin guide can be easily manufactured, and the push-on / push-off mechanism can be easily assembled.
Further, the lateral biasing means has a structure for biasing the guide pin in one direction by comprising a spring arm having a proximal end fixed to the guide pin support side of either the support portion or the slider. It will be easy. Further, by configuring the spring arm with one end side of the helical spring, the shape of the guide pin constituting member becomes larger than that of the conventional heart cam mechanism even when the whole is miniaturized, and the assembly becomes easy.

  Further, in the present invention, the forward guide portion has a guide pin that abuts on the slider forward movement side from the guide pin position during the forward movement of the slider to prevent the forward movement of the slider. An operation for stopping the slider at a predetermined push-in position is provided by providing a folding guide portion for guiding the guide pin to the detent locking portion by returning the slider by the biasing force of the return spring upon release. It is performed only by performing an operation of pushing to a position where it cannot be pushed at the time of pushing, and the operability is improved.

Furthermore, in the present invention, the structure of the pin guide is simplified by configuring the pin guide with a rising surface inside the concave groove formed on the surface of the support portion or the pin guide installation portion of the slider.
Further, in the present invention, the back-return prevention mechanism is for preventing back-return by lowering the traveling direction side of the guide pin on the bottom surface of the pin passing portion on the front surface of the guide portion at the boundary portion between the forward path guide portion and the return path guide portion. By configuring the step portion and the guide pin with downward biasing means for biasing the tip of the guide pin at the step portion position to a height lower than the higher side of the step portion, By configuring with a flap valve type door that opens only in the direction of travel of the guide pin, it can be configured with a simple structure.

  The best mode for carrying out the push-on / push-off mechanism and the push-type memory card connector according to the present invention will be described below in detail with reference to the illustrated embodiments.

1 to 3 show an embodiment of a push-type memory card connector using a push-on / push-off mechanism according to the present invention.
In the push-type memory card connector of this example, the housing 10 which is a support portion for supporting the slider, the card 12 inserted into the card insertion space 11 of the housing 10, and reciprocating in the insertion / ejection direction within the housing 10. The slider 13 that slides, the return spring 14 that urges the slider 13 in the ejecting direction of the card 12, and the slider 13 is pushed together with the card 12, so that the slider 13 is prevented from returning at the predetermined pushing position, and is pushed again And a push-on / push-off mechanism comprising a pin guide and a guide pin 16 for releasing the detent.

  The housing 10 includes a housing main body 10A molded by a synthetic resin material and a shield cover 10B press-molded by a metal material fitted on the upper surface thereof.

  The pin guide 15 constituting the push-on / push-off mechanism is installed upward on the bottom surface 10a of the housing body 10A, which is one of virtual planes parallel to the reciprocating direction of the slider 13, and when the slider 13 is operated in the pushing direction side. The forward path guide portion 15A on which the guide pin 16 is slid and the return path guide portion 15B on which the guide pin 16 is slid when the slider 13 is operated in the discharging direction.

  The guide pin 16 is formed integrally with the helical spring 18 in a state where the free end side of the spring arm 18a on one end side of the helical spring 18 is bent. The helical spring 18 has a spring arm 18b on the other end side fixed to the slider 13 in the sliding direction. The guide pin 16 is oriented in a direction perpendicular to the bottom surface 10a of the housing body.

  Further, the spring arm 18a constitutes a lateral biasing means, and is one direction intersecting the reciprocating direction of the slider 13 along a plane parallel to the bottom surface 10a of the housing body, in this example, the counterclockwise direction in FIG. The guide pin 16 is biased to the side. In the figure, an arrow F indicates a biasing direction.

  The forward path guide portion 15 </ b> A and the backward path guide portion 15 </ b> B constituting the pin guide are disposed substantially parallel to the reciprocating direction of the slider 13. The return path guide portion 15B is installed on the center side of the housing, and the outward path guide portion 15A is installed on the housing edge side. The guide pin 16 is attached by a spring arm 18a in a direction crossing them from the return path guide portion 15B toward the outward path guide portion 15A. It is energized.

  In the forward path guide portion 15A and the backward path guide portion 15B, the rising wall surface (side wall) on the direction side where the guide pin 16 is pressed by the urging force of the spring arm 18a constitutes a pin sliding contact surface.

  The forward path guide portion 15A is formed inside the side wall portion of the housing body 10A, and the forward path guide portion 15A is a guide pin 16 at a standby position where the slider 13 is most pushed out by the urging force of the return spring 14. The pin stop position d slightly when the innermost portion is pushed when the slider 13 is in the most pushed position when the slider 13 is pushed most from the standby pin stop position a on the start end side of the forward path guide portion 15A where the It is up to this side.

  A guide pin engaging portion 19 is formed midway in the forward guide portion 15A. The guide pin engaging portion 19 is engaged with the guide pin 16 against the urging force of the return spring 13. A portion from the standby pin stop position a to the guide pin engagement portion 19 is an on-push guide portion 15Aa, and the guide pin engagement portion 19 reciprocates the slider from the back end of the on-push guide portion 15Aa. When the guide pin 16 is pushed together with the slider 13 and pushed to the end on the back side of the on-push guide portion 15Aa, the urging force of the spring arm 18a is formed. Is moved to the guide pin engaging portion 19 side, and the pushing operation force of the slider 13 is released to move to the pin stop position c in the pin engaging portion 19 when the detent is locked, whereby the slider 13 is detented. The slider is stopped at a predetermined pushing position.

  In this example, a partition wall 21 is provided on the far side extending direction side of the on-push guide portion 15Aa with a gap larger than the thickness of the guide pin 16, and the guide pin 16 collides with the guide pin 16 during the forward movement and is guided. It is guided to the engaging portion 19 side.

  On the back side of the guide pin engaging portion 19, a return-path-side guiding portion 15Ab for shifting from the pushing-in stop state of the slider 16 to the return operation is formed. The return path guiding portion 15Ab is formed so as to be inclined toward the return path guide portion 15B, and between the innermost end portion and the return path guide portion 15B, a spring arm 18a, which is a laterally urging means, is formed. Is provided with a reverse prevention mechanism 40 that does not return from one side to the other side, that is, the forward path guide portion 15A against the horizontal lateral biasing force. The back position is the pin stop position d when the innermost portion is pushed.

  The end portion of the return path guide portion 15B on the slider return direction side has a length from the above-described standby pin stop position a to the far back side. Therefore, when the slider 13 reaches the standby position where it is most pushed out. The guide pin 16 is disengaged from the return path guide portion 15B and is moved to the forward path guide portion 15a side by the horizontal lateral biasing force of the spring arm 18a. As a result, the guide pin 16 is circulated while being in sliding contact with the forward path guide portion 15A and the backward path guide portion 15B by the reciprocating motion of the slider 13.

  As shown in FIG. 3, the reverse return preventing mechanism 40 is configured so that the return path guide portion 15 </ b> B side of the pin passage portion bottom surface 42 where the tip surface of the guide pin 16 faces is located at the boundary between the forward path guide portion 15 </ b> A and the return path guide portion 15 </ b> B. The stepped portion 41 for preventing reversion and the guide pin 16 at the position of the stepped portion 41 are provided with a downward urging means for urging the tip to a height lower than the higher side of the stepped portion. In this example, the urging means is constituted by a push-down spring portion 43 cut out and formed in the shield cover 10B, whereby the tip of the guide pin 16 is formed on the return path side constituting the step portion 41 for preventing the return. It is pushed down to a position lower than the pin passing part bottom surface 42 of the guiding part 15Ab.

  As a result, when the guide pin 16 gets over the step portion 41, the return side guide portion 15 </ b> B in which the side surface of the guide pin 16 guided from the return side guide portion 15 </ b> Ab to the return route guide portion 15 </ b> B constitutes the step portion 41. It abuts against the rising surface 41a (shown in FIG. 3) directed to the side to prevent the return to the forward path guide portion 15A side.

  The slider 13 has a slide base 24 facing in the sliding direction. The slide base 24 has one parallel guide surface 24a and another parallel guide surface 24b parallel to each other on both sides parallel to the slide direction. I have.

Further, the slide base 24 has a card stopper portion 25 that protrudes on the side of one parallel guide surface 24a on the tip end side in the slide direction and receives the tip end of the card 12, and the other on the tip end side in the slide direction of the slide base 24. A holder portion 26 having a return spring receiving portion 26b for holding the winding core portion 18c of the helical spring 18 projecting on the side of the parallel guide surface 24b and receiving the tip of the return spring 14, and a slide base 24 is provided. The other end side spring arm fixing part 27 which fixes the spring arm 18b of the other end side of the helical spring 18 toward the sliding direction of the slider 13 is provided.
The winding core portion 18 c of the helical spring 18 is fitted and supported by a core portion supporting portion 26 a formed by a protrusion of the holder portion 26. The other end-side spring arm fixing portion 27 is formed by groove portions 27a provided in the sliding direction on the surface of the slide base 24, and support protrusions 27b that protrude alternately on both side walls of the groove portions 27a. The spring arm 18b on the other end side is inserted into the groove 27a, and the side surfaces are alternately pushed and fixed by the alternate support protrusions 27b.

  The helical spring 18 is held with its winding core portion 18c fitted into the core portion supporting portion 26a of the holder portion 26, and the distal end side of the guide pin 16 provided on the spring arm 18a on one end side is the pin of the housing body 10A. The side surface of the guide pin 16 inserted into the guide 15 is in pressure contact with the pin guide rising slide surface of the pin guide by the biasing force of the spring arm 18a on one end side.

  In the housing main body 10A, one parallel guide portion 28 for guiding the card insertion space 11 for inserting the card 12 and one parallel guide surface 24a and the other parallel guide surface 24b of the slide base 24 of the slider 13 are respectively provided. A parallel guide portion 29, a proximal end stopper portion 30 for contacting the proximal end portion of the slide base 24 by the biasing force of the return spring 14 in a standby state, and a return spring receiving portion 32 for receiving the proximal end of the return spring 14. It has been.

  Next, the operation of the guide pin 16 in the pin guide constituting the push-on / push-off mechanism in such a push-type memory card connector will be described together with the operation of the card and the slider with reference to FIGS. To do.

  In an initial state where the card 12 is not inserted into the card insertion space 11 of the housing, the slider 13 is in the standby position where it is most pushed out by the return spring 14 as shown in FIG. The guide portion 15A is located at the standby pin stop position a of the base end portion of the on-push guide portion 15Aa and is pressed against the guide portion 15Aa by the urging force of the spring arm 18a.

  From this state, when the card 12 is inserted and pushed into the card insertion space 11, the slider 13 is moved in the pushing direction. At this time, the guide pin 16 moves while being in sliding contact with the on-push guide portion 15Aa. When the guide pin 16 moves to the tip end portion, the guide pin 16 is moved to the back side of the guide pin engaging portion 19 by the urging force of the spring arm 18a.

  In this state, when the pushing force of the slider 13 by the card 12 is released, the guide pin 16 is pushed together with the slider 13 by the return spring 14 in the return direction, but the guide pin 16 is engaged with the guide pin engaging portion 19. At the time of locking, the pin stops position c is entered and the return is prevented, whereby the slider 13 is stopped at a predetermined pushing position. At this time, the card 12 is pushed into the card insertion space 11 and the terminal is electrically connected to a contact spring provided in the housing 10 (not shown).

  When the card 12 inserted in this way is taken out, the guide pin 16 is brought into sliding contact with the return path guiding portion 15Ab by the operation of pushing the inserted card 12 again, that is, by an off-push operation, and reaches the reverse return prevention mechanism 40. Then, it passes through this, enters the return path guide portion 15B, and stops at the pin stop position d when the innermost portion is pushed.

  Thereafter, when the pushing force against the card 12 is released, the slider 13 is moved in the pushing direction by the return spring 14, and the guide pin 16 is not returned to the forward path guide portion 15A by the return prevention mechanism 40, but is slid to the backward path guide portion 15B. The slider 13 returns to the standby position without being prevented from returning, and the card 12 is pushed out at the same time. Since the return path guide portion 15B is interrupted while returning to the standby position, the guide pin 16 moves to the forward path guide portion 15A by the urging force of the spring arm 18a, stops at the standby pin stop position a, and returns to the initial state.

In the reverse rotation preventing mechanism in the above embodiment, the inclined surface is provided on the forward path guide portion 15A side, but the present invention is not limited to this, and the bottom surface of the backward path guide portion 15B is lower than the bottom surface of the backward path guide portion 15Ab. By doing so, you may form the step part 41 for reversal prevention. In this way, the length of the return path guide portion 15B is long to some extent, and if the bottom surface is gradually raised and returned to the flat surface, the groove is sharpened at the tip of the guide pin 16 rather than the one where the bottom surface of the groove is steep. Can be prevented. Further, since the bottom surface and the tip of the guide pin 16 are in sliding contact, the card is prevented from popping out.
Further, the guide pin 16 is pushed downward by the push-down spring 42 so as to drop the guide pin 16 toward the return path guide portion 15B. However, the guide pin 16 is elastic by the inclination of the step portion 41 for preventing the return. It is only necessary to be energized so as to fall into the return path guide groove 15B by passing through the step portion 41 after being lifted up, and the elasticity of the spring arm of the guide pin 16 can be used instead of the spring portion 10b for pushing down. May be used. In this case, the guide pin 16 can be elastically held at a position where the tip of the guide pin 16 is not in contact with the bottom of the return path guide groove 15B in a free state.

  In addition to the structure using the step portion 41 and the push-down spring portion 42 described above, the back-return prevention mechanism 40 is non-returned at a position connected to the return guide portion 15B at the tip of the forward guide portion 15A as shown in FIG. The structure which installed the door 45 may be sufficient. This non-return door 45 has a flap-type non-return valve shape constituted by a leaf spring. That is, one end of the non-return door 45 is embedded and fixed at the edge of the opening portion of the forward guide portion 15A to the return guide portion 15B opposite to the guide pin pushing direction side, and the other end of the non-return door 45 is fixed. The side is in contact with the stepped portion of the shape recessed from the return path guide groove 15B side at the edge of the opening on the guide pin pushing direction side.

When the guide pin 16 goes from the outward guide groove 15A side to the return guide portion 15B, the guide pin 16 pushes the check door 45 to open the door, and the guide pin 16 enters the return guide groove 15B. By moving and passing through the position of the non-return door 45, the non-return door 45 is closed by the elasticity of the leaf spring, and the guide pin 16 is prevented from returning into the forward path guide groove 15A.
Furthermore, the reverse prevention mechanism 40 may use a non-reversible one-way revolving door 47 as shown in FIG. 6 instead of the flap type non-return door. In this case, the return door 47 is temporarily set by rotating the rotary door 47 so that the guide pin 16 can rotate only in a direction in which the guide pin 16 can pass from the tip of the forward guide 15A toward the return guide 15B. The guide pin 16 that has moved to the side is prevented from returning into the forward path guide portion 15 </ b> A by the one-way rotating door 47.
Furthermore, in the above-described embodiment, the forward path guiding portion 15Ab of the forward path guide portion 15A is inclined toward the backward path guide portion 15B side. However, as shown in FIG. 15Ba may be provided, and the front end of the return path guide portion 15Ab of the forward path guide portion 15A may be continued through the reverse prevention mechanism 40.

  Further, in the above embodiment, the horizontal flat partition wall 21 is used. Instead, as shown in FIG. 7, the semicircular shape for introducing the guide pin 16 into the guide pin engaging portion 19 is used. The guide guide engaging portion 19 may be formed in a semicircular shape by providing the turn-up guide portion 21a, and the tip of the on-bush guide portion 51Aa being inserted into the semicircular open portion.

  By doing so, the guide pin 16 is turned from the standby pin stop position a before it reaches the detent locking pin stop position c engaged with the guide pin engaging portion 19, and the semicircular shape of the guide guide portion 21 a is turned back. On-push operation end pin stop position b in the innermost part of the shape is reached, and the push-in operation is prevented.

  As a result, the operator can recognize the completion of the predetermined push-in operation, and after that, by releasing the push-in operation force, the slider 13 is returned to the return spring 14 so that the guide pin 16 is turned back and guided by the guide portion 21a. And is engaged with the guide pin engaging portion 19.

  Further, in the above-described embodiment, the case where the pin guide is molded into a shape rising from the flat surface is shown, but it may be formed by forming a concave groove on the flat surface as shown in FIG. . In FIG. 8, parts having the same functions as those in the above embodiment are given the same reference numerals, and redundant description is omitted.

  Further, each of the above embodiments shows the case where the pin guide is provided on the housing 10 side and the guide pin 16 is provided on the slider 13 side. However, as shown in FIG. On the side, a guide pin 16 may be provided on the housing 10 side. In this case, the pin guide is reversely arranged in the front-rear direction. Also in FIG. 9, parts having the same functions as those in the above embodiment are given the same reference numerals, and redundant description is omitted.

  Further, although not shown in the drawing, the urging direction of the guide pin 16 by the spring arm 18a may be the clockwise direction opposite to the above-described example, and in this case, the arrangement of the pin guide is reversed left and right. It becomes arrangement of.

Further, in any of the above-described examples, the pin guide is a reversal in which the guide pin 16 does not return to the forward guide portion side at a position slightly in front of the pin stop position d when the innermost portion is pushed when the slider 13 is pushed most. Although the prevention mechanism 40 is provided, the present invention is not limited to this, and as shown in FIG. 10, the guide pin biasing direction by the spring arm 18a is the clockwise direction in FIG. A return prevention mechanism 40 is provided at a position slightly before returning from the operating position to the standby position, that is, the guide pin 16 moves in the return direction along the return path guide portion 15B and reaches the standby pin stop position a of the forward path guide portion 15A. When the slider is pushed in, the forward guide portion 15A is turned back without returning to the backward guide portion 15B. A structure to be pushed to the end stop position b may be.
In FIG. 10, the same reference numerals are given to the same functional portions as those in the above-described embodiment, and the description thereof will be omitted.

1 is a plan view showing a state in which an internal structure is disclosed by removing a top plate of a housing in an embodiment of a push-type memory card connector using a push-on / push-off mechanism according to the present invention. It is a disassembled perspective view which shows the slider and housing which are used in the present Example shown in FIG. FIG. 2 is an enlarged cross-sectional view of a portion for preventing a reverse rotation in the embodiment shown in FIG. It is a top view which shows the operation | movement process of the guide pin which slides along the pin guide provided in the housing of the Example shown in FIG. It is a fragmentary top view which shows the other example of the reverse prevention mechanism in the push-on / push-off mechanism which concerns on this invention. It is a partial top view which shows the further another example of the reverse return prevention mechanism in the push-on / push-off mechanism which concerns on this invention. It is a partial top view which shows the further another example of the reverse return prevention mechanism in the push-on / push-off mechanism which concerns on this invention. It is a partial top view which shows the further another example of the reverse return prevention mechanism in the push-on / push-off mechanism which concerns on this invention. It is a partial top view which shows the further another example of the reverse return prevention mechanism in the push-on / push-off mechanism which concerns on this invention. It is a partial top view which shows the further another example of the reverse return prevention mechanism in the push-on / push-off mechanism which concerns on this invention. It is a top view of the state which removed the top plate of the housing of the conventional push-type memory card connector, and disclosed the internal structure. It is the principal part enlarged view of the pin guide centering on the heart cam of the slider used with the conventional push-type memory card connector.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Housing 10A Housing main body 10B Shield cover 10a Bottom face 11 Card insertion space 12 Card 13 Slider 14 Return spring 15 Pin guide 15A Outward guide part 15Aa On-push guide part 15Ab Return side guide part 15B Inward part guide part 15Ba Inclined part 16 Guide pin 18 Winding spring 18a Spring arm 18b on one end side Spring arm 18c on the other end side Winding core portion 19 Guide pin engaging portion 21 Partition wall 21a Folding guide guide portion 24 Slide base 24a One parallel guide surface 24b The other parallel guide surface 25 Card stopper portion 25a Reinforcing plate portion 26 Holder portion 26a Core portion supporting portion 26b Return spring receiving portion 27 Other end side spring arm fixing portion 27a Groove portion 27b Support projection 28 One parallel guide portion 29 The other parallel guide portion 29a The other parallel guide Base end side portion 30 Base end stopper portion 32 Return spring receiving portion 40 Reverse return prevention mechanism 41 Step portion 42 for preventing reverse return Pin passage portion bottom surface 43 Spring portion 45 for pushing down Non-return door 47 One-way rotary door a Standby Pin stop position b Pin stop position c at the end of on-push operation Pin stop position d when detent is locked Pin stop position when the innermost part is pushed

Claims (8)

A slider that can freely reciprocate in a linear direction with respect to the support portion, a return spring that urges the slider toward the backward movement side, a guide pin that is supported by either the slider or the support portion, and the guide pin that is provided on the other side The guide pin is moved along the pin guide by pushing the slider in the forward movement direction from the backward movement end position, and the guide is moved at a position before the forward movement end of the slider. The pin engages with the detent locking portion installed on the pin guide, and the slider is detented. By depressing the slider again from the detent state, the detent is released and the push operation is released. In the push-on / push-off mechanism configured to return to the return operation end position by the return spring,
The pin guide is installed on a virtual plane parallel to the reciprocating motion direction of the slider, and a pin sliding contact surface which is a rising wall surface from the virtual plane where the side surface of the guide pin abuts by the reciprocating motion of the slider Composed of
The guide pin abuts on at least one pin sliding contact surface by being urged in one direction by a lateral urging means,
On one side between both ends of the forward path guide part and the backward path guide part, the guide pin passes from one side to the other side in the opposite direction against the horizontal lateral biasing force of the lateral biasing means. By providing a back-reverse prevention mechanism that does not return, the guide pin circulates along the pin guide by the pushing / returning operation of the slider,
Push-on-push, characterized in that the pin sliding contact surface in the middle of the forward path guide portion is provided with a guide pin engaging portion for locking the guide pin against the urging force of the return spring. Off mechanism.   2. The lateral biasing means comprises a spring arm having a base end fixed to a guide pin support side of either the support portion or the slider, and a guide pin is provided at a distal end of the spring arm in an orthogonal arrangement. The described push-on / push-off mechanism. The push-type memory card connector according to claim 2, wherein the spring arm has one end side of a helical spring.   In the forward path guide portion, a guide pin abuts on the slider forward movement side from the guide pin position during the forward movement of the slider to prevent the forward movement of the slider, and the return spring of the slider is released by releasing the forward movement force of the slider. The push-on / push-off mechanism according to any one of claims 1 to 3, further comprising a folding guide portion for guiding the guide pin to the detent locking portion by returning the slider by an urging force.   5. The push-on / push-off mechanism according to claim 1, wherein the pin guide has a rising surface inside a concave groove formed on a surface of a support portion or a pin guide installation portion of a slider.   The reversion preventing mechanism includes a step portion for preventing reversion, in which the guide pin has a lower traveling direction on the bottom surface of the pin passing portion on the front surface of the guide portion at a boundary portion between the forward path guide portion and the return path guide portion, and the guide The push-on / push-off according to any one of claims 1 to 5, wherein the pin has a downward urging means that urges the pin at a position of the step portion to a height lower than a higher side of the step portion. mechanism.   6. The push-on / push-off mechanism according to claim 1, wherein the reverse-return prevention mechanism includes a flap valve type door that opens only on a traveling direction side of the guide pin.   A slider which is reciprocally slid in the insertion / ejection direction of the memory card inserted in and removed from the memory card insertion space in the housing, a return spring which biases the slider in the ejection direction of the memory card, and the slider Push-on that consists of a pin guide that detents the slider at its predetermined depressing position by pushing it together with the card, and a guide pin that moves while being guided by the pin guide to release the detent by pushing again. And a push-off mechanism, wherein the slider is pushed in by pushing the memory card in the pushing direction, and the memory card is ejected by pushing the slider in the pushing direction. -Push type memory card connector comprising a characterized by using the push-on push-off mechanism according to any one of claims 1 to 7 as a push-off mechanism.

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