JP2004288466A - Socket for memory card - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a socket for a memory card in which popping out of the memory card can be prevented and no operation failure occurs. <P>SOLUTION: The socket is constituted by providing an elastic contact 23 to a housing 3, which is brought into an elastic contact with a surface along the direction that an injecting member is slid to a housing 3 when the ejecting member is pushed into a retaining position, where at least the contact terminal of the memory card MC and a contact are brought into contact with each other. Thus, with the frictional force due to contact pressure of the elastic contact part 23 and the ejecting member reducing the popping out force of the memory card MC, the memory card MC can be prevented from popping out. Furthermore, since the ejecting member does not receive any frictional force from the elastic contact 23 in a position which is shallower than the contact position, no operation failure occurs. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a memory card socket for connecting a memory card such as an SD memory card so as to be freely inserted and removed.
[0002]
[Prior art]
Conventionally, as a memory card socket of this type, a memory card has a housing in which a memory card is slidably inserted and removed and a plurality of contacts that contact a connection terminal provided on the memory card, and a memory card inserted in the housing. An ejection member that abuts against the housing and slides against the housing, a biasing spring that biases the ejection member against the housing in a sliding direction when the memory card is removed, and a push-on / push-off type. There is provided a device having a lock mechanism (see, for example, Patent Document 1).
[0003]
When connecting a memory card to a memory card socket provided with a push-on / push-off type locking mechanism as described above, the memory card is inserted into the housing and pushed in. Then, when the ejecting member receives a pressing force via the memory card and the connection terminal of the memory card moves to a lock position slightly deeper than the holding position where it contacts the contact, the ejection direction of the memory card from the holding position is changed. The movement of the eject member with respect to the housing is prohibited by the lock mechanism, and the memory card remains at the holding position even after the pressing force on the memory card is removed. To remove the memory card, push the memory card a little again and then remove the pressing force on the memory card. Then, the prohibition of the movement to the eject member by the lock mechanism is released, and the memory card is pushed out of the housing by receiving the spring force of the urging spring via the eject member.
[0004]
[Patent Document 1]
Patent No. 3252133 (Pages 3-4, Fig. 6)
[0005]
[Problems to be solved by the invention]
However, in the memory card socket having the above-described lock mechanism, there is a risk that the memory card will pop out vigorously when trying to remove the memory card, and may fall and be damaged. Here, if the spring force of the biasing spring is reduced to prevent the memory card from jumping out, the spring force of the biasing spring causes the friction due to the contact pressure of the contact before the memory card separates from the contact in the process of pushing the memory card. Therefore, the spring force of the biasing spring cannot be reduced because the memory card may be weaker than the force and an operation failure that the memory card stops halfway may occur.
[0006]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a memory card socket that can prevent a memory card from jumping out and that does not cause a malfunction.
[0007]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided a housing in which a memory card is slid and inserted and which holds a plurality of contacts for contacting connection terminals provided on the memory card, and a pressing force which comes into contact with the memory card inserted in the housing. Receiving member that slides with respect to the housing, a biasing spring that biases the ejecting member against the housing in a sliding direction when the memory card is pulled out, and a holding position where the connection terminal of the memory card contacts the contact. When the eject member is pushed into the lock position further back, the movement of the eject member with respect to the housing in the direction of pulling out the memory card from the holding position is prohibited, and thereafter, once the pressing force on the eject member is once removed, the eject A lock mechanism for releasing the prohibition when the eject member is pushed in, When the ejecting member is pushed in only to a position less than the contact position where the connection terminal of the memory card inserted into the housing starts to contact the contact, the ejecting member does not contact either of the ejecting member and the memory card, and the ejecting member is held at least. When the housing is pushed to the position, the housing is provided with an elastic contact portion which elastically contacts a surface of at least one of the eject member and the memory card along a direction in which the housing slides.
[0008]
According to a second aspect of the present invention, in the first aspect of the present invention, the elastic contact portion is provided at a position in contact with only the eject member.
[0009]
According to a third aspect of the present invention, in the first aspect, the housing is made of a material having elasticity, and the elastic contact portion is formed integrally with the housing.
[0010]
According to a fourth aspect of the present invention, in the third aspect of the present invention, the elastic contact portion is formed by cutting and raising a part of the housing into a space in which the memory card and the eject member slide.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0012]
(Embodiment 1)
As shown in FIG. 1, the present embodiment includes a housing 3 which has a substantially rectangular parallelepiped shape which is flattened up and down, and has a memory card insertion opening 42 into which a memory card MC is inserted and withdrawn and which is open at the front. Hereinafter, the direction in which the memory card MC is extracted is referred to as the front, and the upper, lower, left, and right directions are based on FIG.
[0013]
The memory card MC used in the present embodiment is an SD memory card, which has a substantially rectangular outer peripheral shape, and has a notch 27 for preventing reverse insertion by dropping a right rear corner. A plurality of (not shown, nine in the case of SD memory) connection terminals (not shown) are provided on the lower surface of the memory card MC side by side. Further, a lock notch 37 which is depressed in a rectangular shape is provided on the right edge of the memory card MC. Further, stepped portions 19 are formed on both left and right side portions on the lower surface side of the memory card MC so that the width on the lower surface side is smaller than the width on the upper surface side. On the left side edge of the memory card MC, there is provided a write protect switch SW which can be manually slid back and forth to switch between data write enable / disable.
[0014]
As shown in FIG. 2, the housing 3 has a base shell 1 formed by punching and bending a thin stainless steel plate, and a base formed by punching and bending a thin stainless steel plate similarly to the base shell 1. And a cover shell 2 attached to the upper side of the shell 1. Inside the housing 3, a contact block 4 having a plurality of contacts 10 that are in contact with connection terminals of the memory card MC is held. On the front side of the contact block 4, an eject member 5 that can slide back and forth in the housing 3 is housed. Coil springs 13 as urging springs for urging the eject member 5 forward are held at both left and right ends inside the housing 3.
[0015]
More specifically, the contact block 4 includes a base 7 made of a synthetic resin molded product and arranged at the rear end of the housing 3. On the base 7, each contact 10, a pair of switch pieces 30a and 30b for recognition of insertion of the memory card MC, and a pair of switch pieces 31a and 31b for position detection of the write protect switch SW of the memory card MC are respectively provided. It is held side by side by insert molding so as to protrude forward and backward of the base 7. Each of the contacts 10 and the switch pieces 30a, 30b, 31a, and 31b has a portion protruding backward from the base 7 connected to an external circuit, and a portion protruding forward from the base 7 contacting the memory card MC.
[0016]
The base shell 1 has a bottom plate 12 and side walls 6a and 6b protruding left and right of the bottom plate 12. Projecting pieces 18 for preventing the ejection member 5 from dropping out of the memory card insertion opening 42 are respectively provided at the front ends of the left and right ends of the bottom plate 12 so as to protrude upward. Here, the distance between the lower ends of the left and right projecting pieces 18 is larger than the left and right widths of the portion below the step 19 of the memory card MC and is higher than the step 19 of the memory card MC. The width is smaller than the left and right widths of the part, so that when the memory card MC is inserted upside down, the projecting piece 18 is caught. At the rear end of the bottom plate 12, a plurality (four in the figure) of connecting pieces 9 are formed by cutting and raising, which are arranged side by side and protrude upward from the bottom plate 12, respectively. A through-hole 8 corresponding to the coupling piece 9 of the base shell 2 is vertically formed in the base 7 of the contact block 4. The coupling piece 9 is press-fitted into the through-hole 8 of the contact block 4, whereby the base shell 7 is pressed. 1 and the contact block 4 are connected. The switch pieces 31a and 31b of the bottom plate 12 correspond to the switch pieces 31a and 31b of the bottom plate 12 so that the switch pieces 31a and 31b for detecting the position of the write protection switch SW and the contact 10 do not come into contact with the bottom plate 12 when pressed down by the memory card MC. Escape holes 11 are vertically provided at the position and the position corresponding to each contact 10, respectively. Furthermore, when it is necessary to insulate the housing 3 from other components disposed below the housing 3 in the device using the present embodiment, an insulating tape 80 is attached to the lower surface of the bottom plate 12.
[0017]
The cover shell 2 includes a top plate 21 and side walls 20 vertically provided on the left and right of the top plate 21. At the left and right ends of the top plate 21, two slits 24 are provided side by side. Each of the left and right portions of the top plate 21 sandwiched by the slits 24 is provided with a holding piece 25 that is bent so that an intermediate portion in the front-rear direction projects downward and presses the memory card MC against the eject member 5. I have. A plurality of connecting pieces (not shown) are formed at the rear end of the top plate 21 so as to be arranged side by side and project downward from the top plate 21. A plurality of (three in the figure) through-holes 22 corresponding to the connecting pieces of the cover shell 2 are vertically provided in the base 7 of the contact block 4, and the connecting pieces are inserted into the through-holes 8 of the contact block 4. The cover shell 2 and the contact block 4 are connected by being press-fitted. Further, a plurality of (three in the figure) coupling projections 40 formed by cutting and raising and projecting inward are provided on each side wall 20 side by side. Here, a coupling hole 41 is provided on each of the side walls 6a and 6b of the base shell 1, and the cover shell 2 and the base shell 1 are coupled by engaging the coupling protrusion 40 with the coupling hole 41. .
[0018]
The eject member 5 includes a main portion 5a that is long in the left and right and abuts on the rear end of the memory card MC, and two arms 5b and 5c extending forward from the left and right ends of the main portion 5a, respectively. It is a synthetic resin molded product formed in a U-shape as a whole. At the right end of the main portion 5a, an overhang portion 5d that comes into contact with the cutout portion 27 of the memory card MC is provided. When trying to insert the memory card MC in the wrong direction, the error can be recognized by the feeling that the overhang 5d is caught. In addition, a groove 33 for projecting the contact 10 forward when the eject member 5 is pushed in is provided on the lower surface of the main portion 5a.
[0019]
The arms 5b and 5c guide the left and right sides of the memory card MC. On the inner surfaces of the arms 5b and 5c, steps 50 on which the steps 19 of the memory card MC are mounted are provided. Is provided. Also, an inclined surface 34 is provided on the inner surface of the front end of each of the arms 5b, 5c to increase the space between the arms 5b, 5c toward the front.
[0020]
At the rear ends of the arms 5b and 5c of the eject member 5, grooves (not shown) into which one ends of the coil springs 13 are inserted are provided. The other end of each coil spring 13 is attached to the base shell 1 via a spring seat 100, respectively. The spring seat pieces 100 are respectively provided at the rear ends of the side walls 6a and 6b of the base shell 1 and the buckling prevention needles 101 inserted into the coil spring 13 from the rear to prevent the buckling of the coil spring 13. It has a mounting piece 102 that is unevenly coupled to the coupling holes 110a and 110b, respectively.
[0021]
Here, the cover shell 2 is provided with a lock piece 26 whose rear end is integrated with the right rear end of the top plate 21 and whose front end can be bent left and right. At the middle of the lock piece 26 in the front-rear direction, there is provided a step 26a for projecting the front part of the lock piece 26 to the left from the rear part. At the front end of the lock piece 26, a lock claw 26b projecting leftward is formed by bending. On the upper surface of the eject member 5, there are formed concave portions 200 which are respectively released behind the right end of the main portion 5a and left and right of the right arm portion 5c and in which the lock pieces 26 are stored. In a state where the memory card MC is not inserted, the left surface of the portion of the lock piece 26 on the front side of the stepped portion 26a elastically contacts the rear side of the left opening of the right arm 5c, so that the lock piece 26 is locked with the lock claw. 26b is regulated so as to be housed in the concave portion 200. When the eject member 5 moves to a predetermined position with the insertion of the memory card MC, the left surface of the portion of the lock piece 26 behind the step 26a elastically contacts the rear side of the left opening of the right arm 5c, The portion of the lock piece 26 on the front side of the step portion 26a fits into the left opening of the right arm portion 5c. Here, the locking claw 26b projects to the left from the right arm 5c and engages with the locking notch 37 of the memory card MC, thereby preventing the memory card MC from dropping from the ejection member 5.
[0022]
Further, a guide groove 15 is provided on the right side surface of the right arm portion 5c, and a heart cam 15a is formed by being surrounded by the guide groove 15. Here, on the right side walls 6a, 6b of the base shell 1, an L-shaped piece 14 is cut and raised to the left. The L-shaped piece 14 is provided with a bearing hole 14b extending right and left. One end of a guide pin 16 whose both ends are bent at substantially right angles to the same side is inserted into the bearing hole 14b, and the other end is engaged with the guide groove 15. The guide pin 16 is ejected when one end (hereinafter, referred to as “fixed end 16a”) is supported by the bearing hole 14b and the other end (hereinafter, referred to as “free end 16b”) is guided by the guide groove 15. The member 5 rotates about the fixed end 16a as the member 5 slides.
[0023]
The operation of the guide pins 16 when inserting and removing the memory card MC will be described with reference to FIG. When the memory card MC is not inserted, the front ends of the arms 5a and 5b of the eject member 5 are in contact with the projecting pieces 18 of the base shell 1, and the free ends 16b of the guide pins 16 are the rear ends of the guide grooves 15. It is located in part a. When the memory card MC is inserted into the memory card insertion slot 42 of the housing 1 in a correct direction and pushed in, the eject member 5 receives the pressing force and slides backward through the memory card MC. At this time, the free end 16b of the guide pin 16 is guided by the upper surface of the heart cam 15a and passes through the upper part B of the heart cam 15a. When the memory card MC is further pushed in, the free end 16b of the guide pin 16 reaches the front end d of the guide groove 15, and the free end 16b abuts on the front end of the guide groove 15, so that the further entry of the eject member 5 is prohibited. Is done. The front end d of the guide groove 15 is located in front of a recess 15d provided on the front surface of the heart cam 15a, and when the free end 16b of the guide pin 16 is located here, the pressing force against the memory card MC is reduced. When removed, the ejecting member 5 is pushed back by the spring force of the coil spring 13, and the free end 16b of the guide pin 16 enters the recess 15d of the heart cam 15a. Here, when the free end 16b of the guide pin 16 contacts the heart cam 15a, the forward movement of the eject member 5 is prohibited. In this state, the connection terminal of the memory card MC is in contact with the contact 10. That is, the guide pin 16, the guide groove 15, and the bearing hole 14b of the L-shaped piece 14 of the base shell 1 constitute a lock mechanism. The position of the eject member 5 in which the free end 16b of the guide pin 16 is located at the front end d of the guide groove 15 is the lock position, and the eject member in a state in which the free end 16b of the guide pin 16 enters the recess 15d of the heart cam 15a. The position 5 is the holding position. Further, in this state, the upper one of the switch pieces 30a, 30b for insertion recognition of the memory card MC is pushed down by the ejecting member 5, and the two switch pieces 30a, 30b come into contact with each other, so that the memory is removed. The insertion of the card MC is recognized. Further, whether or not the write-inhibited state is recognized is determined by whether or not the switch pieces 31a and 31b for detecting the position of the write protect switch SW of the memory card MC are in contact with each other.
[0024]
To remove the memory card MC, first push the memory card MC. Then, the free end 16b of the guide pin 16 is guided by the front end of the guide groove 15 in front of the heart cam 15a, and moves to the front lower side of the heart cam 15a. Here, when the pressing force on the memory card MC is removed, the eject member 5 is pushed back by the spring force of the coil spring 13, so that the free end 16 b of the guide pin 16 passes through the lower side C of the heart cam 15 a and the guide groove 15 Return to back end a. Here, the guide groove 15 is branched into one portion near the rear end of the heart cam 15a and two upper and lower portions near the front end of the heart cam 15a. In order to prevent the free end 16b of the guide pin 16 from entering an erroneous path different from the above-mentioned correct path, a depth dimension to the erroneous path is provided on the bottom surface near each branch of the guide groove 15. A step 15c is provided to make the depth smaller than the depth to the correct course, and the free end 16b of the guide pin 16 is formed on the bottom surface of the guide groove 15 by the elasticity of the pressing piece 17 cut and raised on the right side wall 6a of the base shell 1. It is designed to be in contact with
[0025]
Here, as shown in FIGS. 2 and 4, a plurality of elastic contact portions 23 formed by being cut and raised downward are provided at the rear end of the top plate 21 of the cover shell 2. Each elastic contact portion 23 is inclined so that the size of the protrusion toward the inside of the housing 3 increases toward the rear end. The elastic contact portion 23 moves from a predetermined position (hereinafter, referred to as a “resistance generating position”) between a contact position where the connection terminal of the memory card MC and the contact 10 come into contact with each other and a forward position of the eject member 5. The ejection member 5 is elastically contacted to the stop position where the movement is prohibited, and the ejection member 5 is pressed against the upper surface of the base shell 1. Further, the elastic contact portion 23 is separated from the memory card insertion opening 46 to such an extent that the memory card MC does not come into contact even when the eject member 5 reaches the stop position. That is, the elastic contact portion 23 is provided at a position in contact with only the eject member 5, and does not contact the memory card MC. Therefore, the memory card MC is not damaged by the elastic contact portion 23.
[0026]
The effect of the above configuration will be described with reference to FIG. The horizontal axis in FIG. 5 indicates the displacement X of the eject member 5 from the position where the memory card MC is not inserted, and the vertical axis indicates the force for pushing the eject member 5 (hereinafter, referred to as “ejection force F”). The energy for pushing out the memory card MC is obtained by integrating the discharge force F with the displacement X.
[0027]
The discharge force F is caused by the spring force of the coil spring 13 and linearly increases with respect to the displacement X of the eject member 5 as indicated by a straight line ab. Furthermore, according to the above configuration, the eject member 5 is pressed against the base shell 1 by the elastic force of the elastic contact portion 23 from the resistance force generating position P3 between the contact position P1 and the holding position P2 to the stop position P4, A friction force against the spring force of the coil spring 13 is generated. Here, the rear end of each elastic contact portion 23 is located rearward of the position where the rear end of the eject member 5 reaches. Further, since each of the elastic contact portions 23 is inclined so as to increase the dimension of projecting into the housing 3 toward the rear end, the deformation amount of the elastic contact portion 23 increases as the eject member 5 is pushed. The frictional force proportional to the spring force of the elastic contact portion 23 increases linearly with the displacement X of the ejecting member 5 as shown by a straight line cd.
[0028]
When the memory card MC is taken out, the amount of energy for pushing out the memory card MC corresponding to the area Z shown by the oblique lines in FIG. 5 is reduced by the frictional force. That is, the momentum for pushing out the memory card MC is reduced, so that the memory card MC is prevented from jumping out.
[0029]
Here, if it is attempted to prevent the memory card MC from jumping out by increasing the spring force of the holding piece 25 or decreasing the spring force of the coil spring 13 as shown by a broken line, the ejection force F at the contact position P1 is assumed. And the frictional force between the contact 10 and the memory card MC may cause an operation failure in which the memory card MC stops inside the housing 3. Furthermore, when the spring force of the pressing piece 25 is increased, the memory card MC may be damaged. On the other hand, according to the present invention, at the contact position P1, the same discharge force F as in the related art is obtained, so that no malfunction occurs, and there is no risk of damaging the memory card MC as described above.
[0030]
Further, since the elastic contact portion 23 is formed integrally with the housing 3, the provision of the elastic contact portion 23 does not increase the number of components. Furthermore, since the elastic contact portion 23 is formed by cutting and raising, even if the elastic contact portion 23 is pressed by the ejecting member 5, the elastic contact portion 23 is at most pushed back to a position before being cut and raised, and projects outside the housing 2. Nothing. Therefore, the provision of the elastic contact portion 23 does not hinder the incorporation into the device.
[0031]
(Embodiment 2)
In the present embodiment, as shown in FIG. 6, a housing 3 having a memory card insertion opening 42, which is formed in a substantially rectangular parallelepiped shape which is flattened up and down and has a shape different from that of the first embodiment, is opened on the front surface. Prepare. Hereinafter, the direction in which the memory card MC is extracted is referred to as the front, and the upper, lower, left, and right directions are based on FIG.
[0032]
The memory card MC used in the present embodiment is called a mini SD card which is a miniaturized version of a conventional SD memory card, has a substantially rectangular outer peripheral shape, and has a right rear corner to prevent reverse insertion. Notch 27 is formed. On the lower surface of the memory card MC, a plurality of (not shown, 11 in the case of a mini SD card) connection terminals (not shown) are provided side by side. In addition, locking notches 37 are provided on both left and right side edges of the memory card MC, each of which is depressed in a rectangular shape. Further, step portions 19 are formed on both left and right sides of the rear end of the memory card MC so that the left and right widths on the upper surface side are smaller than the left and right widths on the lower surface side.
[0033]
As shown in FIG. 7, the housing 3 has a base shell 1 formed by punching and bending a thin stainless steel plate, and a base formed by punching and bending a thin stainless steel plate similarly to the base shell 1. And a cover shell 2 attached to the upper side of the shell 1. Inside the housing 3, a contact block 4 having a plurality of contacts 10 that are in contact with connection terminals of the memory card MC is held. On the front side of the contact block 4, an eject member 5 that can slide back and forth in the housing 3 is housed. Coil springs 13 as urging springs for urging the eject member 5 forward are held at both left and right ends inside the housing 3.
[0034]
More specifically, the contact block 4 includes a base 7 made of a synthetic resin and arranged at the rear end of the housing 3. Each contact 10 is held on the base 7 by insert molding so as to protrude forward and backward of the base 7. Each contact 10 has a portion projecting rearward of the base 7 connected to an external circuit, and a portion projecting forward of the base 7 comes into contact with the memory card MC.
[0035]
The base shell 1 has a bottom plate 12 and side walls 6a and 6b protruding left and right of the bottom plate 12. At the front end of each of the side walls 6a and 6b, a projecting piece 18 for preventing the eject member 5 from dropping out of the memory card insertion slot 42 is provided inwardly. In order to prevent the contacts 10 from being in contact with the bottom plate 12 when pressed down by the memory card MC, escape holes 11 are provided vertically through the bottom plate 12 at positions corresponding to the respective contacts 10.
[0036]
The cover shell 2 includes a top plate 21 and side walls 20 vertically provided on the left and right of the top plate 21. At the left and right ends of the top plate 21, two slits 24 are provided side by side. Each of the left and right portions of the top plate 21 sandwiched by the slits 24 is provided with a holding piece 25 that is bent so that an intermediate portion in the front-rear direction projects downward and presses the memory card MC against the eject member 5. I have.
[0037]
The ejecting member 5 is made of a synthetic resin molded article, and has a main portion 5a which is long in the left and right and abuts on the upper end of the rear end of the memory card MC, and extends forward from the left and right ends of the main portion 5a, respectively. It comprises two arms 5b and 5c forming a character shape, and a flat plate-like connecting piece 5e connecting the lower ends of the inner surfaces of the front portions of the arms 5b and 5c to each other.
[0038]
At the left end of the main portion 5a, an overhang portion 5d that comes into contact with the cutout portion 27 of the memory card MC is provided. Further, the lower surface of the main portion 5a is located above the lower surface of the connecting piece 5e, so that a gap is generated between the lower surface of the main portion 5a and the upper surface of the bottom plate 12 of the base shell 1. When the eject member 5 is pushed in, the contact 10 projects forward of the main part 5a through the lower side of the main part 5a.
[0039]
Each arm 5b guides the left and right sides of the memory card MC. A step 50 is provided on the inner surface of the rear end of each of the arms 5b and 5c so that the upper side protrudes from the lower side. The step 19 of the memory card MC is located below the step 50 of the eject member 5. It is designed to enter.
[0040]
Further, at the rear ends of the arms 5b and 5c of the eject member 5, grooves (not shown) into which the front ends of the coil springs 13 are inserted are provided. The rear end of each coil spring 13 is attached to the contact block 4 via spring seat pieces 120 and 130, respectively. Here, a protruding portion 71 protrudes forward from the left end of the base 7. One of the spring seat pieces 120 is attached to a spring seat holding groove 71 a provided on the lower surface of the projecting portion 71 of the contact block 4, and the other is inserted into the one coil spring 13 from the rear to buckle the coil spring 13. And a buckling prevention needle 121 for preventing buckling. The other spring seat 130 has a buckling prevention needle 131 inserted into the other coil spring 13 from the rear to prevent buckling of the coil spring 13, and a coupling groove provided at the left end of the base 7 of the contact block 4. 7a is provided with a mounting piece 132 that is unevenly coupled to the mounting piece 132a.
[0041]
Further, a guide groove 15 is provided on the upper surface of the projecting portion 71 of the contact block 4, and a heart cam 15 a is formed by being surrounded by the guide groove 15. Here, a bearing hole 14b is provided on the upper surface of the left arm 5b of the eject member 5. Then, one projection 19a of a guide piece 19 made of a metal strip having projections 19a and 19b projecting downward from both ends is inserted into the bearing hole 14b, and the other projection 19b is engaged with the guide groove 15. Let me do it. The guide piece 19 has a projection 19 a pivotally supported by the bearing hole 14 b and the other projection 19 b guided by the guide groove 15. It turns around 19a. In the present embodiment, the guide groove 15 of the contact block 4, the bearing hole 14b of the eject member 5, and the guide piece 19 constitute a lock mechanism. The guide groove 15 has a shape in which the direction of the guide groove 15 of the first embodiment is changed, and the operation of the projection 19 b of the guide piece 19 inside the guide groove 15 is the operation of the free end 16 b of the guide pin 16 of the first embodiment. Therefore, detailed description is omitted.
[0042]
Further, a lock claw 19c is provided to protrude rightward at an intermediate portion of the guide piece 19 in the front-rear direction. When the eject member 5 slides to a predetermined position, the lock claw 19c engages with the lock notch 37 on the left side of the memory card MC, thereby preventing the memory card MC from dropping from the eject member 5.
[0043]
Here, the rear end of the top plate 21 of the cover shell 2 and the bottom plate 12 of the base shell 1 are provided with elastic contact portions 23 and 12a, respectively, which are cut and raised into the inside of the housing 3. 7 and 8). Each of the elastic contact portions 23 and 12a is inclined so that the projecting dimension into the housing 3 increases toward the rear end. From the resistance generation position to the stop position, the elastic contact portion 12a of the base shell 1 elastically contacts the lower surface of the connecting piece 5e of the eject member 5, and the elastic contact portion 23 of the cover shell 2 contacts the upper surface of the main portion 5a of the eject member 5. Make contact Here, the projecting dimension of the elastic contact portion 12a of the base shell 1 from the upper surface of the bottom plate 12 is exaggerated in the drawing, but is small enough not to actually contact the memory card MC. Further, the elastic contact portion 23 of the cover shell 2 is separated from the memory card insertion opening 46 to such an extent that the memory card MC does not come into contact even when the eject member 5 reaches the stop position. Therefore, neither the elastic contact portion 12a of the base shell 1 nor the elastic contact portion 23 of the cover shell 2 makes contact with the memory card MC.
[0044]
According to the above configuration, in addition to the same effects as in the first embodiment, the case where the elastic contact portions 12a and 23 are provided only on one side by providing the elastic contact portions 12a and 23 on both the upper and lower sides with the eject member 5 interposed therebetween. The degree of freedom of design is improved as compared with.
[0045]
Note that, as an example of the memory card MC, the SD memory card is described in the first embodiment, and the mini SD card is described in the second embodiment. However, the types of the memory card MC are not limited to these two types, and the present invention is not limited thereto. It is possible to correspond to various memory cards MC.
[0046]
【The invention's effect】
According to a first aspect of the present invention, there is provided a housing in which a memory card is slid and inserted and which holds a plurality of contacts for contacting connection terminals provided on the memory card, and a pressing force which comes into contact with the memory card inserted in the housing. Receiving member that slides with respect to the housing, a biasing spring that biases the ejecting member against the housing in a sliding direction when the memory card is pulled out, and a holding position where the connection terminal of the memory card contacts the contact. When the eject member is pushed into the lock position further back, the movement of the eject member with respect to the housing in the direction of pulling out the memory card from the holding position is prohibited, and thereafter, once the pressing force on the eject member is once removed, the eject A lock mechanism to release the prohibition when the eject member is pushed in, When the ejecting member is pushed in only to a position lower than the contact position where the connection terminal of the memory card inserted into the housing starts to contact the contact, the ejecting member does not contact either the ejecting member or the memory card, and the ejecting member is held at least. When the memory card is pushed out to the position, the housing is provided with a resilient contact portion that resiliently contacts a surface along a direction in which the eject member and the memory card slide with respect to at least one of the housings. The force of pushing the memory card is reduced by the frictional force generated by the elastic contact of the elastic contact portion, so that the memory card is prevented from jumping out. Further, when the eject member is pushed out to the contact position, the elastic contact portion does not come into contact with any of the eject member and the memory card, so that the memory card is not affected by the elastic portion and thereafter, via the eject member. It is pushed out of the housing by receiving the spring force of the urging spring. Therefore, a malfunction in which the memory card stops while being pushed out of the housing is prevented.
[0047]
According to a second aspect of the present invention, in the first aspect, the elastic contact portion is provided at a position in contact with only the ejecting member, so that the elastic contact portion does not damage the memory card.
[0048]
According to a third aspect of the present invention, in the first aspect of the present invention, the housing is made of a material having elasticity and the elastic contact portion is formed integrally with the housing, so that a separate component is used for the elastic contact portion. The number of parts is reduced, and the manufacturing cost can be reduced.
[0049]
According to a fourth aspect of the present invention, in the third aspect, the elastic contact portion is formed by cutting and raising a part of the housing into a space in which the memory card and the eject member slide, so that the memory card is pushed in. Also, since the elastic contact portion does not protrude outside the housing, it is easier to incorporate the elastic contact portion into the device than when the elastic contact portion protrudes outside the housing.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a first embodiment of the present invention.
FIG. 2 is an exploded perspective view showing the same.
FIG. 3 is a plan view showing a guide groove of the above.
FIG. 4 is a sectional view taken along line AA of FIG. 2 showing a main part of the same.
FIG. 5 is an explanatory diagram showing a relationship between a displacement amount of an ejection member and a discharge force for pushing out a memory card in the above.
FIG. 6 is a diagram showing a second embodiment of the present invention.
FIG. 7 is an exploded perspective view showing the same.
FIG. 8 is a sectional view taken along the line BB of FIG. 7 showing a main part of the above.
[Explanation of symbols]
3 Housing
5 Ejecting member
10 contacts
12a bullet contact
13 Coil spring
14b Bearing hole
15 Guide groove
16 Guide pins
19 Guide pieces
23 Bullet
MC memory card

Claims (4)

A housing in which a memory card is slid and inserted and which holds a plurality of contacts that come into contact with connection terminals provided in the memory card, and slides against the housing in contact with the memory card inserted in the housing and receives a pressing force. An ejecting member, an urging spring for urging the ejecting member against the housing in a sliding direction when the memory card is pulled out, and a locking position deeper than a holding position at which the connection terminal of the memory card contacts the contact. When the ejection member is pushed in, the movement of the ejection member with respect to the housing in the direction of pulling out the memory card from the holding position is prohibited, and then the ejection member is pushed in again after the pressing force on the ejection member is once removed. A lock mechanism to release the prohibition, and When the ejecting member is pushed in only to a position shallower than the contact position where the connection terminal of the memory card that has come into contact with the contact does not come into contact with the ejecting member or the memory card, and the ejecting member is pushed at least to the holding position. A memory card socket characterized in that the housing has a resilient contact portion which resiliently contacts a surface of at least one of the eject member and the memory card along a direction in which the housing slides with respect to the housing. 2. The memory card socket according to claim 1, wherein the elastic contact portion is provided at a position in contact with only the eject member. 2. The memory card socket according to claim 1, wherein the housing is made of an elastic material, and the elastic contact portion is formed integrally with the housing. 4. The memory card socket according to claim 3, wherein the elastic contact portion is formed by cutting and raising a part of the housing into a space in which the memory card and the eject member slide.

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