Card adapter

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a card adapter for electrically connecting electrical connecting portions of a card-shaped electronic device to contacts in a slot provided in a personal computer or the like for receiving another card-shaped electronic device which is manufactured in accordance with a different standard.

2. Description of the Prior Art

A card adapter has been conventionally used, for example, for electrically connecting contacts of a CF (Compact Flash) card which is a card-shaped electronic device smaller than a PC card to contacts in a slot provided in a personal computer for receiving a PC card.

FIG. 17

shows one example of this type of conventional card adapter disclosed in Japanese Laid-Open Patent Application 2000-259782.

The card adapter

80

shown in

FIG. 17

has a chassis

81

made of resin or the like, a circuit board assembly

82

mounted on the chassis

81

, and a pair of conducting plates

83

,

83

provided on the upper and lower sides of the chassis

81

, respectively.

The chassis

81

has a CF card receiving space

84

for receiving the CF card therein. The circuit board assembly

82

is provided with a first connector

85

to be electrically connected to the contacts (contact pins) provided in the slot for a PC card, a second connector

86

to be electrically connected to the contacts of the CF card, an eject button (eject lever)

87

and an eject arm

88

for ejecting the CF card received in the CF card receiving space

84

.

The eject button

87

is disposed in the chassis

81

such that it can be moved along the longitudinal direction of the adapter. The eject arm

88

is pivotably mounted on the circuit board assembly

82

by means of a rotation axis

89

. Further, the tip portion of the eject button

87

is linked with one end of the eject arm

88

through a connection

90

.

When ejecting the CF card received in the CF card receiving space

84

, eject operation is carried out by pushing the eject button

87

into the chassis

81

. When the eject button

87

is pushed, the eject arm

88

is rotated about the rotation axis

89

, and the other end portion thereof (which is an end portion opposite to the end portion linked with the eject button

87

) is moved toward the inside of the CF card receiving space

84

, and as a result, the CF card is disconnected from the card adapter

80

by the eject arm

88

.

Further, the CF card is provided with grounding contact portions (not shown in the drawing) on the side surfaces thereof for discharging static electricity charged in the CF card, and the chassis

81

is also provided with an electrical path for discharging the static electricity from the grounding contact portion of the CF card to a grounding means of the slot for a PC card.

The electrical path is constructed from an elastic contacting part

91

which elastically contacts with the grounding contact portion of the CF card, a contact part

92

which electrically connects with the grounding means of the slot for a PC card, and the conducting plate

83

which electrically connects the elastic contacting part

91

and the contact part

92

.

In the conventional card adapter

80

, the contact part

92

is provided on the outer surface of the chassis

81

which will be frequently held by a user. Therefore, if the user touches the contact part

92

when holding the card adapter

80

, static electricity charged in the user is discharged to the contacts provided in the slot for a PC card for receiving the card adapter and to the grounding contact portion of the CF card through the contact part

92

, the conducting plate

83

, and the elastic contacting part

91

, thus resulting in the case that an electronic circuit provided in the personal computer or the CF card is broken.

SUMMARY OF THE INVENTION

In view of the problems described above, it is an object of the present invention to provide a card adapter which can reliably isolate a slot provided in a personal computer and a card-shaped electronic device such as a CF card from a user.

In order to achieve the object mentioned above, the present invention is directed to a card adapter for electrically connecting a plurality of electrical connecting portions of a card-shaped electronic device to a plurality of contacts provided in a slot for receiving another card-shaped electronic device which is manufactured in accordance with a different standard, comprising:

a first connector to be electrically connected to the contacts provided in the slot;

a second connector which is electrically connected to said first connector, said second connector being adapted to be connected to the electrical connecting portions of the card-shaped electronic device;

a chassis in which said first and second connectors are disposed, said chassis having upper and lower sides; and

a pair of conducting plates provided on the upper and lower sides of the chassis,

wherein said chassis has a pair of arms extending from portions of the chassis which are located at opposite sides of said second connector, respectively, with a space therebetween so as to define a receiving space of the card-shaped electronic device, said arms being provided with a pair of insulating grip portions for isolating said conducting plates from a user holding the card adapter.

As described above, in the card adapter according to the present invention, the arms which are portions frequently held by a user are provided with the pair of insulating grip portions so that conductive parts such as the conducting plates provided on the upper and lower sides of the chassis and the like are reliably isolated from a user. Therefore, according to the present invention, the card adapter can prevent static electricity charged in the user from being discharged from the user to the contacts provided in the slot for receiving the card adapter and to a grounding contact portion of a card-shaped electronic device to be connected to the card adapter through the conductive parts of the card adapter.

In the present invention described above, it is preferred that each of the arms has a tip side, and said insulating grip portions are provided on the tip sides of the arms in the extension direction.

Further, it is also preferred that said chassis is formed of an insulating material.

In this case, it is also preferred that said insulating grip portions are formed by partially exposing the insulating material of the arms.

Further, it is also preferred that each of said tip sides is an area of the arm which extends from a tip of the arm over at least 1 cm in the extending direction of the arm.

In the present invention, it is preferred that at least one of the conducting plates is provided with a plurality of connecting protrusions electrically connected to a grounding means provided in the slot.

In this case, it is also preferred that, when the card adapter is inserted into the slot, said connecting protrusions are adapted to make an electrical connection with a grounding means in the slot after said first connector has been electrically connected to the contacts in the slot.

In the present invention, it is preferred that the card-shaped electronic device is one selected from the group consisting of a semiconductor memory card, an interface card, and a hard disk.

In this case, it is also preferred that the memory card has opposite side surfaces which are in contact with the arms of the chassis when the memory card is connected to the adapter, and the memory card is provided with a grounding contact portion on at least one of said opposite side surfaces, and the arms are provided with connecting means for electrically connecting said grounding contact portion to at least one of said conducting plates when the memory card is connected to said second connector.

The above and further objects, structures and effects of the present invention will be more apparent from the following detailed description of the embodiments with reference to the appended drawings.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1

is a perspective view which shows the overall structure of an embodiment of a card adapter according to the present invention.

FIG. 2

is an exploded perspective view which shows the structure of the card adapter.

FIG. 3

is a perspective view which shows the card adapter from which conducting plates are removed with a CF card being disconnected therefrom.

FIG. 4

is a perspective view of the card adapter from which the conducting plates are removed with the CF card being connected thereto.

FIG. 5

is a partially cut away view which shows the internal structure of arms of the card adapter shown in FIG.

3

.

FIG. 6

is a partially cutout perspective view of the card adapter for showing a chassis, a push member and a link arm thereof.

FIG. 7

is an enlarged view which shows the section of a first linking part indicated by an arrow A in FIG.

6

.

FIG. 8

is an enlarged view which shows the section of a rotation axis and the link arm indicated by an arrow B in FIG.

6

.

FIG.

9

(

a

) is a perspective view looking from the lower right of

FIG. 2

, showing a second linking part of the card adapter.

FIG.

9

(

b

) is a perspective view looking from the lower left of

FIG. 2

, showing the second linking part of the card adapter.

FIGS.

10

(

a

) and (

b

) are perspective views which show a connecting member of the card adapter, respectively.

FIG. 11

is a perspective view looking from the back side, showing the conducting plate of the card adapter.

FIGS.

12

(

a

) and (

b

) are enlarged views which show an elastic contact member and its periphery in

FIG. 11

, respectively.

FIG. 13

is a sectional view taken along the A-A′ line in FIG.

1

.

FIG. 14

is a perspective view which shows the overall structure of a CF card to be connected to the card adapter of the present invention.

FIG. 15

is a plan view which shows another embodiment of the card adapter of the present invention in which the arms have a different structure.

FIG. 16

is a perspective view which shows the overall structure of another embodiment of the card adapter in which a cap associated with an eject lever is modified.

FIG. 17

is an exploded perspective view which shows a conventional card adapter.

DETAILED DESCRIPTION OF THE INVENTION

Hereinbelow, preferred embodiments of a card adapter according to the present invention will be described in detail with reference to the appended drawings.

FIG. 1

is a perspective view which shows the overall structure of an embodiment of the card adapter according to the present invention;

FIG. 2

is an exploded perspective view which shows the structure of the card adapter;

FIG. 3

is a perspective view which shows the card adapter from which conducting plates are removed with a CF card being disconnected therefrom;

FIG. 4

is a perspective view of the card adapter from which the conducting plates are removed with the CF card being connected thereto;

FIG. 5

is a partially cut away view which shows the internal structure of arms of the card adapter shown in

FIG. 3

;

FIG. 6

is a partially cutout perspective view of the card adapter for showing a chassis, a push member and a link arm thereof:

FIG. 7

is an enlarged view which shows the section of a first linking part indicated by an arrow A in

FIG. 6

;

FIG. 8

is an enlarged view which shows the section of a rotation axis and the link arm indicated by an arrow B in FIG.

6

: FIG.

9

(

a

) is a perspective view looking from the lower right of

FIG. 2

, showing a second linking part of the card adapter; FIG.

9

(

b

) is a perspective view looking from the lower left of

FIG. 2

, showing the second linking part of the card adapter; FIGS.

10

(

a

) and (

b

) are perspective views which show a connecting member of the card adapter, respectively;

FIG. 11

is a perspective view looking from the back side, showing the conducting plate of the card adapter; FIGS.

12

(

a

) and (

b

) are enlarged views which show an elastic contact member and its periphery in

FIG. 11

, respectively;

FIG. 13

is a sectional view taken along the A-A′ line in

FIG. 1

;

FIG. 14

is a perspective view which shows the overall structure of a CF card to be connected to the card adapter of the present invention;

FIG. 15

is a plan view which shows another embodiment of the card adapter of the present invention in which the arms have a different structure; and

FIG. 16

is a perspective view which shows the overall structure of another embodiment of the card adapter in which a cap associated with an eject lever is modified.

The card adapter according to the present invention is used, for example, for electrically connecting a plurality of electrical connecting portions of a card-shaped electronic device such as a CF (Compact Flash (which is a trade mark of SanDisk Corporation)) card, an interface card or a hard disk or the like to a plurality of contacts in a slot provided in a personal computer or the like for receiving another card-shaped electronic device which is manufactured in accordance with a different standard from the CF card or the like described above. In this regard, it is to be noted that the following description for the embodiments will be made with regard to the case where the card adapter according to the present invention is used for electrically connecting electrical connecting portions of a CF card to contacts (contact pins) provided in a slot for a PC card.

As shown in

FIGS. 1

to

5

, a card adapter

1

includes a first connector

11

to be electrically connected to the contacts provided in the slot for a PC card; a second connector

12

which is electrically connected to the first connector

11

and is adapted to be connected to the electrical connecting portions of a CF card

2

: a chassis

10

in which the first and second connectors

11

,

12

are disposed; a pair of conducting plates

70

,

71

provided on the upper and lower sides of the chassis

10

; and an ejecting mechanism used when the CF card

2

is ejected. The ejecting mechanism includes a push member

40

, an eject lever

50

and a link arm

60

. The push member

40

is disposed in the chassis

10

, wherein the push member

40

is movable between a first position (see

FIG. 4

) in which the electrical connecting portions of the CF card

2

can be connected to the second connector

12

and a second position (see

FIG. 3

) in which the electrical connecting portions of the CF card

2

are disconnected from the second connector

12

, and the push member

40

is capable of pushing the CF card

2

positioned at the first position toward the second position. The eject lever

50

is movably mounted with respect to the chassis

10

. The link arm

60

is pivotably mounted on the chassis

10

via a rotation axis

13

to link the push member

40

and the eject lever

50

, wherein one end of the link arm

60

is linked with the push member

40

via a first linking (coupling) part

14

, and the other end is linked with the eject lever

50

via a second linking (coupling) part

15

, whereby the link arm has the function of a transmission means for transmitting the movement of the eject lever

50

to the push member

40

.

The chassis

10

is made of an insulating material such as a resin or the like and it is formed into a roughly rectangular shape. As shown in

FIGS. 2

to

5

, the chassis

10

includes a main body

16

in which the first connector

11

is positioned at one end and the second connector

12

is positioned at the other end, and a pair of arms

17

L,

17

R having a prescribed space therebetween that extend from the other end of the main body

16

provided with the second connector

12

to define a CF card receiving space

19

(see

FIGS. 3 and 5

) described below. As shown in

FIGS. 2

to

5

, the arm

17

L is provided with an eject lever receiving space

25

in which the eject lever

50

is movably received, and the arm

17

R is provided with an elastic member receiving space

23

which receives an elastic member

43

(described below) provided on the push member

40

. Further, the tip portions in the extension direction of the arms

17

L,

17

R are provided with a pair of insulating grip portions

18

L,

18

R for insulating the pair of conducting plates

70

.

71

from a user gripping the card adapter

1

.

As shown in

FIGS. 3 and 4

, the insulating grip portions

18

L,

18

R are formed by exposing the insulating material of the tip portions in the extension direction of the pair of arms

17

L,

17

R. This exposing of the insulating material is carried out by removing a portion of each of the conducting plates

70

,

71

. By forming such structure, a user gripping the insulating grip portions

1

L,

18

R does not make contact with conductive members such as the conducting plates

70

,

71

and connecting members

30

described below.

Further, the insulating grip portions

18

L.

18

R are preferably provided for a distance of at least 1 cm from the tip portions in the extension direction of the pair of arms

17

L,

17

R since these areas are normally gripped by the user when the card adapter

1

is mounted into the slot.

Then, by having this kind of structure, the card adapter

1

is insulated from static electricity from the user by the insulating grip portions

18

L,

18

R gripped by the user, and this makes it possible to prevent such static electricity from flowing to the slot and the CF card

2

through the conducting plates

70

,

71

and the other conductive members.

Further, in the present embodiment, as shown in FIG.

3

and

FIG. 4

, the length of the arm

17

L and the length of the arm

17

R are roughly equal, and an eject lever cap

53

(described below) is positioned at the tip of the arm

17

L. However, the present invention is not limited to this structure, and it is possible to be formed into the structure shown in

FIG. 15

in which one of the arms is formed to be a long arm

17

R′, the other arm is formed to be a short arm

17

L′ having a shorter length than the long arm

17

R′, and the eject lever

50

is provided in the short arm

17

L′.

In the case of the structure shown in

FIG. 15

, it is possible to reduce the amount of protrusion of the tip portion of the cap

53

of the eject lever

50

with respect to the tip portion of the long arm

17

R′ when the eject lever

50

is pulled into the inside of the chassis

10

.

As shown in

FIG. 14

, the CF card

2

is a plate-like card-shaped electronic device having a roughly square shape, and electrical connecting portions (not shown in the drawing) which are adapted to make an electrical connection with contacts provided in the CF card receiving space

19

(contacts of the second connector) are provided in the end surface of the top side in the drawing. Further, both the left and right side end surfaces of the CF card

2

in the drawing, namely, the side surfaces positioned at the sides of the arms

17

L,

17

R when the CF card

2

is positioned in the CF card receiving space

19

of the chassis

10

are respectively provided with a grounding contact portion

3

for discharging the static electricity charged on the CF card

2

to connecting members

30

(described below) provided on both the left and right sides of the CF card receiving space

19

, and a guide groove

4

and a guide concave portion

5

for guiding the CF card

2

when the CF card

2

is mounted in the CF card receiving space

19

.

Further, as shown in

FIG. 5

, the arms

17

L,

17

R of the chassis

10

are provided with the connecting members

30

which are adapted to make an electrical connection with the grounding contact portions

3

of the CF card

2

.

Each of the connecting members

30

is formed from a conductive material such as a metal material or the like. As shown in FIGS.

10

(

a

) and

10

(

b

), each connecting member

30

includes a mounting portion

32

for mounting the connecting member

30

to one of mounted portions

20

,

20

provided on the chassis

10

and an elastic contact portion (in the form of a metal spring)

31

which makes elastic contact with the grounding contact portion

3

when the CF card

2

is received in the CF card receiving space

19

.

Specifically, as shown in FIGS.

10

(

a

) and

10

(

b

), the mounting portion

32

of each connecting member

30

is formed into a shape having a roughly C-shaped cross section to have a pair of opposed top and bottom engagement parts

33

,

33

. Each of the engagement parts

33

,

33

includes a pair of hooks

34

,

34

. These hooks

34

have the function of preventing the connecting member

30

from being disengaged from the mounted portion

20

when the connecting member

30

is mounted to the mounted portion

20

.

Further, as shown in FIGS.

10

(

a

) and

10

(

b

), the elastic contact portion

31

is integrally formed with the mounting portion

32

, and it includes a bent strip formed to have a roughly V-shaped cross section which acts as the metal spring.

Furthermore, as shown in FIG.

5

and

FIG. 13

, the mounted portions

20

,

20

are respectively provided at two predetermined locations in the arms

17

L,

17

R of the chassis

10

. Further, as is best shown in

FIG. 13

, each mounted portion

20

has a concave portion

27

which is formed in the top surface of each of the respective arms

17

L,

17

R.

The connecting member

30

having the above structure is mounted to the corresponding mounted portion

20

so that its top and bottom engagement parts

33

,

33

of the mounting portion

32

hold the top and bottom surfaces of the arm, respectively, at the location of the concave portion

27

as shown in FIG.

13

. When the connecting member

30

is mounted to the mounted portion

20

in this way, the elastic contact portion

31

of the connecting member

30

protrudes inwardly from the inner surface of the arm (

17

L or

17

R) so that it can make elastic contact with the grounding contact portion

3

of the CF card

2

when the CF card

2

is received in the CF card receiving space

19

. Further, in this state, as described below in more details, corresponding elastic contact members

74

L,

74

R provided on the conducting plate

70

can make contact with the top engagement parts

33

of the connecting members

30

, respectively, so that the connecting member

30

is electrically connected to the conducting plate

70

.

Further, as shown in

FIG. 2

, the chassis

10

is provided with a pair of biasing members

21

,

21

which normally bias the push member

40

from the first position toward the second position. As shown in

FIG. 2

, the biasing members

21

,

21

are compression coil springs provided on both ends of the second connector

12

, and the push member

40

is biased and displaced from the first position to the second position by the biasing force of the biasing members

21

,

21

.

Further, as shown in

FIGS. 2

to

5

, the chassis

10

has the rotation axis

13

which supports the link arm

60

in a freely rotatable manner. As shown in

FIG. 8

, the rotation axis

13

is integrally formed with the chassis

10

. Further, after the link arm

60

is mounted, the tip portion of the rotation axis

13

is formed into a mushroom shape having a diameter larger than the diameter of the rotation axis

13

by heat deformation or the like. Then, by forming such structure, it is possible to prevent the link arm

60

from disconnecting from the rotation axis

13

.

Further, as shown in FIG.

3

and

FIG. 4

, the chassis

10

is provided with walls

22

a

to

22

d

in order to restrict the rotation angle of the link arm

60

around the rotation axis

13

.

As shown in

FIG. 4

, the walls

22

a

and

22

b

are provided at positions corresponding to the positions of the lower side surface of the link arm

60

in the left side of the drawing from the rotation axis

13

, and the upper side surface of the link arm

60

in the right side of the drawing from the rotation axis

13

when the push member

40

is positioned at the first position.

Further, as shown in

FIG. 3

, the walls

22

c

and

22

d

are provided at positions corresponding to the positions of the upper side surface of the link arm

60

in the left side of the drawing from the rotation axis

13

, and the lower side surface of the link arm

60

in the right side of the drawing from the rotation axis

13

when the push member

40

is positioned at the second position.

Now, when an attempt is made to rotate the link arm

60

beyond a required angle, the side portions of the link arm

60

(that is, the upper side surface of the link arm

60

in the left side from the rotation axis

13

and the lower side surface of the link arm

60

in the right side from the rotation axis

13

) come into abutment with the walls

22

c

and

22

d

, whereby the rotation of the link arm

60

is restricted. Then, by restricting the rotation of the link arm

60

in this way, the displacement of each end portion of the link arm

60

, namely, the displacement of the push member

40

and the eject lever

50

respectively linked to the first linking part

14

and the second linking part

15

is also restricted.

The push member

40

has a function which pushes the CF card

2

, and a function which protects contact pins

29

of the second connector

12

when the CF card

2

is removed.

The push member

40

is formed from an insulating material such as resin or the like in the same manner as the chassis

10

, and as shown in

FIGS. 2

to

5

, the push member

40

includes a contact pin covering portion

41

for covering the contact pins

29

of the second connector

12

, a protruding portion

42

which extends from the end portion of the covering portion

41

at the side of the first connector

11

(which is shown in the upper side of the covering portion

41

in the drawings), and the elastic member

43

provided on the end portion of the covering portion

41

on the right side in the drawings.

As shown in FIG.

2

and

FIG. 3

, the covering portion

41

is formed roughly in the shape of a flat box, and includes protrusion holes

44

formed in the end surface at the side of the CF card receiving space

19

to enable the protrusion of the contact pins

29

of the second connector

12

.

Further, as shown in

FIGS. 2

to

5

, the protruding portion

42

extends from roughly the center of the covering portion

41

in the width direction thereof toward the first connector

11

. Further, an aperture

45

which engages with a projection

62

(described below) of the link arm

60

is disposed in a roughly central portion of the protruding portion

42

in the width direction thereof. The aperture

45

is formed into the shape of a slit which has a width roughly the same as (slightly larger than) the diameter of the projection

62

(described below) disposed on the end portion of the link arm

60

so that the projection

62

can move along the aperture

45

when the link arm

60

is rotated.

Then, by adopting such a structure, it is possible to provide a prescribed play between the projection

62

and the aperture

45

, and it becomes possible to ideally convert the rotational movement of the link arm

60

into the reciprocal movement of the push member

40

.

Furthermore, in the present embodiment, the engaging part of the projection

62

and the aperture

45

is referred to as the first linking part

14

. Further, in the present embodiment, the projection

62

is disposed on the link arm

60

, and the aperture

45

is disposed in the push member

40

, but the present invention is not limited to this arrangement. It is also possible to provide the projection on the push member

40

, and provide the aperture in the link arm

60

, and in the case where such structure is adopted, it is possible to achieve the same advantages as the present embodiment.

As described above, in the present embodiment, the first linking part

14

is positioned in roughly the central portion of the push member

40

in the width direction thereof. Accordingly, when the push member

40

is displaced, there is no difference in the displacements of the end portions of the CF card

2

in the width direction thereof like that which occurs in the prior art card adapter

80

described above, so that it becomes possible to prevent deformation of the contact pins

29

of the second connector

12

when the push member

40

is displaced.

The elastic member

43

is made from a metal material, and as shown in FIG.

4

and

FIG. 5

, the elastic member

43

includes a locking protrusion

46

which locks with a locking aperture

24

formed in the elastic member receiving space

23

of the chassis

10

, and a flat spring portion

47

which makes it possible to displace the locking protrusion

46

. The elastic member

43

having the above structure is fixed to the end portion of the push member

40

(which is shown in the right side of the drawings), and is received in the elastic member receiving space

23

provided in the arm

17

R of the chassis

10

.

As shown in FIG.

3

and

FIG. 5

, when the push member

40

reaches the second position, the locking protrusion

46

locks with the locking aperture

24

of the chassis

10

. Then, when an attempt is made to displace the push member

40

from the second position toward the first position, the locking surface of the locking protrusion

46

makes contact with the locking surface of the locking aperture

24

, whereby the push member

40

is kept at the second position.

Further, as shown in

FIG. 4

, when the CF card

2

is mounted in the CF card receiving space

19

, the locking protrusion

46

makes contact with a side surface of the CF card

2

, and is displaced to the right side in the drawings, namely, into the inside of the arm

17

R. This displacement disengages the lock between the locking protrusion

46

and the locking aperture

24

, thereby making it possible to displace the push member

40

from the second position to the first position.

As described above, the push member

40

is movable between the first position shown in

FIG. 4

, namely, the position where the CF card

2

is received in the CF card receiving space

19

under the state that the electrical connecting portions of the CF card

2

are connected to the contact pins of the second connector

12

, and the second position shown in

FIG. 3

, namely, the position where the electrical connecting portions of the CF card

2

can be disconnected from the second connector

12

. When the push member

40

is moved from the first position toward the second position, the push member

40

is capable of pushing the CF card

2

positioned at the first position toward the second position. According to the movement of the push member

40

, the protrusion holes

44

of the covering portion

41

of the push member

40

cover the contact pins

29

(see

FIG. 2

) of the second connector

12

so that the contact pins

29

are held inside the covering portion

41

of the push member

40

, whereby the contact pins

29

are protected by the covering portion

41

. In other words, in accordance with the movement of the push member

40

, the contact pins

29

of the second connector

12

are pulled out of the electrical connecting portions of the CF card

2

.

Further, as seen from the drawings, the push member

40

is constructed so as to push the CF card

2

by surface contact or multiple point contact along the both sides of the center of the push member

40

in the width direction thereof (although at least two point contact occurs in the both sides of the center position, many contact points are preferred). Accordingly, contact does not occur only at a single point like the tip portion of the eject arm

88

of the prior art card adapter

80

described above. This makes it possible to prevent abrasion of the contact portion of the CF card

2

. Further, because the surface contact or multiple point contact described above occurs in the both sides of the center position of the push member

40

, it is possible to prevent inclination of the CF card

2

inside the CF card receiving space

19

.

The link arm

60

is formed from a metal material, and as shown in FIG.

2

and

FIG. 8

, the link arm

60

is provided with an axis hole

61

in roughly the center thereof for support by the rotation axis

13

provided on the chassis

10

. Further, the projection

62

is disposed on the right side end portion of the link arm

60

in the drawings, and a linking protrusion

63

is provided on the left side end portion of the link arm

60

in the drawings. In the present embodiment, the portion of the link arm

60

excluding the linking protrusion

63

is referred to as a link arm body

64

for convenience sake, and the engagement part of the linking protrusion

63

and a linking protrusion receiving hole

51

is referred to as the second linking part

15

.

As shown in FIG.

6

and

FIG. 7

, the projection

62

is integrally formed with the link arm

60

(which is formed from a metal material) by carrying out a burring process or the like on the right side end portion of the link arm

60

in the drawings. In the present embodiment, by integrally forming the projection

62

with the link arm

60

by a burring process in this way, the processes carried out when manufacturing the link arm

60

are made more efficient.

As shown in FIGS.

9

(

a

) and

9

(

b

), the linking protrusion

63

is formed to have a roughly rectangular plate-like shape, and is integrally formed with the left side end portion of the link arm body

64

in the drawings via a step portion

65

. The step portion

65

has a function which adjusts the position of the linking protrusion

63

with respect to the linking protrusion receiving hole

51

(described below) provided in the eject lever

50

, and the linking protrusion

63

and the link arm body

64

are integrally formed via the step portion

65

. Accordingly, when the link arm

60

is mounted to the chassis

10

, the operation which engages the linking protrusion

63

to the linking protrusion receiving hole

51

of the eject lever

50

is made more efficient.

As shown in

FIG. 2

, the eject lever

50

is constructed from a rod-shaped eject rod

52

which is received in the eject lever receiving space

25

provided in the chassis

10

, and the cap

53

(made from an insulating resin) which covers the tip end portion of the eject rod

52

(which is shown in the lower side in the drawings).

Further, in the present embodiment, the cap

53

is formed to have a roughly rectangular parallelepiped shape, but the present invention is not limited to this. As shown in

FIG. 16

, the cap

53

may be formed to have roughly the same cross-sectional shape as the arm

17

L, and it is possible to provide the inner side surface of the cap

53

(which is shown in the right side in the drawings) with a guide portion (protruding member)

54

which extends in the extension direction of the arm

17

L.

When the CF card

2

is mounted in the CF card receiving space

19

of the chassis

10

, the guide portion

54

is adapted to engage with the guide concave portion

5

provided on the side surface of the CF card

2

in order to guide the CF card

2

.

By providing the guide portion

54

, when the CF card

2

is to be mounted into the card adapter

1

while the card adapter

1

is in a mounted state inside a slot (not shown in the drawings) for a PC card, the guide concave portion

5

of the CF card

2

is guided by the guide portion

54

, so that the CF card

2

can be mounted smoothly.

As shown in FIG.

2

and

FIG. 9

, the linking protrusion receiving hole

51

which receives the linking protrusion

63

of the link arm

60

is provided in the base end of the eject rod

52

. As shown in FIGS.

9

(

a

) and

9

(

b

), the linking protrusion receiving hole

51

is formed into a through hole having a roughly rectangular cross section which passes through the eject rod

52

from the right side surface into the left side surface. The width of the linking protrusion receiving hole

51

is designed to be larger than the width of the linking protrusion

63

.

In this way, by setting the width of the linking protrusion receiving hole

51

to be larger than the width of the linking protrusion

63

, it is possible to provide a prescribed play between the linking protrusion

63

and the linking protrusion receiving hole

51

. This makes it possible to ideally convert the rotational motion of the link arm

60

into the reciprocal motion of the eject lever

50

.

The conducting plates

70

,

71

are formed from a metal material. As shown in FIG.

2

and

FIG. 11

, each conducting plate is constructed from a roughly rectangular main body cover portion

72

which protects the main body

16

of the chassis

10

. and a pair of arm cover portions

73

L,

73

R which extend from both side ends of the edge of the main body cover portion

72

(which is shown in the lower side in the drawings).

When mounted to the chassis

10

, the main body cover portion

72

makes contact with a connecting plate

28

provided on the upper portion of the chassis

10

. The connecting plate

28

is electrically connected to at least one of the terminal pins of the first connector

11

, and has a function which discharges static electricity from the main body cover portion

72

to a grounding terminal of the slot.

Further, as shown in FIG.

11

and

FIG. 12

, on the underside of the pair of arm cover portions

73

L,

73

R of the conducting plate

70

, there are integrally formed with long and narrow plate-shaped elastic contact members

74

L,

74

R, respectively, so as to extend from the outside end portions of the arm cover portions

73

L,

73

R toward the inside. As shown in

FIG. 13

, when the conducting plate

70

is mounted to the chassis

10

, the elastic contact members

74

L,

74

R make elastic contact with the engagement parts

33

of the connecting members

30

provided on the chassis

10

to make an electrical connection between the connecting members

30

and the conducting plate

70

.

Further, the conducting plate

70

is provided with a plurality of connecting protrusions

75

which are adapted to make a connection with a grounding means of a slot such as a plurality of tongue members or the like positioned in the upper side of the slot.

As shown in FIG.

2

and

FIG. 11

, the connecting protrusions

75

are provided on the conducting plate

70

near the end portion of the first connector

11

, and each connecting protrusion

75

is a protrusion formed in the shape of a hemisphere. The connecting protrusions

75

are adapted to make an electrical connection with the grounding means of the slot after the first connector

11

is electrically connected to the contacts of the slot. Therefore, in the case where the static electricity from the conducting plate

70

can not be discharged from the first connector

11

due to a break in the discharge path or the like, the connecting protrusions

75

are connected to the grounding means of the slot so that the static electricity from the conducting plate

70

is discharged to the grounding means of the slot. Further, because the connecting protrusions

75

make contact with the grounding means of the slot at many points, the grounding resistance of the main body cover portion

72

is lowered, and this makes it possible to shield the outside from undesired radiation of electromagnetic waves generated inside the device.

In this way, in the present embodiment, first, static electricity from the CF card

2

is discharged to the grounding terminal of the slot through the connecting members

30

, the conducting plate

70

, the connecting plate

28

and the first connector

11

, and they form a first discharge path. Further, in the case where this first discharge path is broken for some reason, the static electricity from the CF card

2

is discharged to the grounding means in the upper side of the slot through a second discharge path, namely, through the connecting members

30

and the conducting plate

70

(connecting protrusions

75

). In this way, by providing these two separate discharge paths for discharging the static electricity from the CF card

2

, it becomes possible to discharge the static electricity from the CF card

2

to the grounding means of the slot more reliably.

Accordingly, in the structure described above, because there is no need to provide any members equivalent to the contact member

92

of the prior art card adapter

80

described above which are arranged on the side portion of the chassis

81

to make contact with the conducting plate

83

, it becomes possible to reliably insulate the conducting plate

70

from a user gripping the card adapter

1

. As a result, in the case where the user's body is charged with a large amount of static electricity especially during the winter season or the like, this static electricity is not discharged to the slot or the CF card

2

through the conducting plate

70

, so that there is no risk of the internal electronic circuits malfunctioning or being damaged by such static electricity.

As described above, in the card adapter

1

of the present invention, the push member

40

, the link arm

60

and the eject lever

50

are linked through the first linking part

14

and the second linking part

15

so that when one of these three members is displaced, the other two members are also moved. In addition, when the CF card

2

is removed from the card adapter

1

, namely, when the push member

40

is displaced from the first position to the second position, the eject lever

50

is reliably pulled inside the chassis

10

in accordance with the displacement of the push member

40

.

As a result, even in the case where the CF card

2

is removed from the card adapter

1

by hand without using the eject lever

50

, the eject lever

50

is held inside the chassis

10

. Therefore, it is possible to prevent the eject lever

50

from being damaged when the CF card

2

is not mounted in the card adapter

1

.

Further, in the structure described above, the rotation axis

13

is integrally formed with the chassis

10

, and after the rotation axis

13

is inserted through the axis hole

61

of the link arm

60

, the top end portion thereof is processed to have a larger diameter than the diameter of the rotation axis

13

, thereby preventing the link arm

60

from detaching from the rotation axis

13

.

Further, in the structure described above, since the walls

22

a

to

22

d

are provided as restricting means for restricting the rotation angle of the link arm

60

on the chassis

10

, it is possible to prevent the link arm

60

from rotating more than necessary. Further, because of this restricted rotation of the link arm

60

, the push member

40

and the eject lever

50

are prevented from protruding out of the chassis

10

more than necessary.

Further, in the structure described above, the first linking part

14

is constructed by the projection

62

disposed on one end of the link arm

60

, and the aperture

45

formed in the push member

40

to engage with the projection

62

, wherein the aperture

45

is positioned roughly in a central portion of the push member

40

in the width direction thereof. Accordingly, it is possible to prevent inclination of the push member

40

when the push member

40

is displaced.

Further, in the structure described above, the link arm

60

is formed from a metal material, and the projection

62

is integrally formed with the link arm

60

by a burring process. Accordingly, the manufacturing process of the link arm

60

can be simplified.

Further, in the structure described above, the aperture

45

is formed into a slit having a width roughly the same as the diameter of the projection

62

, and the projection

62

is capable of moving along the aperture

45

when the link arm

60

is rotated. Accordingly, it is possible to ideally convert the rotational motion of the link arm

60

into the reciprocal motion of the push member

40

.

Further, in the structure described above, the second linking part

15

is constructed by the linking protrusion

63

provided on the other end of the link arm

60

and the linking protrusion receiving hole

51

provided in the eject lever

50

to engage with the linking protrusion

63

, so that the rotational motion of the link arm

60

is converted into the reciprocal motion of the eject lever

50

. The linking protrusion

63

is integrally formed with the link arm body

64

through the step portion

65

for adjusting the position of the linking protrusion

63

with respect to the linking protrusion receiving hole

51

. Accordingly, it is possible to simplify the operation of attaching the link arm

60

to the elect lever

50

.

Further, in the structure described above, when the push member

40

reaches the second position, the holding means retains the push member

40

at the second position. This holding means is constructed from the elastic member

43

with the locking protrusion

46

which is provided on the push member

40

, and the locking aperture

24

formed in the chassis

10

, wherein the locking protrusion

46

locks with the locking aperture

24

to reliably retain the push member

40

at the second position. Further, the locking protrusion

46

is constructed to undergo displacement in contact with the side surface of the CF card

2

when the CF card

2

is mounted, and the lock between the locking protrusion

46

and the locking aperture

24

is disengaged by such displacement, thereby making it possible to displace the push member

40

from the second position to the first position. Accordingly, the push member

40

can be constructed to allow for displacement only when the CF card

2

is mounted.

Further, in the structure described above, the chassis

10

includes the pair of arms

17

L,

17

R having a prescribed space therebetween that extend from portions of the chassis

10

which are located at opposite sides of the second connector

12

, respectively, to define the CF card receiving space

19

, wherein one of the arms

17

L,

17

R is provided with the eject lever

50

, with the other being provided with the elastic member

43

. Accordingly, it becomes possible to efficiently utilize the limited space inside the chassis

10

.

Further, in the structure described above, the pair of arms

17

L,

17

R of the chassis

10

are provided with the pair of insulating grip portions

18

L,

18

R which insulate the pair of conducting plates

70

,

71

covering the both surfaces of the chassis

10

from a user gripping the card adapter

1

. Accordingly, it is possible to prevent the discharging of static electricity from the user to the inside of the CF card

2

or to the slot connected to the first connector

11

through the conducting plates

70

,

71

.

Further, in the structure described above, the chassis

10

is formed from an insulating material, and the insulating grip portions

18

L,

18

R are formed by exposing the insulating material of the tip portions of the arms

17

L,

17

R in the extension direction thereof. Accordingly, the structure can be made simple, and the insulating grip portions

18

L,

18

R make it possible to reliably insulate the conducting plates

70

,

71

from the user.

Further, in the structure described above, the insulating grip portions

18

L,

18

R are provided for a distance of at least 1 cm from the tips of the pair of arms

17

L,

17

R along the extending direction where the user is most likely to grip the card adapter

1

.

Further, in the structure described above, at least one of the pair of conducting plates

70

,

71

is provided with the connecting protrusions

75

which are adapted to make an electrical connection with the grounding means provided in the slot. Accordingly, it becomes possible to discharge the static electricity from the CF card

2

to the grounding means of the slot more reliably. Further, it becomes possible to shield the outside from undesired radiation of electromagnetic waves generated inside the device. Further, the connecting protrusions

75

are adapted to make an electrical connection with the grounding means of the slot after the first connector

11

is electrically connected to the contacts of the slot. In other words, if the connecting protrusions

75

are provided at a position on the conducting plate that come to contact with the terminals of the slot before the first connector

11

is connected to the contacts of the slot, that is at a position nearer to the top end of the conducting plate, the card adapter contacts with the grounding means to make grounding even if the card adapter is partially protruded out of the slot. This resulting in the increased risk of discharge due to the increase in the possibility that the user will touch portions of the arm cover portions

73

L,

73

R of the conducting plate

70

away from the insulating grip portions

18

L,

18

R.

Further, the card adapter

1

of the present invention can be used ideally as a card adapter for a semiconductor memory card such as a CF card or the like. Then, in the case where the card adapter

1

of the present invention is used as a card adapter for a CF card, connecting means such as the connecting members

30

or the like are provided to electrically connect the grounding contact portion

3

of the CF card

2

to at least one of the conducting plates

70

,

71

.

Finally, the present invention is not limited to the embodiment described above, and it is possible to make various changes and improvements without departing from the scope and spirit of the invention defined in the appended claims. For example, it is of course possible to apply the card adapter of the present invention to various other card adapters for cards manufactured under different standards than the CF card and the PC card described in the present embodiment. Examples of card-shaped electronic devices that can be used for the card adapter of the present invention include a semiconductor memory card, an interface card and a hard disk and the like.

Card adapter

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Priority Claims (1)

US Referenced Citations (1)

Foreign Referenced Citations (1)