JP2004031238A - Card connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a card connector which is not cut off during data access and provided with a locking mechanism that has a simple constitution, compactness and high reliability. <P>SOLUTION: This card connector is provided with a thin and rectangular case body to house a card inside, and one side face of surrounding four side faces of the case body is an opening side face formed with an opening for taking in and out a card. At the case body, a shape memory alloy body to carry out flexible action in a longitudinal direction by a supply-current is arranged and installed nearly in parallel with the opening side face and with the one end side fixed. The connector constituted so that a locking body to carry out action to lock the card interlocked with the flexible action is arranged and installed at the end of the movable side of the shape memory alloy body. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a card connector (MMC connector or the like) suitable for storing and connecting a memory card or the like therein, and more particularly to a card connector having a locking mechanism used for holding and discharging a card. is there.
[0002]
[Prior art]
A card connector for connecting a memory card or the like receives a detachable card therein, is used in a state of being stored or held, and performs data access and the like. However, during data access, the card may be detached from the card connector for some reason, and such data may be suddenly disconnected. Therefore, there is a trouble and trouble that the user must always pay close attention to prevent such an accident.
[0003]
[Problems to be solved by the invention]
In order to prevent such accidents related to disconnection or detachment of the card connector, as an example of a conventional card connector, a card is attached and detached by a mechanism using a magnetic force using a solenoid to protect data. However, such a card connector is not practical because it consumes a large amount of power, increases the size and weight of the device, and leads to an increase in cost. There are many problems.
[0004]
The present invention has been made in view of the above problems, and a card connector according to the present invention provides a compact card connector having a very simple configuration, requiring no space, and requiring no complicated mechanism. The purpose of the present invention is to provide a card connector capable of being equipped with a strong and reliable locking mechanism in consideration of dropping or giving an impact to the card connector. I have.
[0005]
[Means for Solving the Problems]
In order to solve the above problems and achieve a desired object, a card connector according to the present invention is configured as follows.
(1) A card connector including a thin rectangular housing for housing a card therein,
One of the four sides around the housing is an opening side provided with an opening for inserting and removing a card,
In the housing, a shape memory alloy body that expands and contracts in the longitudinal direction by energization is disposed substantially parallel to the side surface of the opening, with one end thereof fixed.
At the movable end of the shape memory alloy body, a locking body that performs an operation of locking the card in conjunction with the expansion and contraction operation is disposed,
The configured card connector.
The card connector according to the present invention having the configuration (1) is shown in FIGS.
(2) In the card connector according to (1),
In order to hold the position of the locking body with operation, an elastic means for restraining the locking body is provided separately from the shape memory alloy body.
(3) In the card connector according to (1),
The housing includes a slider body that stops the card and moves in the entry and exit directions together with the card.
(4) In the card connector according to (3),
The locking body includes means for restraining the movement of the slider body.
(5) In the card connector according to (3) or (4),
The housing includes elastic means for applying a pressing force to the slider body in a card removal direction.
(6) A card connector including a thin rectangular housing for storing a card therein,
One of the four sides around the housing is an opening side provided with an opening for inserting and removing a card,
In the housing, a shape memory alloy body that expands and contracts in the longitudinal direction by energization is disposed substantially at right angles to the side surface of the opening, and one end side thereof is fixed,
At the movable end of the shape memory alloy body, a locking body that performs an operation of locking the card in conjunction with the expansion and contraction operation is disposed,
Elastic means for applying a tensile force to the locking body separately from the shape memory alloy body to maintain the position of the locking body with operation
The housing includes a slider body that stops the card and performs a movement operation in the card entry / exit direction together with the card,
The locking body includes means for restraining the movement of the slider body,
The housing is a card connector including elastic means for applying a pressing force to the slider body in a card removal direction.
The card connector according to the present invention having the configuration (6) is shown in FIG.
[0006]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, an embodiment of a card connector according to the present invention will be described in detail with reference to the drawings. FIG. 1 is a configuration explanatory view showing a first embodiment of the present invention. FIG. 2 shows a second embodiment of the present invention. FIG. 3 shows a third embodiment of the present invention. FIG. 4 is a structural explanatory view showing a fourth embodiment of the present invention.
[0007]
1A to 1C show a card connector in a state before a card is inserted, that is, in a state before card locking is applied. FIG. 1A shows a front view of the card connector, and FIG. ) Shows a top view thereof, and (c) shows a left side view thereof. FIG. 1D is a front view of the card connector in a state where the card locking is already applied.
[0008]
In FIG. 1, a main body 100 'of a card connector 100 of the present invention has a substantially rectangular parallelepiped shape when viewed from a front portion 101, and has a thin and horizontally long shape when viewed from an upper surface portion 104. It is a housing. An opening side surface is formed at the upper surface 104 at the upper side of the four surrounding sides, and a card storage portion 102 is provided for receiving a card (not shown) inserted from the direction of arrow M1. A plurality of connector sections 180 for connection are provided on the lower surface 107 side on the lower side.
The card connector 100 includes a shape memory alloy body 110 slightly below the upper surface portion 104 of the main body 100 ′ and substantially parallel thereto. The shape memory alloy body 110 is a helical spring body that constantly urges at room temperature, but has the property of being deformed to the stored shape or length by being energized and causing the alloy itself to generate heat. It consists of an alloy material. The shape memory alloy body 110 can change its shape itself by utilizing a temperature change accompanying energization and non-energization.
[0009]
The shape memory alloy body 110 has its right end fixed by a stopper 112 on the right side 105 side of the front part 101, and is always attached toward the left side 106 by natural elastic force at normal temperature. The force is going. A locking body 120 is connected and connected to the left end of the shape memory alloy body 110 via a fixing section 114.
The locking body 120 is a main constituent member for forming a mechanism for locking a card inserted into the main body 100 from the upper surface portion 104 so as to keep the stored state so that the card cannot be taken out. Since the locking body 120 is integrally connected to the shape memory alloy body 110, the locking body 120 always performs an operation that is linked to an operation associated with elastic expansion and contraction or shape deformation of the shape memory alloy body 110.
[0010]
The locking body 120 has a “U” -shaped hook or hook-like shape as a whole, and has a main portion 126 linearly connected to the longitudinal direction of the shape memory alloy body 110 and a substantially right angle from the main portion 126. The neck portion 124 is bent in the right direction, and the hook portion 122 is bent from the neck portion 124 in a substantially right angle direction. As the locking body 120 moves left and right, the hooks 122 form a structure that opens and closes and locks the upper surface 104 into and from which the card is inserted. In FIG. 1D, the arrow M2 indicates the rightward movement of the locking body 120, and accordingly, the hook 122 also moves rightward, covering a part of the left side of the upper surface 104, and the card storage state. FIG. 4 shows a state in which a locking structure for holding the pattern is formed.
[0011]
The stopper 140 is a locking member that engages with the locking body 120 to hold the position thereof, and is integrally connected to the second shape memory alloy body 130 in a linear manner. The stopper 140 is moved upward when the locking body 120 is in the card locked state, and the downwardly engaging portion 128 provided on the main portion 126 and the upper end portion of the stopper 30 are unevenly engaged. The positioning of the locking body 120 is maintained. The stopper 140 is configured to be movable in a direction substantially perpendicular to the direction of movement of the locking body 120, and is connected and connected in a straight line as a stopper 140-stopper 134-second shape memory alloy body 130-. The lower end is fixed to the front portion 101 at the stopper 132.
[0012]
Now, with reference to FIG. 1, a procedure for inserting a card into the card connector 100 and storing the card will be described below.
1) When a card (not shown) is received in the direction of arrow M1, the shape memory alloy body 110 is energized to apply a predetermined voltage.
2) The shape memory alloy body 110 generates heat by energization, and its length in the longitudinal direction is reduced due to its inherent shrinking property. It is moved in the direction of arrow M2 to the locking position.
[0013]
3) When the locking body 120 moves rightward to the predetermined locking position where the card is stored, the natural spring pressing force of the second shape memory alloy body 130 which has been compressed acts upward. As a result, the stopper 140 is moved in the direction of arrow M3, and the leading end thereof is engaged with the engaging portion 128 of the locking body 120, and the locking body 120 and the stopper 140 are unevenly engaged, so that the locking position is predetermined. And a stable holding and storing structure is formed. In this state, the energization of the shape memory alloy body 110 is stopped, while the second shape memory alloy body 130 is not energized from the beginning.
[0014]
Next, when the user releases the state in which the card is stored in the card connector 100, the following procedure is performed.
4) When the user of the card connector 100 presses the release button, energization starts, and the second shape memory alloy body 130 is energized and given a predetermined voltage. Since the shape memory alloy body 130 undergoes a shape deformation that generates heat and contracts, the stopper 140 interlocked with the shape memory alloy body 130 moves down from the engaging portion 128 of the locking body 120, so that the locking body 120 moves leftward. Can be moved.
5) The shape memory alloy body 110 is not energized and does not receive a voltage, and is elastically biased leftward by its own natural spring force, so that the locking body 120 is returned to the left original position.
6) The user can remove the memory card.
[0015]
Referring now to FIG. 2, there is shown a card connector according to a second embodiment of the present invention. FIGS. 2A to 2C are diagrams illustrating a situation where the card 290 is inserted into the card connector 200 and card locking is performed. 2A is a front view of the card connector 200, FIG. 2B is a top view thereof, and FIG. 2C is a left side view thereof.
[0016]
In FIG. 2, the appearance of the card connector 200 according to the present invention is similar to that of FIG. 1 already described, and includes a thin rectangular housing (main body 200 ′) for inserting and storing the card 290 from above. The upper side surface 204 of the main body 201 is an opening side surface, and has a card storage opening 202 for receiving a card 290 to be inserted. The card 290 inserted from here is locked by The lower end of the card 290 comes into contact with the lower end stopper 231 of the moving slider 230 and stops. The slider 230 and the card 290 are moved together to near the bottom of the main body 201 of the card connector 200 to be in the housed state. The lower portion of the slider 230 is supported by an elastic body 240, and the elastic body 240 always urges upward. It should be noted that a plurality of connector portions (FIG.) 280 for connection are provided on the lower side.
[0017]
The card connector 200 includes a shape memory alloy body 210 slightly below the upper surface portion 204 (opening side surface) of the main body 200 ′ and substantially parallel to the upper side. The shape memory alloy body 210 is a spiral spring body that constantly urges at normal temperature, but when it is energized, itself generates heat, and is deformed to the stored shape or length. It consists of an alloy material having properties. The shape of the shape memory alloy body 210 can be changed by controlling a temperature change accompanying energization and non-energization.
The right end of the shape memory alloy 210 is retained by a stopper 212 on the right side 205 side of the front part 201. When the power is not supplied, the shape memory alloy 210 is directed toward the left side 206 by a natural elastic force at normal temperature. Always energized. A locking body 220 is connected and connected to the left end thereof, and is engaged and connected by an interlocking portion 224.
[0018]
The locking body 220 is a member that rotates around a rotation fulcrum 222 fixedly provided on the main body 200 ′ side, and a hook 226 and an interlocking part 224 are provided on both sides of the center rotation hole 223. It is configured to rotate according to the principle of leverage. A torsion spring 225 is provided on the rotation fulcrum 222, and the hook 226 is constantly urged in the clockwise direction in FIG. 2B. The operation of opening and closing 226 (arrow M20) is performed.
The slider 230, which can move up and down in cooperation with the locking body 220, has a structure in which an upper end surface 232 thereof can contact the lower end surface of the hook portion 226 of the locking body 220. If the upper end surface 232 of the slider 230 is in contact with the lower end surface of the hook portion 226 and is in contact therewith, the slider 230 is at the lowermost position and is in a state of storing a card. If the upper end surface 232 of the slider 230 is not aligned with the hook portion 226, the slider 230 can move upward, and the card is released.
[0019]
The rotation of the hook portion 226 elastically urged restricts the movement of the slider 230 in the vertical direction. When the hook portion 226 of the locking body 220 and the upper end surface 232 of the slider 230 are aligned, the card is The locking mechanism that keeps the position of 290 works to form a structure that cannot be removed while the card is stored. Since the locking body 220 is engaged and connected to the shape memory alloy body 210 at the interlocking portion 224, the natural elastic force of the shape memory alloy body 210 and the expansion and contraction operation due to the change in the energized shape are always interlocked. Perform the operation.
[0020]
Now, with reference to FIG. 2, a procedure for inserting the card 290 into the card connector 200 and storing the card will be described below.
1) When the card 290 is inserted, the lower end of the card 290 contacts the lower end stopper 231 of the slider 230 that can move up and down together with the card, and the card is locked. The slider 230 and the card 290 come together to form the card connector 200. Is moved to the vicinity of the bottom of the main body 201. An arrow M21 indicates a state of the slider 230 moving up and down.
2) When the slider 230 is moved below the locking body 220 and the hook portion 226 of the locking body 220 is tilted clockwise by the elastic force of the torsion spring 225, the position of the slider 230 is fixed downward and the card 290 is located at a predetermined position.
3) The card locking structure is completed.
[0021]
Next, when the users release the state in which the card 290 is stored in the card connector 200, the following procedure is performed.
4) When the user presses the release button in order to remove the card 290, energization of the shape memory alloy body 210 starts, and when a predetermined voltage is applied, the shape memory alloy 210 is reduced and deformed into a shape whose length is reduced.
5) The interlocking part 224 of the locking body 220 is pulled rightward in FIG. 2 by the shape memory alloy body 210, and the hook part 226 of the locking body 220 is turned in the left rotation direction to be in the open state. The slider 230 is moved upward by the upward bias.
6) The card 290 moves and comes out together with the upward movement of the slider 230, so that the card 290 is taken out from the card connector 200.
[0022]
Next, referring to FIG. 3, this figure shows a third embodiment of the card connector of the present invention. FIGS. 3A to 3C are diagrams illustrating a situation in which the card 390 is inserted into the card connector 300 and card locking is performed. 3A shows a front view of the card connector 300, FIG. 3B shows a top view thereof, and FIG. 3C shows a left side view thereof.
[0023]
In FIG. 3, the basic configuration of the card connector 200 according to the present invention is similar to that of FIG. 2 already described, but this card connector 300 is located below the lower surface of the main body 300 and substantially parallel to the upper and lower sides. A shape memory alloy body 310 made of a linear body is provided, and performs movement in conjunction with the locking body 320 and the slider 330. The shape memory alloy body 310 here is a linear body, and has the property of generating heat itself when energized and energized, thereby expanding and contracting to the stored length. In the alloy body 310, the overall length of the linear body is reduced. The shape memory alloy body 310 is a two-folded linear body. The shape memory alloy body 310 is extended from the stop part 312 to the left, and is stopped at the stop part 325 on the interlocking part 324 below the rotating hook-shaped locking body 320. And is returned to the stopper 312. The stopper 312 is formed so as to protrude downward from the right side of the lower side of the front part 301, and is supplied with power E from terminals (313, 314) in the front part 301 and is energized.
[0024]
The two elastic members (340, 350) shown in FIG. 3 are constantly urged by natural elastic force, and the elastic member 340 applies a pressing force to the lower surface of the slider 330 to give a force to move the slider 330 upward. Further, the elastic body 350 applies a pressing force to the right side surface of the interlocking portion 324 below the locking body 320 to rotate the interlocking portion 324 to the left.
The locking body 320 is a member that rotates around a rotation fulcrum 322 fixed to the left side of the main body 300 ′, and has a rotation hook 326 and an interlocking part 324 on the upper and lower sides. It is configured to rotate according to the principle of leverage. In addition, the rotation hook portion 326 of the locking body 320 has a lower end portion 328 so that the rotation hook portion 326 can abut when the upper end surface 332 of the slider 330 is aligned. The locking body 320 performs a horizontal movement (arrow M32) of the rotation hook portion 326 in conjunction with the shape memory alloy body 310, restrains the vertical movement of the slider 330, and allows the card to be inserted or removed. The accompanying card locking operation is performed.
[0025]
The slider 330 that can move up and down in cooperation with the locking body 320 has a structure that can contact the lower end face 328 of the rotating hook 326 of the locking body 320 at the upper end face 332. When the upper end surface 332 of the slider 330 and the lower end surface 328 of the rotating hook portion 326 come to a position where they can abut or lock, the slider 330 is in a state where a card is stored. Also, when the upper end surface 332 of the slider 330 and the lower end surface 328 of the rotating hook 326 are not at a position where they can abut or lock, the slider 330 can move upward and the card is released. State.
[0026]
The locking body 320 affected by the constantly biased elastic body 350 and the shape-memory alloy body 310 that is energized and contracted, and the slider 330 affected by the constantly biased elastic body 340 are at positions where they are locked to each other. Then, the locking mechanism operates, and the card storage state is formed. As described above, the operation of the locking body 320 and the slider 330 is always performed in conjunction with the natural elastic force of the elastic body 350 and the elastic body 360 and the expansion and contraction operation of the shape memory alloy caused by the change in the shape of the energized heat. Perform the operation.
[0027]
Now, referring to FIG. 3, a procedure for inserting the card 390 into the card connector 300 and storing the card 390 will be described below.
1) When the card 390 is inserted, a force to move the rotating hook portion 326 of the locking body 320 rightward by the elastic body 350 is applied, and the right end surface 327 of the locking body 320 and the right end surface 333 of the slider 330 are applied. Are in contact with each other in a state where sliding movement is possible.
2) When the card 390 is inserted, the lower end of the card 290 comes into contact with the lower end stopper 331 of the slider 330 which stops the card and moves up and down together, and the slider 330 and the card 390 come together to form the main body of the card connector 300. It is moved to near the bottom of 301. Here, an arrow M30 indicates how the slider 330 moves up and down.
3) When the slider 330 moves below the lower end surface 328 of the locking body 320, the rotation hook 326 of the locking body 320 is tilted rightward by the elastic body 350, and the upper end surface 332 of the slider 230 is The locking body 320 and the slider 330 are positioned by contacting the lower end surface 328 of the turning hook 326 of the locking body 320. Thus, the locking structure is completed.
[0028]
Next, when the users release the state in which the card 390 is stored in the card connector 300, the following procedure is performed.
4) When the user presses a release button to remove the card 390, the shape memory alloy body 310 starts to be energized and a predetermined voltage is applied.
5) The stopping portion 325 of the locking body 320 is pulled rightward in FIG. 2 by the shape memory alloy body 310, and the turning hook 326 of the locking body 320 is turned leftward to be in an open state. The slider 330 is moved upward by the upward biasing of the elastic body 340.
6) Since the card 390 moves and comes out together with the upward movement of the slider 330, the card 390 is taken out from the card connector 300.
[0029]
Further, referring to FIG. 4, this drawing is a fourth embodiment of the card connector of the present invention. FIGS. 4A to 4C are diagrams illustrating a situation in which the card 490 is inserted into the card connector 400 and card locking is performed. 4A is a front view of the card connector 400, FIG. 4B is a top view thereof, and FIG. 4C is a left side view thereof.
[0030]
4, the basic configuration of the card connector 400 according to the present invention is similar to that of FIGS. 1 to 3 already described, and the card connector 400 is substantially parallel to the left side surface of the main body 401 and has a card opening side surface. Is provided with a shape memory alloy body 410 positioned substantially at a right angle, and performs an operation in conjunction with the locking body 420 and the slider 430. The shape memory alloy body 410 itself generates heat when energized and energized, thereby shortening the length in the vertical direction. The shape memory alloy body 410 is fixed to the base 412 via a stopper 411 on the lower side below, and is connected to the movable part 414 via a stopper 413 above. The movable portion 414 has a locking portion 415 for locking the locking body 420.
[0031]
The two elastic bodies (440, 450) shown in FIG. 4 are constantly urged by natural elastic force, and the elastic body 440 applies a pressing force to the lower surface of the slider 430 to apply a force to move the slider 430 upward. The elastic body 450 applies a pulling force to the turning hook 422 of the locking body 420 to apply a force to turn to the right.
The locking body 420 is a member that rotates around a rotation fulcrum 421 provided fixed to the main body 401, and an arrow M41 indicates a state of the operation. The locking body 420 has a lower end hook portion 424, and in a card storage state, can contact the upper end surface 432 of the slider 430 to restrict upward movement of the slider 430.
[0032]
In addition, the locking body 420 includes a hook locking portion 425 to form a locking relationship with the locking portion 415 of the movable portion 414 of the shape memory alloy body 410.
The locking body 420 is provided with a hook main part 422, which is rotated to the right to lock the left end portion of the upper surface where the card 490 is inserted, thereby locking the card 490. Prevent discharge when spilled. The hook main part 422 opens and closes the upper surface by pivotal movement (arrow M41) to the left and right, and interlocks with the card insertion or removal operation.
[0033]
The slider 430 that can move up and down in cooperation with the left and right rotation of the locking body 420 has a structure that can abut on the upper end surface 432 thereof with the lower end of the hook locking portion 424 of the locking body 420.
If the upper end surface 432 of the slider 430 is in contact with the lower end of the hook engaging portion 424, the slider 430 is located at the lowest position of the main body 401 and the card is stored. Also, when the hook locking portion 424 of the locking body 420 moves rightward, the slider 430 can move upward, and the card is released (taken out).
The operation of rotating the locking body 420 right and left is a structure that is interlocked with the rightward bias of the elastic body 450 and the operation of the hook locking portion 425 that is affected by the expansion and contraction of the shape memory alloy body 410. Therefore, when the locking body 420 rotates rightward, the card is in the card storage state, and when the locking body 420 rotates leftward, the card is released (taken out).
[0034]
Referring now to FIG. 4, a procedure for inserting and storing the card 490 in the card connector 400 will be described below.
1) Before the card 490 is inserted, since the slider 430 is at the upper position, the hook main part 422 of the locking body 420 is relatively moved leftward and is in the open state. When the card 490 is inserted, the slider 430 that has received the card 490 is pushed down and moved to the bottom of the card connector 400.
2) When the slider 430 moves together with the card 490, the hook main part 422 of the locking body 420 is moved rightward by the elastic body 450, the hook locking part 424 moves leftward, and the slider 430 is positioned. Locking is completed.
[0035]
Next, when the users release the state in which the card 490 is stored in the card connector 400, the following is performed.
4) When the user presses the release button in order to remove the card 490, the current is applied to the shape memory alloy 410, and when a predetermined voltage is applied, the length of the shape memory alloy 410 is reduced in the vertical direction.
5) Since the locking portion 414 is moved downward due to the reduction of the shape memory alloy body 410, the locking body 420 engaged with the locking portion 414 like the cam mechanism is turned to the left, and the hook main portion 422 is also moved. It is moved to the left and the card slot is open.
5) Since the locking portion 414 is moved downward due to the reduction of the shape memory alloy body 410, the locking body 420 engaged with this by the hook locking portion 425 like a cam mechanism rotates in the counterclockwise direction. The hook main part 422 is moved to the left, the card insertion slot is opened, and the hook lower end part 424 is moved to the right, so that the elastic body 440 works to move the slider 430 upward.
6) The card 490 is removed from the card connector 400.
[0036]
As described above, according to the card connector of the present invention, the following excellent effects can be obtained.
ADVANTAGE OF THE INVENTION The card connector by this invention is provided with the locking mechanism with high reliability and a compact, and can prevent the accident regarding the data storage accompanying the connection disconnection of a card reliably. In addition, a simple and space-saving configuration can be adopted, and the device can be designed as a strong device that is safe even in the event of a device drop.
As a specific great effect of the card connector according to the present invention, during data access such as when downloading or reading data, removal and removal of the memory card are prevented, and data access is suddenly disconnected. Accidents can be prevented. The effect of the card connector according to the present invention is particularly large when it is used as a visual telephone with a memory card.
[Brief description of the drawings]
FIG. 1 is a configuration explanatory view showing a first embodiment of a card connector according to the present invention.
FIG. 2 is a configuration explanatory view showing a second embodiment of the card connector according to the present invention.
FIG. 3 is a configuration explanatory view showing a third embodiment of the card connector according to the present invention.
FIG. 4 is a configuration explanatory view showing a fourth embodiment of the card connector according to the present invention.
[Explanation of symbols]
100, 200, 300, 400 card connector
100 ', 200', 301, 401 Main body (housing)
110, 130, 210, 310, 410 Shape memory alloy body
120, 220, 320, 420 Locking body
230, 330, 430 slider
240, 340, 350, 440 elastic body
140 stopper

Claims (6)

A card connector including a thin rectangular housing for storing a card therein,
One of the four sides around the housing is an opening side provided with an opening for inserting and removing a card,
In the housing, a shape memory alloy body that expands and contracts in the longitudinal direction by energization is disposed substantially parallel to the side surface of the opening, with one end thereof fixed.
At the movable end of the shape memory alloy body, a locking body that performs an operation of locking the card in conjunction with the expansion and contraction operation is disposed,
A card connector characterized by being constituted. The card connector according to claim 1,
A card connector, comprising: elastic means for restraining the locking body separately from the shape memory alloy body in order to hold the position of the locking body with operation. The card connector according to claim 1,
The card connector according to claim 1, wherein the housing includes a slider body that stops the card and performs a movement operation with the card in and out of the card. The card connector according to claim 3,
The locking body includes means for restraining the movement of the slider body.
A card connector, characterized in that: The card connector according to claim 3 or 4,
The card connector according to claim 1, wherein the housing includes elastic means for applying a pressing force to the slider body in a card removal direction. A card connector including a thin rectangular housing for storing a card therein,
One of the four sides around the housing is an opening side provided with an opening for inserting and removing a card,
In the housing, a shape memory alloy body that expands and contracts in the longitudinal direction by energization is disposed substantially at right angles to the side surface of the opening, and one end side thereof is fixed,
At the movable end of the shape memory alloy body, a locking body that performs an operation of locking the card in conjunction with the expansion and contraction operation is disposed,
In order to hold the position of the locking body with the operation, separately from the shape memory alloy body, the housing is provided with elastic means for applying a tensile force to the locking body, and the housing stops the card and moves in and out together with the card. Equipped with a slider body that performs
The locking body includes means for restraining the movement of the slider body,
The card connector, wherein the housing is provided with elastic means for applying a pressing force to the slider body in a card removal direction.

Images