DE102011082722B4 - ELECTRONIC DEVICE - Google Patents

Abstract

Electronic device with:
- a printed circuit board (60) having a plurality of electrodes (61) on at least one surface of surfaces (60a, 60b) of an end portion of the printed circuit board (60);
- A first housing (80) in which the circuit board (60) is housed and having an opening; and
a card edge connector (20) comprising
- A second housing (30) having a first side (30 a), a second side (30 b) and a third side (30 b), wherein the second side (30 b) and the third side (30 b) on opposite sides adjacent to the first side (30a), the second housing (30) defines a groove (31) which is open on the first side (30a) and continuous in a first direction (D1) in the second side (30b) and the third side (30b) extends; and
a plurality of terminals (40) held in the second housing (30), the terminals (40) having terminal projections (42, 42a, 42b) extending from at least one inner surface of inner surfaces (31a, 31b) of the groove (31) protrude into the groove (31), the inner surfaces (31a, 31b) in a second direction (D2), which is perpendicular to the first direction (D1), opposite, the terminal projections (42, 42a, 42b) in a third direction ( D3) perpendicular to the first direction (D1) and the second direction (D2), and the terminal projections (42) have contact portions (41, 41a, 41b) for contacting the electrodes (61)
- In a state in which a part of the second housing (30) is arranged with the groove (31) over the opening in the first housing (80), the end portion of the circuit board (60) is received in the groove (31) and the contact portions (41, 41a, 41b) of the terminal projections (42) contact the electrodes (61), characterized in that
a rotation element (50) is rotatably held in the card edge connector (20);
- The rotary member (50) has a rotating part (51) and first projections (52);
- The rotating part (51) in the groove (31) in the first direction (D1) closer than the contact portions (41) of the connection projections (42) to a bottom portion (31c) of the groove (31) is arranged;
the rotating part (51) rotates about a rotation axis (C1) defined in the third direction (D3) and adapted to contact extended portions (47a, 47b) of the terminal projections (42, 42a, 42b), which extend from the contact portions (41, 41a, 41b) toward the bottom portion (31c) of the groove (31), around the terminal projections (42, 42a, 42b) in accordance with rotation of the rotary member (51) in the second direction To move (D2);
- the first projections (52) in the third direction (D3) are connected to opposite ends of the rotary member (51) to rotate with the rotary member (51) and located outside the groove (31);
- said first housing (80) has second protrusions (82) each protruding from an inner surface of said first housing (80) corresponding to said first protrusions (52);
in an initial state in which the end portion of the circuit board (60) is not received in the groove (31), the contact portion (41, 41a, 41b) of each terminal projection (42, 42a, 42b) is held at a position at which a distance between the inner surface (31a, 31b) of the groove (31) and the contact portion (41, 41a, 41b) in the second direction (D2) is greater than a distance between the inner surface (31a, 31b) of the groove (31) and the surface (60a, 60b) of the end portion of the circuit board (60) on which the electrodes (61) are disposed; and
- When inserting the end portion of the printed circuit board (60) in the groove (31) and when removing the end portion of the printed circuit board (60) from the groove (31) of the rotary member (51) with the first projections (52) in a first rotational direction after the first protrusions (52) hit the second protrusions (82) and until the first protrusions (52) abut the second protrusions (82), and begins with the first protrusions (52) in a second rotational direction rotate counter to the first rotational direction when the first projections (52) exceed the second projections (82), wherein the terminal projections (42, 42 a, 42 b) in accordance with the rotation of the rotary member (51) in the first rotational direction toward the inner surface (31a, 31b) are moved so that the contact portions (41, 41a, 41b) are separated from the surface (60a, 60b) of the end portion of the circuit board (60), and the terminal projections (42, 42a, 42b) in accordance with the rotation of the rotary member (51) in the second direction are moved back toward the surface (60a, 60b) of the end portion of the printed circuit board (60), so that when inserting the end portion of the printed circuit board (60) into the groove (31) in that the contact portions (41, 41a, 41b) are brought into contact with the electrodes (61).

Description

The present invention relates to an electronic device having a printed circuit board and a card edge connector which receives an edge of the printed circuit board.

A card edge connector, for example, in the JP 2003-178834 A described. In the described card edge connector, an edge of a circuit board is inserted into a housing such that a plurality of electrodes provided on the surface of the edge of the circuit board are brought into contact with contact portions of terminals exposed from the housing so as to make an electrical connection , The circuit board serves as a plug.

In such a card edge connector, the contact portions of the terminals contact the electrodes stably due to resiliency of the terminals. Consequently, when the printed circuit board is inserted into the housing or removed from the housing, in the event that the contact portions of the terminals contact the printed circuit board, such as the edge of the printed circuit board or the surface of the printed circuit board on which the electrodes are formed, the connections are damaged. For example, a plated layer on the terminals is peeled off, or the terminals may be deformed. The plated layer peeled off the terminals may cause a short circuit, resulting in deterioration of electrical reliability.

Further relevant prior art is known from the JP H05-290 934 A ,

It is therefore an object of the present invention to provide an electronic device with a card edge connector having improved electrical reliability.

The object is achieved by the features of claim 1.

According to a first aspect of the present invention, an electronic device includes a circuit board, a first housing, and a card edge connector. The circuit board has a plurality of electrodes on at least one surface of surfaces of an end portion of the circuit board. In the first housing, the circuit board is housed, and the first housing has an opening. The card edge connector has a second housing and connectors. The second housing defines a groove to receive the end portion of the circuit board therein. The groove is open on a first side of the second housing and extends in a first direction continuously to a second side and a third side of the second housing, wherein the second side and the third side are opposite sides of the first side. The connections are held in the second housing. The terminals have terminal protrusions protruding from at least one inner surface of inner surfaces of the groove into the groove, facing the inner surfaces in a second direction that is perpendicular to the first direction. The terminal projections are aligned in a third direction that is perpendicular to the first direction and the second direction. Each of the terminal protrusions has a contact portion to contact the electrodes. In a state where a part of the second housing having the groove is disposed in the first housing, the end portion of the circuit board is disposed in the groove, and the contact portions of the terminal projections contact the electrodes.

The electronic device further includes a rotation member rotatably supported in the card edge connector. The rotary member has a rotating part disposed in the groove and first protrusions connected to the rotating part and rotatable with the rotating part. The rotary member is disposed in the groove in the first direction closer than the contact portions of the terminal protrusions to a bottom portion of the groove. The rotating member rotates about an axis of rotation defined in the third direction, and is configured to contact extended portions of the terminal protrusions extending from the contact portions toward the bottom portion of the groove to turn the terminal protrusions in accordance with rotation of the first protrusion Rotate rotating parts in the second direction. The first protrusions are connected in the third direction to opposite ends of the rotary member to rotate with the rotary member and disposed outside the groove. The second housing has second protrusions respectively protruding from an inner surface of the second housing corresponding to the first protrusions.

In an initial state in which the end portion of the circuit board is not received in the groove, the contact portion of each terminal projection is held at a position at which a distance between the inner surface of the groove and the contact portion in the second direction is greater than a distance between the Inner surface of the groove and the surface of the circuit board is, on which the electrodes are arranged.

When inserting the circuit board into the groove and upon removal of the end portion of the circuit board from the groove, the rotation part rotates with the first projections in a first one In the rotational direction, after the first protrusions hit the second protrusions and until the first protrusions abut on the second protrusions, the rotary part starts to rotate with the first protrusions in a second rotational direction opposite to the first rotational direction when the first protrusions are the second protrusions exceed. The terminal protrusions are moved toward the inner surface in accordance with the rotation of the rotary member in the first rotational direction, so that the contact portions are separated from the surface of the end portion of the printed circuit board. Further, the terminal protrusions are moved back toward the surface of the end portion of the printed circuit board in accordance with rotation of the rotary member in the second direction, so that when the printed board is inserted into the groove, the contact portions are brought into contact with the electrodes.

In such a structure, when inserting the end portion of the circuit board into the groove and removing the end portion of the circuit board from the groove, the first protrusions of the rotation member contact the second protrusions of the second housing. The end portion of the circuit board is further inserted or removed from the groove so that the first projections "climb up" the second projections. As a result, the rotary part is rotated in the first rotational direction. The rotary member moves the terminal projections during rotation in the first rotational direction toward the inner surface of the groove and away from the printed circuit board. Consequently, the contact portions of the terminal protrusions are brought to a position without contacting the circuit board.

The terminal protrusions are elastically deformed by being pressed by the rotary member when the rotary member rotates in the first rotational direction. Consequently, when the first protrusions have exceeded the second protrusions, the rotary part starts to rotate in the second rotational direction by the elasticity of the elastically deformed terminal protrusions. As a result, the terminal protrusions are moved away from the inner surface of the groove. Consequently, the contact portions are brought into contact with the electrodes of the circuit board upon insertion of the end portion of the circuit board into the groove. Since the contact portion of the terminal protrusions in the initial state in the second direction is located farther from the inner surface than the surface of the printed circuit board, the contact portions can securely contact the electrodes. Upon removal of the end portion of the circuit board from the groove, the contact portions of the terminal protrusions are returned to the initial state position due to the rotation of the rotation member in an opposite direction.

In this way, damage and unexpected deformation of the contact portions of the terminals can be reduced because the contact portions of the terminal are separated from the circuit board when the end portion of the circuit board is inserted into the groove or removed from the groove. Consequently, electrical reliability of the electronic device can be improved.

• 1 eine Querschnittsansicht einer elektronische Vorrichtung gemäß einer Ausführungsform der vorliegenden Erfindung;
• 2 eine Querschnittsansicht entlang einer Linie II-II in der 1;
• 3 eine Querschnittsansicht entlang einer Linie III-III in der 2;
• 4(a) eine Perspektivansicht eines Rotationselements der elektronischen Vorrichtung der Ausführungsform;
• 4(b) eine Draufsicht des Rotationselements entlang einer Rotationsachse;
• 5(a) bis 5(d) Ansichten zur Veranschaulichung eines Prozesses zum Einfügen einer Leiterplatte in eine Nut eines Gehäuses der elektronischen Vorrichtung der Ausführungsform;
• 6(a) bis 6(d) Abbildungen zur Veranschaulichung eines Prozesses zum Entfernen der Leiterplatte aus dem Gehäuse der Ausführungsform;
• 7(a) und 7(b) Draufsichten von Modifikationen eines ersten Vorsprungs des Rotationselements der Ausführungsform;
• 8(a) und 8(b) Draufsichten von Modifikationen eines Rotationsteils des Rotationselements der Ausführungsform;
• 9(a) eine Perspektivansicht einer Modifikation eines Gehäuses, das ein Rotationselement der Ausführungsform hält;
• 9(b) eine Querschnittsansicht entlang einer Linie IXB-IXB in der 9(a); und
• 9(c) eine Querschnittsansicht entlang einer Linie IXC-IXC in der 9(b).

Other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings in which like parts are given the same reference numerals. In the drawings:

• 1 a cross-sectional view of an electronic device according to an embodiment of the present invention;
• 2 a cross-sectional view along a line II-II in the 1 ;
• 3 a cross-sectional view along a line III-III in the 2 ;
• 4 (a) a perspective view of a rotary member of the electronic device of the embodiment;
• 4 (b) a plan view of the rotary member along a rotation axis;
• 5 (a) to 5 (d) Views for illustrating a process of inserting a printed circuit board into a groove of a housing of the electronic device of the embodiment;
• 6 (a) to 6 (d) Illustrative illustrations of a process for removing the circuit board from the housing of the embodiment;
• 7 (a) and 7 (b) Top views of modifications of a first projection of the rotary member of the embodiment;
• 8 (a) and 8 (b) Plan views of modifications of a rotary part of the rotary member of the embodiment;
• 9 (a) a perspective view of a modification of a housing that holds a rotary member of the embodiment;
• 9 (b) a cross-sectional view along a line IXB-IXB in the 9 (a) ; and
• 9 (c) a cross-sectional view along a line IXC-IXC in the 9 (b) ,

Hereinafter, an exemplary embodiment of the present invention is under With reference to the accompanying drawings, in which like parts are given the same reference numerals.

An electronic device 10 In general, as in 1 shown a card edge connector or card edge connector 20 , a circuit board 60 and a housing 80 as main components. 1 shows a mounting state in which the circuit board 60 in a groove 31 a housing 30 of the card edge connector 20 is included. In contrast, a state in which the circuit board 60 not in the groove 31 of the housing 30 is inserted (such as in the 5 (a) ), referred to as the initial state.

The card edge connector 20 serves as a forwarding element for an electrical connection of the printed circuit board 60 and a wiring harness 32 which is used to allow connection to an external device. The card edge connector 20 generally indicates the housing 30 , Connections 40 and a rotation element 50 as main components. The connections 40 be from the case 30 held. The rotation element 50 is rotatable by the housing 30 held.

The housing 30 is constructed of an electrically insulating element and formed for example by resin injection. The housing 30 has the groove 31 as an accommodation space for accommodating the circuit board 60 on. The groove 31 defined as in the 1 to 3 shown an opening on an end surface 30a of the housing 30 , The groove 31 has a predetermined width in accordance with the thickness of the circuit board 60 and a predetermined depth in accordance with an insertion depth of the circuit board 60 on.

The groove 31 defines openings on both side surfaces 30b of the housing 30 , That is, the groove 31 is at the end surface 30a and both side surfaces 30b of the housing 30 continuously opened. More precisely, the case 30 has a first side, which is the end surface 30a defined, and a second and a third page on which the side surfaces 30b define on opposite sides of the first page. The groove 31 is on the first page 30a opened and extends to the second and third page 30b ,

Hereinafter, a depth direction of the groove 31 , such as a right-left direction in the 1 , as first direction or depth direction D1 and a width direction of the groove 31 or a thickness direction of the circuit board 60 , such as an up-down direction in the 1 , as a second direction or width direction D2 designated. Further, a direction becomes perpendicular to the depth direction D1 and to the width direction D2 referred to as the third direction. The first direction D1 also corresponds to an insertion and removal direction of the circuit board 60 with respect to the housing 30 ,

The housing 30 has an accommodation room 33 for housing the wiring harness 32 on. When the wiring harness 32 in the accommodation room 33 is inserted, the wiring harness 32 and the connections 40 electrically connected to each other. Furthermore, the housing has 30 a sealing element 34 on an outer peripheral surface.

The sealing element 34 For example, is constructed of silicone rubber and has a ring shape. Consequently, if the housing 30 in the case 80 is inserted, the outer peripheral surface of the housing 30 with the inner surface of the housing 80 sealed to allow entry of water or the like into an interior space 81 of the housing 80 to restrict. The outer peripheral surface of the housing 30 Although not shown in the drawings, has an engaging portion to the housing 30 in engagement with the housing 80 bring to.

The housing 30 For example, it can be constructed from a single piece / element. As another example, the housing may 30 be formed by, several pieces / elements are interconnected.

The connections 40 are made of a metal with a favorable electrical conductivity. The terminals are formed, for example, by plating phosphor bronze with nickel and further gold plating it.

Each of the connections 40 sticks out as in 3 shown from an inner surface 31a . 31b the groove 31 partly in the groove 31 to a connection projection 42 to build. The connection tab 42 has a first contact section (contact point) 41 on, in the attachment state, a contact with an electrode (pad) 61 which is attached to one edge of the circuit board 60 is formed. The connection tab 42 is elastically deformable.

The first contact section 41 contacts the electrode 61 in a state in which the terminal projection 42 is elastically deformed. Consequently, a stable contact pressure between the electrode 61 and the terminal projection 42 guaranteed.

In the present embodiment, the terminals are 40 on opposite sides of the groove 31 arranged. That is, the terminal protrusions 42 protrude from the two inner surfaces 31a . 31b the groove 31 in the groove 31 , The connection projections 42 are on opposite sides the circuit board 60 arranged. Below are the terminal projections 42 coming from the first inner surface 31a protrude, even as the first terminal projections 42a referred, and the terminal projections 42 coming from the second inner surface 31b protrude, even as the second terminal protrusions 42b designated.

The circuit board 60 is due to the elasticity (biasing force) of the terminal projections 42 attached to the opposite sides of the circuit board 60 be elastically deformed. The first connection projections 42a and the second terminal projections 42b are arranged line-symmetrically to an imaginary center line extending in the first direction D1 between the first inner surface 31a and the second inner surface 31b extends. The elasticity of the connection projections 42 is between both sides of the circuit board 60 balanced. That is, the first terminal protrusions 42a and the second terminal projections 42b have substantially the same elasticity. Consequently, the circuit board 60 through the first and second terminal projections 42a . 42b essentially at a middle position of the groove 31 in the second direction D2 held.

The contact sections 41 the connections 40 are in the third direction D3 aligned. Consequently, the third direction D3 also referred to as alignment direction.

The rotation element 50 has a rotation part 51 up in the groove 31 is arranged. The rotation part 51 contacted an extended section 47 each connection tab 42 at least during one rotation of the rotary part 51 , The extended section 47 extends from the first contact portion 41 in the direction of a groove end (ie bottom portion) 31c of the groove 31 , Below is the section of the extended section 47 , which is the rotation part 51 contacted, as a second contact section 43 designated.

In the present embodiment, the extended portion contacts 47 the rotation part 51 on the second contact section 43 not only in a rotation state in which the rotation part 51 rotates (ie during insertion and removal of the circuit board 60 ), but also in the initial state and in the attachment state. The position of the second contact section 43 changes in accordance with the rotation of the rotation part 51 in the first direction D1 and the second direction D2 ,

The extended section 47 which the second contact portion 43 forms, runs in the initial state, in the rotation state and in the attachment state substantially parallel to the first direction D1 , Because the connection projections 42 on the opposite sides of the rotating part 51 are provided, the rotation part 51 in the middle of the groove 31 in the second direction D2 held.

In the present embodiment, as shown in FIG 2 shown the connections 40 power connections 44 for power transmission and signal connections 45 for signal transmission. Each of the signal connections 45 has a cross-sectional area less than that of each of the power terminals 44 is.

The connection 40 has a third contact portion that makes contact with the wiring harness 32 manufactures. The third contact portion is in a part of the terminal 40 included in the accommodation room 33 exposed. The accommodation room 33 is at an end surface of the housing 30 opposite the end surface 30a in the first direction D1 open. Consequently, the circuit board 60 and the wiring harness 32 in a state in which the wiring harness 32 in the accommodation room 33 is included, over the connectors 40 electrically connected to each other. According to another example, a connector that is integral with the wiring harness 32 is formed, as the connection 40 be used.

The rotation element 50 is designed to be the terminal projections 42 in accordance with the insertion and removal of the circuit board 60 in the second direction D2 to move so as to damage the first contact sections 41 during insertion and removal of the circuit board 60 to reduce. In particular, the rotation element 50 designed to the terminal projections 42 in or with respect to the second direction D2 by moving the force along the insertion and removal direction (ie the first direction D1 ) in a force along the second direction D2 is converted when the housing 30 with the housing 80 is connected, in which the circuit board 60 is held.

The rotation element 50 becomes rotatable in the card edge connector 20 held. The rotation element 50 has the rotation part 51 and first protrusions 52 on. The rotation part 51 will be in the groove 31 held and is about an axis of rotation C1 that are in the third direction D3 extends, rotatable. The first projections 52 are with opposite ends of the rotating part 51 connected and with the rotation part 51 rotatable.

The rotation part 51 is how in 3 shown adjacent to the groove end 31c inside the groove 31 arranged. That is, the rotary part 51 is in the first direction D1 closer than the first contact section 41 to the groove end 31c arranged. Furthermore, the rotating part 51 a shape which the extended portion 47 each connection tab 42 contacted and the connection tab 42 during rotation in the second direction D2 shifts. In particular, the rotary part 51 adapted to the position of the second contact portion 43 in the first direction D1 and the second direction D2 change by the rotation part 51 is rotated.

The rotation part 51 indicates when viewed along the third direction D3 , as in 4 (b) shown an elliptical outline. That is, the rotary part 51 has an elliptical cross-section in a cross-sectional plane perpendicular to the third direction D3 is defined. The center of the elliptical cross-section coincides with the axis of rotation C1 match.

The rotation part 51 contacts the extended section 47 in a range within 90 degrees of a first intersection 54 that is between a minor axis A1 of the elliptical cross section and the elliptical outline is defined, to a second intersection 55 that is between a major axis A2 of the elliptical cross section and the elliptical outline is defined when the rotation part 51 rotates. More specifically, the extended section 47 contacts the area of the rotation part 51 , and the second contact portion 43 is provided by the section in which the extended section 47 the rotation part 51 contacted.

That is, the outline of the rotation part 51 runs point-symmetrical to the axis of rotation C1 , Furthermore, the rotary part 51 formed such that a distance between the axis of rotation C1 and the second contact portion 43 is minimal in the initial state and with the amount of rotation of the rotating part 51 in a direction (such as the first rotational direction) in accordance with the insertion or removal of the circuit board 60 increases. Further, the distance is maximum when the rotation in the first rotation direction is stopped and before the rotation part 51 begins to rotate in an opposite direction (such as the second direction of rotation).

The rotation part 51 is between the first terminal projections 42a and the second terminal protrusions 42b held. Consequently, the rotation part becomes 51 by the elasticity of the elastically deformed connection projections 42a . 42b at a predetermined position with respect to the second direction D2 held. Consequently, the rotation part becomes 51 rotatable in the card edge connector 20 held. The rotation part 51 is through the first and second terminal projections 42a . 42b for example, at a middle position of the groove 31 in the second direction D2 held when the first and the second terminal projections 42a . 42b have the elastically deformed state.

The first projections 52 are along the two side surfaces 30b of the housing 30 outside the groove 31 arranged. The first projections 52 protrude from the rotation part 51 and extend in a direction perpendicular to the third direction D3 , The rotation part 51 is turned when the first protrusions 52 in contact with the second protrusions 82 of the housing 80 brought in accordance with the insertion or removal of the circuit board 60 ,

In the present embodiment, the first projections extend 52 , as in 4 (b) shown from the middle of the rotation part 51 along the minor axis A1 and end on the outside of the elliptical outline. The sections of the first protrusions 52 which the second projections 82 of the housing 80 contact, have a rounded concave shape, such as an R-shape.

The first projections 52 are for example via connecting sections 53 in one piece with the rotary part 51 educated. That is, the first protrusions 52 and the rotation part 51 form a single part of the rotary element 50 , Each of the connecting sections 53 has a circular outline. That is, the connecting portion 53 points in a cross-sectional plane that is in a direction perpendicular to the third direction D3 is defined as having a circular cross section, and the center of the circular cross section is coincident with the axis of rotation C1 match.

Alternatively, the rotation element 50 the connecting sections 53 do not have. In such a case, the first projections are 52 in the third direction D3 with the ends of the rotating parts 51 connected and extend the first projections 52 in the direction perpendicular to the third direction D3 to the outside of the outline of the rotating part 51 ,

The card edge connector having the structure described above 20 forms together with the circuit board 60 and the housing 80 the electronic device 10 , The circuit board 60 points the electrodes 61 on both surfaces. Consequently, the number of times through the card edge connector 20 extending electrical connection paths are effectively increased.

The housing 80 has a bag or cap shape, which the interior 81 in the case 80 Are defined. The circuit board 60 is in the case 80 arranged. The housing 80 is designed to be the case 30 with the circuit board 60 up to one To take up position in the first direction D1 deeper than the groove end 31c lies. If the case 30 for example, in the housing 80 is arranged, is the groove end 31c in the first direction D1 inside the case 80 arranged.

The housing 80 may be provided in the form of a single element. Alternatively, the housing 80 be formed by several parts are connected together.

The second projections 82 protrude from an inner surface of the housing 80 out, in places, which the first protrusions 52 of the rotary element 51 correspond. When the first protrusions 52 the second protrusions 82 in accordance with the insertion or removal of the circuit board 60 contact, becomes the rotation part 51 with the first projections 52 turned so that the terminal projections 42 inside the groove 31 to be moved.

In the present embodiment, the second projections protrude 82 as in the 2 and 3 shown from an inner surface of the housing 80 that is perpendicular to the second direction D2 runs, protrudes and extend the second projections 82 in the second direction D2 , The ends of the second protrusions 82 which make contact with the first protrusions 52 have a rounded convex shape, such as an R-shape.

Because the ends of the first protrusions 52 and the ends of the second protrusions 82 have the rounded convex shapes, the circuit board 60 easily into the card edge connector 20 inserted or from the card edge connector 20 away. The second projections 82 can on inner surfaces of the housing 80 be arranged perpendicular to the third direction D3 run.

Hereinafter, a function of the terminal protrusions 42 and the rotation element 50 if the circuit board 60 in the groove 31 of the card edge connector 20 is inserted, ie when the housing 80 in engagement with the housing 30 is brought with reference to the 5 (a) to 5 (d) described.

In the 5 (a) to 5 (d) and the 6 (a) to 6 (d) describes the reference numeral 41a the first contact section 41 the first terminal projections 42a and describes the reference numeral 41b the first contact section 41 the second terminal projections 42b , Furthermore, the reference number describes 43a the second contact section 43 the first terminal projections 42a and describes the reference numeral 43b the second contact section 43 the second terminal projections 42b , The reference number 60a describes a first surface of the circuit board 60 on which the electrodes 61 are formed and which of the first inner surface 31a the groove 31 opposite, and the reference numeral 60b describes a second surface of the circuit board 60 on which the electrodes 61 are formed and which of the second inner surface 31b the groove 31 opposite. The reference number 47a describes the extended section 47 of the first terminal projection 42a and the reference numeral 47b describes the extended section 47 of the second terminal projection 42b ,

When in the case 80 held circuit board 60 in the groove 31 of the housing 30 is inserted, the first projections contact 52 of the rotary element 50 , as in 5 (a) shown the second protrusions 82 of the housing 80 before the edge 60c the circuit board 60 the first and second terminal projections 42a . 42b contacted. That is, the first protrusions 52 Contact the second projections 82 before the edge 60c the circuit board 60 the first contact sections 41a . 41b the first and second terminal projections 42a . 42b in the first direction D1 reached. Until the first projections 52 the second protrusions 82 Contact, the terminal projections 42 and the rotation element 50 held at their respective positions of the initial state.

In the initial state is a distance between the first inner surface 31a and the first contact section 41a of the first terminal projection 42a , as in 5 (a) shown in the second direction D2 greater than a distance between the first inner surface 31a and the first surface 60a the circuit board 60 , In the same way is a distance between the second inner surface 31b and the first contact section 41b of the second terminal projection 42b greater than a distance between the second inner surface 31b and the second surface 60b the circuit board 60 , More specifically, a distance between the first contact portion 41a of the first terminal projection 42a and the first contact section 41b of the second terminal projection 42b in the second direction D2 is less than a thickness t1 of the circuit board 60 ,

Consequently, in the attachment state, the contact pressure between the first contact portions 41a . 41b and the electrodes 61 by the elasticity of the first and second terminal projections 42a . 42b , which are elastically deformed, be ensured. The present embodiment is configured such that the distance between the first contact portions 41a . 41b less than the thickness t1 of the circuit board 60 is the first contact sections 41a . 41b but do not touch each other.

The first and second terminal projections 42a . 42b are arranged line symmetrically to the imaginary line, in the second direction D2 along the middle of the groove 31 runs and is in the first direction D1 extends, so that the first and second terminal projections 42a . 42b have substantially the same elasticity (spring force). The extended sections 47a . 47b the first and second terminal projections 42a . 42b contact the rotation part 51 not only in the rotation state, but also in the initial state and in the attachment state. The rotation part 51 receives the elasticity of the first and second terminal projections 42a . 42b when the first and second terminal projections 42a . 42b be elastically deformed. Consequently, the rotation part becomes 51 through the first and second terminal projections 42a . 42b always held at the middle position, at which the axis of rotation C1 of the rotary part 51 essentially with the middle of the groove 31 in the second direction D2 matches.

In the initial state contact the extended sections 47a . 47b the rotation part 51 at the first intersections 54 the outline of the rotation part 51 , That is, the second contact portions 43a . 43b are at the first intersections 54 the outline of the rotation part 51 arranged. Here is a distance between each second contact section 43a . 43b and the rotation axis C1 defined in the initial state as rotation radius r1. Further, the distance between the first contact portions 41a . 41b in the second direction D2 as a distance L1 Are defined.

In the initial state, the minor axis is right A1 of the elliptical cross section of the rotating part 51 with the second direction D2 coincide and extend the first projections 52 along the second direction D2 , Furthermore, the main axis is correct A2 of the elliptical cross section of the rotating part 51 in the initial state with the first direction D1 match.

If the circuit board 60 from the in the 5 (a) shown state in which the first projections 52 the second protrusions 82 Contact, continue in the direction of the groove end 31c is inserted, the first projections 52 through the second protrusions 82 pressed, which deals with the circuit board 60 in the first direction D1 move. Consequently, the rotation part starts 51 as indicated by an arrow in the 5 (b) shown with the first protrusions 52 in one direction (such as the first direction) to rotate.

In this way, the main axis A2 then when the rotation part 51 in the first direction D1 rotated, with respect to a direction parallel to the first direction D1 inclined. As a result, the first terminal protrusion becomes 42a who is in contact with the rotary part 51 is located from the position of the initial state toward the first inner surface 31a emotional. In the same way, the second connection projection 42b who is in contact with the rotary part 51 is located from the position of the initial state toward the second inner surface 31b emotional.

That is, the opposite terminal protrusions 42a . 42b become from the positions of the initial state in accordance with the rotation of the rotating part 51 spatially wider from each other. Because the first contact sections 41a . 41b towards the interior surfaces 31a respectively. 31b be crowded become the first contact sections 41a . 41b from the first and the second surface 60a . 60b the circuit board 60 away. In this way, the first and second terminal projections are moved to the positions where the first contact portions 41a . 41b the circuit board 60 do not contact.

This movement of the first contact sections 41a . 41b to the position where the first contact sections 41a . 41b the circuit board 60 Do not contact, as in 5 (b) shown before the edge 60c the circuit board 60 the first and second terminal projections 42a . 42b contacted, ie before the edge 60c the first contact sections 41a . 41b in the first direction D1 reached.

A distance (rotation radius) r2 between each first contact section 43a . 43b and the rotation axis C1 in the state of 5 (b) is greater than the distance r1 in the 5 (a) shown initial state. Further, a distance L2 between the first contact sections 41a . 41b in the second direction D2 in the state of 5 (b) greater than the distance L1 in the initial state of 5 (a) ,

5 (c) shows a state in which the rotary part 51 with the first projections 52 continue in the first direction D1 rotates and the ends of the first protrusions 52 the upper ends of the second protrusions 82 reach by the circuit board 60 continue in the direction of the groove end 31c is inserted. Ie., 5 (c) shows the state in which the first protrusions 52 at an upper reversal point.

In the stage of 5 (c) is the edge 60c the circuit board 60 in the first direction D1 continue to the inside of the groove 31 arranged as the first contact sections 41a . 41b , That is, the edge 60c the circuit board 60 has in the first direction D1 already the first contact sections 41a . 41b happens. Furthermore, a distance (radius of rotation) r3 between each of the second contact sections 43a . 43b and the rotation axis C1 bigger than those in the 5 (a) and 5 (b) shown distances r1 . r2 , Further, a distance L3 between the first contact sections 41a . 41b in the second direction D2 bigger than those in the 5 (a) and 5 (b) shown distances.

The amount of elastic deformation of the first and second terminal protrusions 42a . 42b decreases with an increase in the amount of rotation of the rotating part 51 from the initial state to. In the present embodiment, the opposite terminal projections 42a . 42b the substantially same elasticity and are the second contact portions 43a . 43b point-symmetrical to the axis of rotation C1 arranged. Consequently, the rotation part 51 be rotated while the rotation axis C1 in the second direction D2 essentially held in the same position.

Subsequently, the circuit board 60 from the state in which the first protrusions 52 at the upper reversal point, continue in the direction of the groove end 31c inserted, exceed the first projections 52 completely the second protrusions 82 and take the first protrusions 52 a released or free state. Accordingly, the rotary part begins 51 , as in 5 (d) shown due to the elasticity of the elastically deformed terminal projections 42a . 42b (ie, due to the energy released from the elastically deformed state) to rotate in an opposite direction to rotate (such as a second rotational direction).

As a result, the first and second terminal protrusions become 42a . 42b from the inner surfaces 31a . 31b moved away, ie return the first and the second terminal projections 42a . 42b back to the starting position. This causes the first contact sections 41a . 41b in contact with the electrode 61 on the first and the second surface 60a . 60b the circuit board 60 to be brought.

In the present embodiment, the first and second terminal projections are reversed 42a . 42b and the rotation element 50 , as in 5 (d) shown, back to the positions corresponding to those in the initial state. Consequently, a distance (rotation radius) r4 between each of the second contact sections 43a . 43b and the rotation axis C1 equal to the distance r1 in the 5 (a) shown state. In contrast, there is a gap L4 between the first contact sections 41a . 41b in the second direction D2 greater than the distance L1 and substantially equal to the thickness t1 the circuit board 60 because the circuit board 60 between the first contact sections 41a . 41b is available. Consequently, the first contact sections hold 41a . 41b a state of stable contact with the electrodes 61 ,

The first and second terminal projections 42a . 42b and the rotation element 50 return to the positions equal to those in the initial state. Consequently, the rotation part 51 by the elasticity of the elastically deformed connection projections 42a . 42b also in the fastening state in the middle of the groove 31 in the second direction D2 being held.

The following will be a function of the rotation element 50 if the circuit board 60 out of the groove 31 of the card edge connector 20 is removed, ie when the housing 30 from the case 80 is resolved with reference to the 6 (a) to 6 (d) described.

The circuit board 60 will, as in 6 (a) shown in the 5 (d) shown attachment state moves in one direction to the circuit board 60 in the first direction D1 out of the groove 31 of the housing 30 to remove. In this case, contact the first projections 52 of the rotary element 50 first the second projections 82 , The first and the second protrusions 42a . 42b and the rotation element 50 are held at their respective positions of the attachment state until the first projections 52 the second protrusions 82 to contact.

Subsequently, the first projections 52 then, if the circuit board 60 is further moved from the state in which the first projections 52 in contact with the second protrusions 82 are located, with the movement of the circuit board 60 , as in 6 (b) shown against the second projections 82 pressed. Consequently, the rotary part rotates 51 with the first projections 52 in the second direction of rotation.

When the rotation part 51 rotated in the second direction of rotation, the main axis A2 of the elliptical cross section of the rotating part 51 with respect to a direction parallel to the first direction D1 inclined. As a result, the first terminal protrusions become 42a through the rotation part 51 from the position of the attachment state toward the first inner surface 31a emotional. In the same way, the second connection projections 42b through the rotation part 51 from the position of the attachment state toward the second inner surface 31b emotional.

That is, the opposite terminal protrusions 42a . 42b be through the rotation of the rotating part 51 spatially separated from each other from the position of the attachment state. As a result, the first contact portions are removed 41a . 41b from the first and the second surface 60a . 60b the circuit board 60 and come the first contact sections 41a . 41b the respective inner surface 31a . 31b Near. That is, the first contact portions 41a . 41b are moved to the position without the PCB 60 to contact or to touch.

The movement of the first contact sections 41a . 41b to the position without contacting the circuit board 60 done as in 6 (b) shown before the edge 60c the circuit board 60 in the first direction D1 completely from the first contact sections 41a . 41b has removed.

If the circuit board 60 from the in the 6 (b) shown state is moved, rotates the rotary part 51 further in the second direction of rotation and are the first projections 52 , as in 6 (c) shown on the second protrusions 82 on. 6 (c) shows a state in which the first projections 52 at the upper reversal point. In the state of 6 (c) has the edge 60c the circuit board 60 the first contact sections 41a . 41b already happened, ie has the edge 60c the circuit board 60 already completely from the first contact sections 41a . 41b moved away.

The rotation part 51 can rotate in the second direction of rotation while in the second direction D2 is maintained substantially at the same position, by the substantially same elasticity of the opposite terminal projections 42a . 42b ,

If the circuit board 60 from the in the 6 (c) shown moved state, exceed the first projections 52 completely the second protrusions 82 and take the first protrusions 52 a released state. Consequently, the rotation part starts 51 , as in 6 (d) shown by the elasticity of the elastically deformed connection projections 42a . 42b (such as by energy released from the elastically deformed state) in the first rotational direction. Accordingly, the terminal projections become 42a . 42b from the inner surfaces 31a . 31b remove and reverse the terminal projections 42a . 42b back to the position of the initial state.

Hereinafter, an advantageous effect of the electronic device will be 10 of the present embodiment.

If the circuit board 60 in the case 30 inserted or out of the case 30 is removed, rotates the rotation part 51 of the rotary element 50 in the first direction of rotation after the first projections 52 of the rotary element 50 on the second protrusions 82 of the housing 80 are taken and until the first protrusions 52 the second protrusions 82 exceed. At this time, the rotary part moves 51 the first and second terminal projections 42a . 42b the connections 40 from the position of the initial state toward the first and second surfaces 31a . 31b , As a result, the first contact portions become 41a . 41b the connections 40 from the first and the second surface 60a . 60b the circuit board 60 toward the first and second inner surfaces 31a . 31b away. That is, the first contact portions 41a . 41b are brought to the position without the circuit board 60 to touch.

In this case, the first and second terminal projections become 42a . 42b towards the interior surfaces 31a . 31b elastically deformed by passing through the rotary part 51 is pressed when the rotation part 51 rotated in the first direction of rotation. Consequently, the rotation part starts 51 after the first protrusions 52 the second protrusions 82 have exceeded, by the elasticity of the elastically deformed connection projections 42a . 42b to rotate in the second direction of rotation. As a result, the first and second terminal projections move 42a . 42b from the first and second inner surfaces 31a . 31b path.

As a result, the first contact portions become 41 in the event that the circuit board 60 in the case 30 is inserted, in contact with the electrodes 61 the circuit board 60 brought. The first contact sections 41a . 41b can the electrodes 61 by the elasticity of the first and the second connection projections 42a . 42b contact safely.

In this way, the first contact sections 41a . 41b then, if the circuit board 60 in the case 30 inserted or out of the case 30 is removed, once from the circuit board 60 be separated or removed. Consequently, damage to the first contact portions 41a . 41b such as peeling of the plated portions, and unexpected deformation can be reduced as compared with the conventional apparatus. Accordingly, the reliability of the electrical connection in the electrical device 10 be improved.

In the present embodiment, the circuit board 60 the electrodes 61 on the first and the second surface 60a . 60b on. The connections 40 include the first connections from the first inner surface 31a the groove 31 protrude, and the second connections, from the second inner surface 31b the groove 31 protrude. Consequently, the number of electrical connection paths of the card edge connector 20 be effectively increased.

Furthermore, the circuit board 60 by the elasticity of the elastically deformed connection projections 42a . 42b that are on opposite Sides of the circuit board 60 are arranged to be fastened from both sides. Accordingly, as compared with a structure in which the circuit board 60 through the connections 40 is fixed from one side and a holding member without generating elasticity by elastic deformation from the opposite side, a positioning tolerance of the printed circuit board 60 in the second direction D2 increase.

The above-described structure is, for example, a flexible circuit board 60 applicable. Furthermore, it is due to the flexibility of the circuit board 60 less likely that the elasticity due to the elastic deformation excessive on the circuit board 60 is applied.

In the present embodiment, the rotary member 51 the elliptical outer shape, which is the center of the axis of rotation C1 Are defined. The rotation part 51 contacts each of the first and second terminal projections 42a . 42b within the range of a rotation angle of 90 degrees from the first intersection 54 to the second intersection 55 to the third contact section 43a . 43b provided. As a result, the resistance between the rotary part becomes 51 and the connections 40 decreased, leaving the circuit board 60 in a simple way in the card edge connector 20 inserted or easily from the card edge connector 20 can be removed.

With such a structure, the distance between the axis of rotation is C1 and the third contact portion 43a . 43b minimal in the initial state and takes the distance between the axis of rotation C1 and the third contact portion 43a . 43b with the rotation of the rotating part 51 in one direction too. Further, the distance is maximum in a state where the rotation in one direction is stopped, and before the rotation part 51 begins to rotate in the opposite direction. Accordingly, the rotary part 51 in the opposite direction are further suitably rotated until the first contact portions 41a . 41b in contact with the electrodes 61 the circuit board 60 to be brought.

The elliptical outline of the rotation part 51 runs point-symmetrical to the axis of rotation C1 , The first and second terminal projections 42a . 42b are in the second direction D2 arranged symmetrically to the imaginary center line, extending in the first direction D1 in the middle of the groove 31 extends. Further, contact the extended sections 47a . 47b the terminal projections 42a . 42b the rotation part 51 at the points point symmetrical to the axis of rotation C1 , That is, the third contact portions 43a . 43b are on the outer circumference of the rotating part 51 point-symmetrical to the axis of rotation C1 arranged.

Consequently, the opposite terminal projections 42a . 42b through the one rotating part 51 be moved in the same way substantially simultaneously. The opposite connection projections 42a . 42b are arranged line-symmetrically and thus provide essentially the same elasticity (spring force). Consequently, the rotation part 51 at the substantially middle position of the groove 31 in the second direction D2 being held. Furthermore, the circuit board 60 through the first and second terminal projections 42a . 42b at the substantially middle position of the groove 31 in the second direction D2 being held.

In the present embodiment, the rotary member contacts 51 always the extended sections 47a . 47b the first and second terminal projections 42a . 42b , such as during the rotation of the rotating part 51 , in the initial state and in the attachment state. Consequently, the position of the first contact portions 41a . 41b in the second direction D2 in a simple way through the second contact sections 43a . 43b that serve as a breakpoint, to be matched. That is, a coplanarity of the first contact portions 41a . 41b with respect to the electrodes 61 can be improved.

Furthermore, the rotary part receives 51 in the contact state, the elasticity or springback of the elastically deformed connection projections 42a . 42b , Consequently, as compared with a structure in which the first and the second terminal protrusions 42a . 42b the rotation part 51 do not contact in the initial state, an elasticity of the first and second terminal projections 42a . 42b be improved over the movement. In the present embodiment, the rotary part 51 because the first and the second terminal projections 42a . 42b on opposite sides of the rotating part 51 are arranged, by the elasticity or springback of the elastically deformed connection projections 42a . 42b at the substantially middle position in the groove 31 in the second direction D2 being held.

In the above, the exemplary embodiment of the present invention has been described. However, the present invention is not limited to the above-described exemplary embodiment, but may be variously modified without departing from the scope of the present invention.

For example, the shape and size of the rotating part 51 be modified. In the same Way, shape and size (length) of the first protrusions 52 and second protrusions 82 and a shape of the first and second terminal protrusions 42a . 42b be modified. In addition, a relative arrangement of the rotating part 51 , the first projections 52 , the second protrusions 82 and the first and second terminal protrusions 42a . 42b be modified.

The width of the first projection 52 can, for example, as in the 7 (a) and 7 (b) shown not to be constant but vary. In the in the 7 (a) Example shown takes the width of the first projection 52 depending on the distance to the axis of rotation C1 gradually too. In the in the 7 (b) Example shown takes the width of the first projection 52 in the direction of the axis of rotation C1 gradually too.

In the examples in the 7 (a) and 7 (b) have the first projections 52 a rounded end up. Further, the surface of the first projection 52 which the second projection 82 contacted, in the initial state in the second direction D2 trained to rejuvenate.

The rotation part 51 can, for example, as in the 8 (a) and 8 (b) shown to have a polygonal outer shape. In the in the 8 (a) example shown, the rotary part 51 a substantially rectangular outer shape with rounded corners. Further, the center of the rectangular outer shape is coincident with the rotation axis C1 match.

In such a case, the rotation part 51 preferably constructed such that each extended portion 47a . 47b in the initial state at least either a long side or a corner portion of the rotary part 51 contacted and the corner portion of the rotating part 51 contacted when the rotation part 51 rotated from the initial state, leaving the extended section 47a . 47b the short side of the rotation part 51 not contacted.

In this case, the amount of movement of each contact section 41a . 41b in the second direction D2 with respect to the rotation angle (ie, the rotation amount) compared with the amount of movement of the first contact portion 41a . 41b through the elliptical rotation part 51 in which the minor axis A1 the length is equal to that of the short side and the major axis A2 the length equal to that of the long side has to be increased. Further, the distance between the axis of rotation C1 and every other contact section 43a . 43b minimal in the initial state and takes the distance between the axis of rotation C1 and every other contact section 43a . 43b with the rotation of the rotating part 51 in one direction too. The distance becomes maximum when the rotation stops in one direction and before the rotation starts in the opposite direction. Consequently, the rotation part 51 are suitably rotated in the opposite direction until the first contact portion 41 in contact with the electrode 61 the circuit board 60 is brought. Further, the outer shape of the rectangular rotary part runs 51 point-symmetrical to the axis of rotation C1 , As a result, the first and second terminal protrusions become 42a . 42b similar to the exemplary embodiment described above, arranged symmetrically to the imaginary line located in the center of the groove 31 in the second direction D2 in the first direction D1 extends, and contacted the rotary part 51 the extended sections 47a . 47b at the point-symmetrical positions to the axis of rotation C1 , In such a case, the opposite terminal protrusions 42a . 42b essentially simultaneously in the same way by the one rotary part 51 to be moved. The opposite connection projections 42a . 42b are arranged line-symmetrically, so that they provide substantially the same elasticity (spring force). Accordingly, the rotary part 51 essentially at the middle position of the groove 31 in the second direction D2 being held.

According to another example of the rectangular outer shape, the rotary part 51 have a square outer shape. Alternatively, the rotation part 51 have any other polygonal outer shape, such as a triangular outer shape, a pentagonal outer shape or a hexagonal outer shape, which in the 8 (b) is shown.

In the embodiments described above, the rotary part becomes 51 through the opposite connection projections 42a . 42b held by way of example at a predetermined position. The rotation part 51 However, in another way by a in the 9 (a) to 9 (c) shown structure are kept. The groove 31 of the housing 30 for example, has a wide section 31d and narrow sections 31e on. The wide section 31d is on the first page 30a open and extends in the first direction D1 in the case 30 , The narrow sections 31e are on the second or the third page 30b open.

The rotation part 51 is in the broad section 31d arranged, and the circuit board 60 will be in the wide section 31d inserted. The narrow sections 31e be on opposite sides of the wide section 31d arranged around the connecting sections 53 of the rotary element 50 to recieve. In particular, the narrow section 31e a depression 35 on one side and is like in 9 (c) shown at least a part of the connecting portion 53 in the depression 35 arranged.

With such a structure, a force generated when the circuit board 60 in the case 30 inserted or out of the case 30 is removed from a side wall of the recess 35 be taken perpendicular to the first direction D1 runs. As a result, the rotation element becomes 50 rotatably supported and can a positional shift of the rotary member 50 in the first direction D1 be reduced. In 9 (b) the reference numeral 31b1 describes a portion of the inner surface 31 b of the groove 31 according to the wide section 31d the groove 31 and reference numeral 31b2 a portion of the inner surface 31b the groove 31 according to the narrow section 31e ,

In the exemplary embodiment described above, the circuit board 60 the electrodes 61 on the two surfaces 60a . 60b on. Further, the first and second terminal projections protrude 42a . 42b from the opposite inner surfaces 31a . 31b the groove 31 out. Consequently, the circuit board 60 exemplified by both of the sides through the first and second terminal projections 42a . 42b held. Alternatively, the electrode 61 only on one surface of the circuit board 60 can be arranged and the connection projection 42 from just one of the inner surfaces 31a . 31b protrude.

In such a case, the other surface of the circuit board 60 on which the electrodes 61 are not arranged by a holding portion which is integral in the housing 30 or in the case 80 is intended to be held. In the same way, the rotation element 50 through the connection projection 42 which has only one inner surface 31a . 31b the groove 31 protrudes, and a holding element, which is integral in the housing 30 or in the case 80 is intended to be held.

In the exemplary embodiment described above, the terminal protrusions contact 42 the rotation part 51 in the initial state. Alternatively, the terminal projections 42 the rotation part 51 do not contact in the initial state and the rotation part 51 during the rotation contact.

Other benefits and modifications will be apparent to those skilled in the art. The present invention is not limited to the specific details described above and shown, the apparatus shown, and the illustrative examples.

In the above, an electronic device has been disclosed.

In an electronic device, an end portion of a printed circuit board becomes 60 in a housing 80 is held in a groove 31 a housing 30 a card edge connector 20 inserted or out of the groove 31 removed by the housing 80 with the housing 30 connected or the housing 80 from the case 30 is disconnected. A rotation element 50 is rotatable in the housing 30 held. During insertion and removal of the end portion of the circuit board 60 rotates the rotation part 51 in a first direction of rotation until first projections 52 of the rotary element 50 on second protrusions 52 of the housing 80 abut, and begins the rotation part 51 to rotate in a second rotational direction when the first protrusions 52 the second protrusions 82 exceed. The connection projections 42 . 42a . 42b be through the rotation part 51 which rotates in the first rotational direction, toward an inner surface 31a . 31b the groove 31 moves, leaving the contact sections 41 . 41a . 41b from the surface of the circuit board 60 be removed. The connection projections 42 . 42a . 42b be through the rotation part 51 rotating in the second rotational direction, back toward the circuit board 60 moves, so that when inserting the end portion of the circuit board 60 , the contact sections 41 . 41a . 41b in contact with electrodes 61 the end portion of the circuit board 60 to be brought.

Claims (8)

An electronic device comprising: - a printed circuit board (60) having a plurality of electrodes (61) on at least one surface of surfaces (60a, 60b) of an end portion of the printed circuit board (60); - A first housing (80) in which the circuit board (60) is housed and having an opening; and a card edge connector (20) comprising: - a second housing (30) having a first side (30a), a second side (30b) and a third side (30b), the second side (30b) and the third side (30b) are located on opposite sides adjacent to the first side (30a), the second housing (30) defines a groove (31) open on the first side (30a) and extending in a first direction (D1 ) continuously into the second side (30b) and the third side (30b); and a plurality of terminals (40) held in the second housing (30), the terminals (40) having terminal projections (42, 42a, 42b) extending from at least one inner surface of inner surfaces (31a, 31b) of the groove (31 ) protrude into the groove (31), the inner surfaces (31a, 31b) are opposed in a second direction (D2) perpendicular to the first direction (D1), the terminal projections (42, 42a, 42b) in a third direction (D3) which is perpendicular to the first direction (D1) and the second direction (D2), and the terminal projections (42) contact portions (41, 41a, 41b) to contact the electrodes (61), wherein in a state in which a part of the second housing (30) with the groove (31) is disposed over the opening in the first housing (80), the end portion of the circuit board (60) is received in the groove (31) and the Contact portions (41, 41a, 41b) of the terminal projections (42) make contact with the electrodes (61), characterized in that - a rotation member (50) is rotatably held in the card edge connector (20); - The rotary member (50) has a rotating part (51) and first projections (52); - The rotating part (51) in the groove (31) in the first direction (D1) closer than the contact portions (41) of the connection projections (42) to a bottom portion (31c) of the groove (31) is arranged; the rotating part (51) rotates about a rotation axis (C1) defined in the third direction (D3) and adapted to contact extended portions (47a, 47b) of the terminal projections (42, 42a, 42b), which extend from the contact portions (41, 41a, 41b) toward the bottom portion (31c) of the groove (31), around the terminal projections (42, 42a, 42b) in accordance with rotation of the rotary member (51) in the second direction To move (D2); - the first projections (52) in the third direction (D3) are connected to opposite ends of the rotary member (51) to rotate with the rotary member (51) and located outside the groove (31); - said first housing (80) has second protrusions (82) each protruding from an inner surface of said first housing (80) corresponding to said first protrusions (52); in an initial state in which the end portion of the circuit board (60) is not received in the groove (31), the contact portion (41, 41a, 41b) of each terminal projection (42, 42a, 42b) is held at a position at which a distance between the inner surface (31a, 31b) of the groove (31) and the contact portion (41, 41a, 41b) in the second direction (D2) is greater than a distance between the inner surface (31a, 31b) of the groove (31) and the surface (60a, 60b) of the end portion of the circuit board (60) on which the electrodes (61) are disposed; and - inserting the end portion of the circuit board (60) into the groove (31) and removing the end portion of the circuit board (60) from the groove (31), the rotation part (51) having the first projections (52) in a first one The rotational direction rotates after the first protrusions (52) hit the second protrusions (82) and until the first protrusions (52) abut the second protrusions (82), and begins with the first protrusions (52) in a second rotational direction rotate counter to the first rotational direction when the first projections (52) exceed the second projections (82), wherein the terminal projections (42, 42 a, 42 b) in accordance with the rotation of the rotary member (51) in the first rotational direction toward the inner surface (31a, 31b) are moved so that the contact portions (41, 41a, 41b) are separated from the surface (60a, 60b) of the end portion of the circuit board (60), and the terminal projections ge (42, 42a, 42b) are moved in the second direction back in the direction of the surface (60a, 60b) of the end portion of the printed circuit board (60) in accordance with the rotation of the rotary member (51), so that when inserting the end portion the circuit board (60) into the groove (31), the contact portions (41, 41a, 41b) are brought into contact with the electrodes (61). Electronic device after Claim 1 characterized in that - the electrodes (61) are disposed on both of the surfaces (60a, 60b) of the end portion of the circuit board (60); and the terminal protrusions (42) have first terminal protrusions (42a) extending from one of the inner surfaces (31a, 31b) of the groove (31) toward the electrodes (61) on one of the surfaces (60a, 60b) of the end portion of the printed circuit board (60 ), and second terminal protrusions (42b) protruding from the other of the inner surfaces (31a, 31b) of the groove (31) toward the electrodes (61) on the other of the surfaces (60a, 60b) of the end portion of the printed circuit board (60 ) protrude. Electronic device after Claim 2 characterized in that: - a cross-section of the rotation member (51) defined in a direction perpendicular to the rotation axis (C1) is point-symmetrical with respect to the rotation direction; the first terminal projections (42a) and the second terminal projections (42b) are arranged symmetrically in the initial state to an imaginary line extending parallel to the first direction (D1) in a center of the groove (31) with respect to the second direction (D2); and - the first connection projections (42a) and the second connection projections (42b) make contact with the rotation part (51) at locations point symmetrical to the rotation axis (C1). Electronic device according to one of Claims 1 to 3 characterized in that the rotary member (51) contacts the extended portions (47a, 47b) of the terminal projections (42a, 42b) also in the initial state. Electronic device after Claim 4 , characterized in that the rotary part (51) is formed so that a distance between the rotation axis (C1) and a portion contacting the extended portion (47a, 47b) of each of the terminal projections (42) is minimum in the initial state, with the rotation of the rotation member (51) in the in the first rotational direction, and is maximum when the rotation of the rotary member (51) in the first rotational direction is stopped and before the rotation of the rotary member (51) in the second rotational direction starts. Electronic device after Claim 5 characterized in that: - said rotary member (51) has an elliptical contour in a cross-sectional plane defined perpendicular to said rotational axis (C1), a center of said elliptical contour coinciding with said rotational axis (C1); and - the rotary member (51) contacts the extended portion (47a, 47b) of each of the terminal protrusions (42, 42a, 42b) within a 90 degree range of the elliptical contour defined at a first intersection (54) between a minor axis (A1 ) of the elliptical outline and the elliptical outline starts and ends at a second intersection (55) between a major axis (A2) of the elliptical outline and the elliptical outline. Electronic device after Claim 5 characterized in that: - the rotary member (51) has a rectangular outline in a cross-sectional plane defined perpendicular to the rotational axis (C1), a center of the rectangular outline coinciding with the rotational axis (C1); and the extended portions (47a, 47b) of the terminal projections (42, 42a, 42b) in the initial state contact a long side and / or a short side of the rectangular outline, and contact a corner portion of the rectangular outline when the circuit board (60) is in the second housing (30) is inserted and removed from the second housing (30), and in a state in which the end portion of the printed circuit board (60) is disposed in the groove (31). Electronic device according to one of Claims 1 to 7 characterized in that a portion of the first protrusions (52) and a portion of the second protrusions (81) that contact each other each have a rounded convex shape.

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