This application claims priority from Japanese Patent Application No. 2022-082142 filed with the Japan Patent Office on May 19, 2022, the entire content of which is hereby incorporated by reference.
The present disclosure relates to a flat conductor electric connector to which a flat conductor is connected.
A connector to which a band-shaped flat conductor extending in a front-back direction and having a thickness in an up-down direction is insertably connected forward is disclosed in JP-A-2019-067717. JP-A-2019-067717 describes a backward direction as a flat conductor insertion direction and describes a forward direction as a flat conductor removal direction, but the forward direction will be described herein as the flat conductor insertion direction and the backward direction will be described herein as the flat conductor removal direction. The connector of JP-A-2019-067717 is mounted on a mount surface of a circuit board, and multiple terminals arrayed with a flat conductor band width direction as a terminal array direction are held on a housing. Moreover, a lock member for preventing detachment of a flat conductor is turnably supported by the housing. The lock member is made of resin, and at both ends thereof, outer shaft portions protruding outward in the terminal array direction are provided.
Metal biasing members are held on the housing on both outer sides of a terminal array area. The biasing member is formed in such a manner that a metal plate member is punched into a flat plate shape, and is provided in such a posture that a plate surface thereof is at a right angle to the terminal array direction. The biasing member has a backwards C-shaped portion elastically deformable in the up-down direction. A cam surface (part of an outer peripheral surface) of the outer shaft portion is constantly biased from above by a lower surface (plate-thickness surface) of a locking piece portion which is a lower leg portion of the backwards C-shaped portion, and in this manner, a movable member is maintained at a closed position.
When the flat conductor is removed, the movable member is moved to an open position with a finger against biasing force of the locking piece portion, and the flat conductor is pulled backward. At this point, an elastic piece portion which is an upper leg portion of the backwards C-shaped portion is pushed by the cam surface of the outer shaft portion, and accordingly, is elastically displaced upward. By releasing the finger from the movable member after the flat conductor has been removed, the elastically-displaced elastic piece portion is released, and the movable member automatically returns to the closed position by action of the above-described biasing force.
A flat conductor electric connector according to an embodiment of the present disclosure is a flat conductor electric connector to which a flat conductor extending in a front-back direction is connected, including: a housing into which the flat conductor is inserted forward; multiple terminals arrayed and held on the housing with a direction at a right angle to both the front-back direction and a thickness direction of the flat conductor as a terminal array direction; a metal fitting arranged outside a terminal array area in the terminal array direction and held on the housing; and a movable member movable between a closed position and an open position while turning about a turning axis extending in the terminal array direction, in which the movable member has a locking portion, and removal of the flat conductor is blocked by contact of the locking portion when the movable member is at the closed position and is allowed by release of the locking portion when the movable member is at the open position, the metal fitting has a body portion positioned adjacent to the movable member in the terminal array direction and having a plate surface at a right angle to the terminal array direction, and a biasing portion positioned on one side of the movable member in the thickness direction of the flat conductor and biasing the movable member, the body portion has a movable arm portion extending in the front-back direction and elastically deformable in the thickness direction of the flat conductor, and the biasing portion extends from the movable arm portion toward the movable member in the terminal array direction, and at a plate surface of the biasing portion, biases the movable member from the one side.
In the following detailed description, for purpose of explanation, numerous specific details are set forth in order to provide a thorough understanding of the disclosed embodiments. It will be apparent, however, that one or more embodiments may be practiced without these specific details. In other instances, well-known structures and devices are schematically shown in order to simplify the drawing.
When the movable member turns with the biasing force generated as described above, the locking piece portion of the biasing portion and the cam surface of the outer shaft portion of the movable member slidably contact each other. In JP-A-2019-067717, the locking piece portion slidably contacts the cam surface at the lower surface, i.e., the plate-thickness surface (fracture surface), and therefore, contacts the cam surface at a rough surface. Moreover, the area of contact between the locking piece portion and the cam surface is small, and for this reason, the biasing force tends to act on the narrow area of the cam surface in a concentrated manner. Thus, abrasion of the cam surface is easily caused due to repeated slide contact between the locking piece portion and the cam surface in response to turning of the movable member, and as a result, there is a probability that the biasing force is lowered.
The present invention has been made in view of the above-described situation, and is intended to provide a flat conductor electric connector configured such that biasing force acting on a movable member is less likely to be lowered.
(1) A flat conductor electric connector according to the present invention is a flat conductor electric connector to which a flat conductor extending in a front-back direction is connected, including: a housing into which the flat conductor is inserted forward; multiple terminals arrayed and held on the housing with a direction at a right angle to both the front-back direction and a thickness direction of the flat conductor as a terminal array direction; a metal fitting arranged outside a terminal array area in the terminal array direction and held on the housing; and a movable member movable between a closed position and an open position while turning about a turning axis extending in the terminal array direction, in which the movable member has a locking portion, and removal of the flat conductor is blocked by contact of the locking portion when the movable member is at the closed position and is allowed by release of the locking portion when the movable member is at the open position.
In the flat conductor electric connector, according to the present invention, the metal fitting has a body portion positioned adjacent to the movable member in the terminal array direction and having a plate surface at a right angle to the terminal array direction, and a biasing portion positioned on one side of the movable member in the thickness direction of the flat conductor and biasing the movable member, the body portion has a movable arm portion extending in the front-back direction and elastically deformable in the thickness direction of the flat conductor, and the biasing portion extends from the movable arm portion toward the movable member in the terminal array direction, and at a plate surface of the biasing portion, biases the movable member from the one side.
In the aspect (1) of the invention, the biasing portion of the metal fitting biases the movable member at the plate surface (rolled surface). Thus, as compared to a case where the biasing portion of the metal fitting biases the movable member at a plate-thickness surface (fracture surface), the biasing portion can contact the movable member at a smoother surface. Moreover, the area of contact between the biasing portion and the movable member can be increased. As a result, even if the biasing portion and the movable member repeatedly slidably contact each other due to movement of the movable member, abrasion of the movable member is less likely to be caused, and lowering of biasing force of the biasing portion can be favorably avoided.
(2) In the aspect (1) of the invention, the movable member may have a cam portion contactable with the plate surface of the biasing portion, and the biasing portion may bias the cam portion at least during movement of the movable member.
(3) In the aspect (1) or (2) of the invention, the flat conductor electric connector may be arranged on a mount surface of a circuit board at a right angle to the thickness direction of the flat conductor, the body portion may have a fixing arm portion positioned on the other side of the movable arm portion in the thickness direction of the flat conductor and extending in the front-back direction, and the metal fitting may have a fixing leg portion extending from the fixing arm portion in the terminal array direction and soldered to the mount surface.
A technique of providing the fixing leg portion at the metal fitting and soldering the fixing leg portion to the mount surface of the circuit board can avoid detachment of the metal fitting from the housing when the biasing portion receives force toward the one side in the thickness direction of the flat conductor from the movable member.
(4) In the aspect (3) of the invention, the fixing leg portion may extend to the same side as that of extension of the biasing portion in the terminal array direction. Since the fixing leg portion extends to the same side as that of extension of the biasing portion in the terminal array direction as described above, an increase in the size of the metal fitting in the terminal array direction due to the fixing leg portion can be avoided.
(5) In the aspect (3) or (4) of the invention, the metal fitting may have, at a position between a front end of the fixing arm portion and the fixing leg portion in the front-back direction, a locking leg portion lockable to the housing from the other side, and the locking leg portion may be provided so as to extend from the fixing arm portion.
Since the locking leg portion is provided at the metal fitting as described above, the locking leg portion is locked to the housing from the other side when the biasing portion receives the force toward the one side in the thickness direction of the flat conductor from the movable member, and as a result, detachment of the metal fitting from the housing can be avoided. Specifically, the fixing leg portion is soldered to the mount surface of the circuit board yet before the connector is mounted on the circuit board, and therefore, the soldered portion of the fixing leg portion cannot provide resistance against the force toward the one side. Thus, a technique of providing the locking leg portion to provide resistance against the force toward the one side by locking force between the locking leg portion and the housing is extremely effective before connector mounting.
(6) In any one of the aspects (1) to (5) of the invention, the metal fitting may be press-fitted in and attached to the housing. With this configuration, the metal fitting can be easily attached to the housing.
In the present invention, the movable member is biased by the plate surface of the biasing portion of the metal fitting, and therefore, abrasion of the movable member and therefore lowering of the biasing force acting on the movable member can be favorably avoided.
Hereinafter, an embodiment of the present invention will be described based on the attached drawings.
The connector 1 is mounted on a mount surface of a circuit board (not shown), and the flat conductor C (e.g., an FPC) which is a partner connector is connected so as to be insertable into or removable from the connector 1 with a front-back direction (X-axis direction) parallel with the mount surface as an insertion-removal direction. The connector 1 brings the circuit board and the flat conductor C into electrical conduction with each other in such a manner that the flat conductor C is connected to the connector 1. In the present embodiment, in the X-axis direction (front-back direction), an X1 direction is a forward direction, and an X2 direction is a backward direction. Moreover, a Y-axis direction at a right angle to the front-back direction (X-axis direction) is a connector width direction, and a Z-axis direction at a right angle to the mount surface of the circuit board is an up-down direction.
The flat conductor C is in a flexible band shape which extends in the front-back direction (X-axis direction) and of which the width direction is the connector width direction (Y-axis direction) and thickness direction is the up-down direction (Z-axis direction), and as shown in
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The receiving space 11 is surrounded by the lower wall 12, the upper wall 13, the front wall 15 (see
At the upper wall 13, upper holes 13A penetrating the upper wall 13 in the up-down direction outside the terminal array area are formed. As shown in
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The metal fitting holding portion 17 is in a standing plate shape having a plate surface at a right angle to the connector width direction, and a metal fitting housing portion 17A for housing part of the metal fitting 30 is formed outside the projecting portion 16 in the connector width direction (also see
As shown in
The terminal 20 is formed by punching of a metal plate member, and in a state in which a plate surface thereof is at a right angle to the connector width direction, is press-fitted and attached from the front to the terminal housing portion 19 of the housing 10. As shown in
The lower arm portion 21 has a support target arm portion 21A housed in the lower groove portion 19A, supported from below by a groove bottom surface 19A-1 forming an inner surface of the lower groove portion 19A, and extending in the front-back direction, and an elastic arm portion 21B extending backward from the support target arm portion 21A. The support target arm portion 21A is entirely housed in the lower groove portion 19A. An upper edge of the support target arm portion 21A is inclined downward as extending backward, and on the other hand, a lower edge of the support target arm portion 21A is not inclined with respect to the front-back direction. That is, the support target arm portion 21A is gradually narrowed toward the back. The lower edge of the support target arm portion 21A is supported on the groove bottom surface 19A-1 across the entire area of the support target arm portion 21A in the front-back direction.
The elastic arm portion 21B has a first elastic portion 21B-1 extending from a back end of the support target arm portion 21A, and a second elastic portion 21B-2 positioned higher than the first elastic portion 21B-1, i.e., on a receiving space 11 side, and bent forward from a back end of the first elastic portion 21B-1. The first elastic portion 21B-1 is entirely housed in the lower groove portion 19A, and is inclined upward as extending backward. That is, a clearance formed between a lower edge of the first elastic portion 21B-1 and the groove bottom surface 19A-1 of the lower groove portion 19A gradually becomes larger toward the back. The first elastic portion 21B-1 is elastically deformable in the up-down direction within the area of this clearance. Hereinafter, this clearance will be referred to as an “elastically-deformable space 19A-2.”
In the present embodiment, the groove bottom surface 19A-1 of the lower groove portion 19A is formed at the same height across the entire area in the front-back direction, and therefore, the elastically-deformable space 19A-2 is formed as the clearance between the first elastic portion 21B-1 and the groove bottom surface 19A-1 because the first elastic portion 21B-1 is inclined. However, the form of the elastically-deformable space 19A-2 is not limited to above. For example, as a modification, in an area corresponding to the first elastic portion 21B-1 in the front-back direction, the groove bottom surface 19A-1 may be formed lower than other areas, and accordingly, the elastically-deformable space 19A-2 may be formed. As another modification, a space below the first elastic portion 21B-1, i.e., a downwardly-opened space, may be formed as the elastically-deformable space 19A-2 without the lower wall 12 formed in the area corresponding to the first elastic portion 21B-1 in the front-back direction. In these modifications, the first elastic portion 21B-1 may be in a shape extending without inclined with respect to the front-back direction.
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Since the distance P is set smaller than the thickness dimension R of the flat conductor C as described above, a state in which the flat conductor C is sandwiched with contact pressure by cooperation of the lower contact portion 21B-3 and the upper contact portion 22A is easily maintained even when the flat conductor C tilts due to external force applied in the thickness direction (up-down direction) of the flat conductor C in a state in which the flat conductor C is connected to the connector 1. As a result, contact between the flat conductor C and each terminal 20 with proper contact pressure can be ensured, and unexpected detachment of the flat conductor C can be avoided.
Because of the clearance dimension Q being set smaller than the half of the thickness dimension R of the flat conductor C, even when the distance P is set smaller than twice as great as the clearance dimension Q, the state in which the flat conductor C is sandwiched with contact pressure by cooperation of the lower contact portion 21B-3 and the upper contact portion 22A is easily maintained. Thus, even when the flat conductor tilts due to the external force applied in the thickness direction (up-down direction) of the flat conductor in a state in which the flat conductor C is connected to the connector, contact between the flat conductor C and each terminal 20 with proper contact pressure can be ensured, and unexpected detachment of the flat conductor C can be avoided.
In the present embodiment, both a condition where the distance P is smaller than the thickness dimension R of the flat conductor C and a condition where the distance P is smaller than twice as great as the clearance dimension Q are satisfied, but both these conditions are not necessarily satisfied, and unexpected detachment of the flat conductor C can be avoided as long as any of these conditions is satisfied.
In the present embodiment, the protruding tip of the upper contact portion 22A is positioned at the front with respect to the protruding tip of the lower contact portion 21B-3 of the lower arm portion 21, but a relative positional relationship between the protruding tips in the front-back direction is not limited to above as long as the distance P between the protruding tips satisfies at least one of the above-described two conditions. That is, the protruding tip of the upper contact portion 22A may be positioned at the back with respect to the protruding tip of the lower contact portion 21B-3 of the lower arm portion 21, or the protruding tips may be at the same position.
The coupling arm portion 23 is housed in the front groove portion 19C. A press-fitting protrusion 23A protruding upward is provided at an upper edge of the coupling arm portion 23, and bites into an inner surface of the upper wall 13 to hold the terminal 20 in the terminal housing portion 19. The connection portion 24 extends outward of the housing 10 from the lower portion of the coupling arm portion 23 to the lower front side. A lower edge of the connection portion 24 is positioned slightly lower than a lower surface of the lower wall 12 of the housing 10, and in a state in which the connector 1 is arranged on the mount surface of the circuit board (not shown), is soldered to a corresponding circuit portion (pad) on the mount surface.
As shown in
The body portion 31 has a fixing arm portion 31A positioned adjacent to the cam portion 44 of the movable member 40 on the outer side thereof in the connector width direction, extending linearly in the front-back direction, and fixed to the housing 10, a movable arm portion 31B positioned higher than the fixing arm portion 31A and extending in the front-back direction, and a coupling portion 31C extending in the up-down direction and coupling front end portions of the fixing arm portion 31A and the movable arm portion 31B to each other. The press-fitting fixing portion 31A-1 of the metal fitting 30 provided at the front end portion of the fixing arm portion 31A is press-fitted in the press-fitting groove portion 17A-1 of the metal fitting housing portion 17A, and accordingly, the metal fitting 30 is held in the metal fitting housing portion 17A. In a state in which the metal fitting 30 is housed in the metal fitting housing portion 17A, the fixing arm portion 31A of the metal fitting 30 is supported on a lower inner wall surface 17A-2 of the metal fitting housing portion 17A.
The movable arm portion 31B extends in the front-back direction, and is elastically deformable in the up-down direction, i.e., a direction parallel with a plate surface (rolled surface) thereof. A front half portion of the movable arm portion 31B is inclined downward as extending backward, and a back half portion of the movable arm portion 31B linearly extends, without inclination, backward from a back end of the front half portion. Note that the shape of the movable arm portion is not limited to above and the movable arm portion may be, for example, formed such that the front half portion is inclined upward as extending backward and the back half portion linearly extends, without inclination, backward from the back end of the front half portion. The coupling portion 31C is inclined forward, at a position closer to a front end of the fixing arm portion 31A, as extending upward from an upper edge of the fixing arm portion 31A, and couples a portion of the fixing arm portion 31A closer to the front end thereof and a front end portion of the movable arm portion 31B to each other.
The biasing portion 32 is bent, at an intermediate position of the back half portion of the movable arm portion 31B in the front-back direction, at an upper edge of the movable arm portion 31B, and extends inward in the connector width direction, i.e., toward the cam portion 44 of the movable member 40. The biasing portion 32 has a plate surface (rolled surface) at a right angle to the up-down direction, is positioned immediately above the cam portion 44, and restricts upward movement of the cam portion 44 and therefore upward movement of the movable member 40 (see
In the present embodiment, there is nothing above the back half portion of the movable arm portion 31B as shown in
The fixing leg portion 33 is bent, at a position closer to a back end of the fixing arm portion 31A, at a lower edge of the fixing arm portion 31A, and extends inward in the connector width direction. Since the fixing leg portion 33 is formed so as to extend inward in the connector width direction, i.e., extend to the same side as extension of the biasing portion 32, as described above, an increase in the size of the metal fitting 30 in the connector width direction due to the fixing leg portion 33 can be avoided. The fixing leg portion 33 is positioned at the back with respect to the biasing portion 32 in the front-back direction, and extends across the substantially same area as that of the biasing portion 32 in the connector width direction. Moreover, a lower surface of the fixing leg portion 33 is positioned slightly lower than the lower surface of the lower wall 12 of the housing (see
The locking leg portion 34 is positioned at the front with respect to the fixing leg portion 33, and is provided within the area of the biasing portion 32 in the front-back direction. The locking leg portion 34 extends forward after having extended downward from a lower edge of the fixing leg portion 33, and the entire shape thereof is in an L-shape. As shown in
As shown in
The operation portion 41 is operated when the movable member 40 is moved (turned) between the closed position shown in
As shown in
The cam portion 44 protrudes in a substantially rectangular columnar shape from an outer surface of the protruding end portion 43A of the side plate portion 43 in the connector width direction, and regardless of the position of the movable member 40, is constantly housed in the cam housing portion 10B of the housing 10. The cam portion 44 is positioned immediately below the biasing portion 32 of the metal fitting 30, and upward movement thereof is restricted by the biasing portion 32. The cam portion 44 is provided at a position including the turning axis of the movable member 40 as viewed in the connector width direction, and is formed such that the sectional shape thereof at a right angle to the turning axis is a substantially rectangular shape.
When the movable member 40 is at the closed position, the cam portion 44 contacts a lower surface of the biasing portion 32 at a first restriction target surface 44A forming a flat upper surface at the closed position (
In the present embodiment, in a state in which the cam portion 44 contacts the lower surface of the biasing portion 32 at the closed position or the open position, the movable arm portion 31B of the metal fitting 30 is not elastically deformed, i.e., biasing force from the biasing portion 32 does not act on the cam portion 44. However, as a modification, at least at one of the closed position or the open position, in a state in which the movable arm portion 31B of the metal fitting 30 is slightly elastically deformed, the biasing portion 32 may contact the cam portion 44 such that moderate biasing force from the biasing portion 32 acts on the cam portion 44. As another modification, at least at one of the closed position or the open position, a clearance may be formed in the up-down direction between the cam portion 44 and the biasing portion 32.
A cam surface 44C is formed between the first restriction target surface 44A and the second restriction target surface 44B at an outer peripheral surface (outer peripheral surface parallel with the connector width direction) of the cam portion 44. The cam surface 44C is a protruding curved surface formed at one corner portion of the cam portion 44. In the present embodiment, in a course of the movable member 40 turning between the closed position and the open position, the cam portion 44 presses the biasing portion 32 upward by the cam surface 44C, and accordingly, elastically displaces the movable arm portion 31B. Then, the cam portion 44 receives reactive force, i.e., downward biasing force, from the biasing portion 32.
The connector 1 configured as described above is assembled in the following manner. First, the terminals 20 are press-fitted in and attached to the terminal housing portions 19 of the housing 10 from the front. Moreover, the movable member 40 held in the posture at the closed position is attached to the housing 10 from above. At this point, the side plate portions 43 of the movable member 40 are housed in the side plate housing portions 10A, and the cam portions 44 are housed in the cam housing portions 10B. Next, the metal fittings 30 are press-fitted in and attached to the metal fitting housing portions 17A of the housing 10 from the back. At this point, the locking leg portions 34 are fitted in the locking target end portions 17B, and are locked to the locking target end portions 17B from below. Moreover, the biasing portions 32 of the metal fittings 30 are positioned immediately above the cam portions 44, and accordingly, upward movement of the cam portions 44 is restricted. The connector 1 is completed in such a manner that the terminals 20, the metal fittings 30, and the movable member 40 are attached to the housing 10 as described above.
Note that in the present embodiment, the terminals 20, the movable member 40, and the metal fittings 30 are attached to the housing 10 in this order, but a step of attaching the terminals 20 may be performed after a step of attaching the metal fittings 30 and the movable member 40 or may be performed simultaneously. In the present embodiment, the movable member 40 in the posture at the closed position is attached to the housing 10, but the posture of the movable member 40 upon attachment thereof is not limited to above and may be, e.g., the posture at the open position.
Next, an operation of inserting the flat conductor C into the connector 1 or removing the flat conductor C from the connector 1 will be described.
First, the connection portions 24 of the terminals 20 of the connector 1 are soldered to the corresponding circuit portions of the circuit board (not shown), and the fixing leg portions 33 of the metal fittings 30 are soldered to the corresponding portions of the circuit board. By such soldering of the connection portions 24 and the fixing leg portions 33, the connector 1 is attached to the circuit board.
Next, as shown in
In the present embodiment, the second elastic portion 21B-2 of the terminal 20 having the lower contact portion 21B-3 is bent at the back end of the first elastic portion 21B-1, and extends forward. Thus, when the flat conductor C is inserted into the receiving space 11 from back, the flat conductor C is smoothly guided forward by back end portions of the elastic arm portions 21B, i.e., bent portions of the elastic arm portions 21B curved in a backwardly-raised shape, and reaches the position of the lower contact portions 21B-3. Thus, at any portion, the terminal 20 is not buckled due to contact with the front end of the flat conductor C. As a result, the terminals 20 and the flat conductor C can properly contact each other.
In a course of the flat conductor C being inserted into the receiving space 11, the front end of the flat conductor C contacts the lower contact portions 21B-3 of the second elastic portions 21B-2 of the terminals 20 and the upper contact portions 22A of the upper arm portions 22 of the terminals 20. Then, the front end of the flat conductor C pushes down the second elastic portions 21B-2 to elastically displace the second elastic portions 21B-2 downward, and pushes up the upper arm portions 22 to elastically displace the upper arm portions 22 upward. As a result, a portion between the lower contact portions 21B-3 and the upper contact portions 22A is expanded. At this point, the first elastic portions 21B-1 are also elastically displaced downward in response to elastic displacement of the second elastic portions 21B-2.
At the position of each locking portion 42 of the movable member 40 in the connector width direction, the front end of the flat conductor C contacts the guide surface 42A of the locking portion 42 to push up the locking portion 42. Since the locking portions 42 are pushed up, the entirety of the movable member 40 is moved upward. Accordingly, the biasing portions 32 of the metal fittings 30 are pushed up by the cam portions 44, and the movable arm portions 31B of the metal fittings 30 are elastically displaced upward. That is, elastic displacement of the movable arm portions 31B allows upward movement of the locking portions 42.
Since the portion between the lower contact portions 21B-3 and the upper contact portions 22A of the terminals 20 is expanded and the locking portions 42 of the movable member 40 are moved upward as described above, the flat conductor C can be inserted further forward. As shown in
In a state in which insertion of the flat conductor C is completed, the elastically-displaced state of the elastic arm portions 21B (first elastic portions 21B-1 and second elastic portions 21B-2) of the lower arm portions 21 and the upper arm portions 22 is maintained as shown in
In a course of inserting the flat conductor C, when the locking portions 42 reach the position of the cutouts C1 after the ear portions C2 of the flat conductor C have passed through the position of the locking portions 42, the movable member 40 returns to the closed position, and the locking portions 42 enter the cutouts C1 from above as shown in
In the state shown in
In the present embodiment, the biasing portion 32 biases the cam portion 44 at the plate surface (rolled surface) thereof. Thus, as compared to a case where a plate-thickness surface (fracture surface) of the biasing portion biases the cam portion, the biasing portion 32 can contact the cam portion 44 at a smoother surface, and the area of contact between the biasing portion 32 and the cam portion 44 can be increased. As a result, even if the biasing portion 32 and the cam portion 44 repeatedly slidably contact each other due to movement of the movable member 40, abrasion of the cam portion 44 is less likely to be caused, and lowering of the biasing force of the biasing portion 32 can be favorably avoided.
When the movable member 40 reaches the open position, the second restriction target surface 44B of the cam portion 44 forms the upper surface, and the movable arm portion 31B of the metal fitting 30 is no longer elastically displaced and returns to a free state, as shown in
As a result of movement of the movable member 40 to the open position, the locking portion 42 of the movable member 40 is separated upward from the cutout C1 of the flat conductor C as shown in
In the present embodiment, the fixing leg portion 33 is provided at the metal fitting 30 and is soldered to the mount surface of the circuit board, and therefore, when the biasing portion 32 receives upward force from the cam portion 44 of the movable member 40 in a course of turning the movable member 40, the soldered portion of the fixing leg portion 33 can provide resistance against the upward force, and as a result, detachment of the metal fitting 30 from the housing can be avoided.
In the present embodiment, the locking leg portion 34 is provided at the metal fitting 30, and therefore, detachment of the metal fitting 30 from the housing 10 can be avoided when the biasing portion 32 receives the upward force from the cam portion 44 of the movable member 40 because the locking leg portion 34 is locked to the locking target end portion 17B of the housing 10 from below. Specifically, the fixing leg portion 33 is soldered to the mount surface of the circuit board yet before the connector 1 is mounted on the circuit board, and therefore, the soldered portion of the fixing leg portion 33 cannot provide resistance against the upward force. Thus, a technique of providing the locking leg portion 34 to provide resistance against the upward force by locking force between the locking leg portion 34 and the locking target end portion 17B is extremely effective before connector mounting.
In the present embodiment, the circuit portions of the flat conductor C are exposed at the lower surface of the flat conductor C. Instead, the circuit portions may be exposed at the upper surface of the flat conductor C. In this case, the upper arm portion 22 of the terminal 20 contacts the circuit portion at the upper contact portion 22A. Alternatively, the circuit portions may be exposed at both the lower and upper surfaces of the flat conductor C. In this case, the lower contact portion 21B-3 contacts the lower circuit portion, and the upper contact portion 22A contacts the upper circuit portion.
In the present embodiment, the biasing portion 32 of the metal fitting 30 biases the cam portion 44 of the movable member 40, but the movable member portion to be biased is not necessarily the cam portion and may be other portions of the movable member.
The foregoing detailed description has been presented for the purposes of illustration and description. Many modifications and variations are possible in light of the above teaching. It is not intended to be exhaustive or to limit the subject matter described herein to the precise form disclosed. Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims appended hereto.
Number | Date | Country | Kind |
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2022-082142 | May 2022 | JP | national |