The disclosure of Japanese Patent Application No. 2008-138954, filed on May 28, 2008 is incorporated in the application by reference.
The present invention relates to an electrical connector to be connected to a flat conductive member.
The flat conductive member includes a flexible printed circuit board (FPC) and a flat cable. The flat conductive member is often connected to an electrical connector (connector) mounted on a circuit board. Japanese Patent Publication, for example, has disclosed a conventional connector connected to the flat conductive member.
Patent Reference: Japanese Patent Publication No. 2001-143827
In the conventional electrical connector disclosed in Patent Reference, a plurality of terminals is made of a metal plate so that a flat surface of the metal plate is retained. The terminals are held with a housing so that the flat surfaces of the metal plates are parallel to each other in the housing. Each of the terminals includes a contacting arm (contact spring piece) at a lower side thereof and a supporting arm at an upper side thereof extending toward an opening of the housing for receiving the flat conductive member.
In the conventional electrical connector, a pressing member is disposed at the opening of the housing to be rotatable from an open position for receiving the flat conductive member easily to a closed position for pressing the flat conductive member to the contacting portion of the contacting arm after the flat conductive member is inserted. When the pressing member is at the open position, the flat conductive member is situated over the contacting portion of the contacting arm. Then, after the pressing member is rotated to the closed position, the pressing member presses the flat conductive member with a pressing portion thereof. Thereby, the flat conductive member contacts with the contacting portion of the contacting arm with a contacting pressure.
In the conventional connector described above, the terminal includes one contacting arm. The contacting arm includes contacting portions at two locations in an extending direction thereof for contacting with the flat conductive member steadily.
In the conventional connector described above, it is necessary to securely contact with the flat conductive member at the contacting portions thereof with a sufficient contacting pressure. Accordingly, it is desirable that the contacting arm elastically deforms by a large amount at a position of the contacting portion. To this end, in the conventional connector described above, the contacting portions are located close to a forefront portion of the contacting arm. Consequently, both of the contacting portions are situated close to each other and deform together.
Accordingly, in the conventional connector described above, when the flat conductive member is inserted into the connector, the two contacting portions situated on the one contacting arm contact with the flat conductive member almost concurrently. When the pressing member presses the contacting portions through the flat conductive member, the contacting portions deform concurrently by almost the same amount.
When the two contacting portions are not properly situated against the flat conductive member due to a designing error or a manufacturing error, even though the other of the contacting portions contacts with the flat conductive member with a proper contacting pressure, one of the contacting portions may not obtain a sufficient contacting pressure, thereby resulting in an unstable contact state.
In view of the problems described above, an object of the present invention is to provide an electrical connector to be connected to a flat conductive member including two contacting portions located independently with each other, and capable of obtaining a sufficient and steady contacting pressure with respect to the flat conductive member.
Further objects and advantages of the invention will be apparent from the following description of the invention.
In order to attain the objects described above, according to the present invention, an electrical connector to be connected to a flat conductive member (connector) includes a housing and a terminal formed of a metal plate so that a flat surface of the metal plate is retained. The terminal is held and aligned in the housing so that the flat surface of the metal plate becomes parallel to each other. The terminal includes a base portion having an attached portion, and a contacting arm extending from the base portion. The flat conductive member is inserted into a space formed between the contacting arm and a supporting portion facing the contacting arm.
The electrical connector further includes a pressing member disposed to be rotatable from an open position for receiving the flat conductive member easily to a closed position for pressing the flat conductive member. The pressing member is supported on the supporting portion to be rotatable. As the pressing member is rotated to the closed position, the flat conductive member is pressed by the pressing member, thereby contacting with the terminal.
According to the present invention, in the electrical connector, the terminal includes a first contacting portion situated formed on the contacting arm extending from the base portion and a second contacting portion situated at a position closer to the base portion than the first contacting portion. The first contacting portion is capable of elastic deformation and situated at a position closer to the supporting portion than the second contacting portion in a direction the contacting arm faces the supporting portion in a free state.
In the present invention described above, the flat conductive member is inserted into the space between the supporting portion and the contacting arm when the pressing member is at the open position. The first contacting portion formed on the contacting arm is situated at the position closer to the supporting portion than the second contacting portion formed on the base portion. Thereby, the flat conductive member is situated over the first contacting portion in a secure contact state therewith.
After the flat conductive member is inserted, when the pressing member is rotated to the closed position, the pressing member presses the first contacting portion through the flat conductive member to deform elastically. As a result, a distance between the first contacting portion and the second contacting portion decreases as the first contacting portion deforms elastically in a direction the contacting arm faces the supporting portion, in other words, a thickness direction of the flat conductive member. The first contacting portion deforms to a position at a level the same as that of the second contacting portion or deforms further with the second contacting portion deforming together. Consequently, the flat conductive member contacts with both of the first contacting portion and the second contacting portion steadily.
According to the present invention, it is preferable that the supporting portion is formed at a supporting arm being capable of an elastic deformation upon receiving a force from the pressing member. The second contacting portion situated at the closer side to the base portion than the first contacting portion can deform relatively by a reacting force generated by the elastic deformation of the supporting arm, even in a case that the second contacting portion does not deform elastically. Accordingly, the second contacting portion can contact with the flat conductive member with an elastic pressure. Thus it is possible to obtain a steady contact state with sufficient contacting pressure, together with the first contacting portion.
According to the present invention, it is preferable that the supporting portion is situated between the first contacting portion and the second contacting portion in a direction the flat conductive member is inserted. Thereby the flat conductive member is supported on the first contacting portion and the second contacting portion like a beam. When a pressing portion of the pressing member presses the flat conductive member by a reaction force from the supporting portion located between both of the first and second contacting portions, the flat conductive member can contact steadily with the first conductive member and the second conductive member.
According to the present invention, the contacting arm may include a first contacting arm and a second contacting arm. The first contacting arm extends from the base portion at a farther position than the second contacting arm. Further, the first contacting arm may be inclined, so that a forefront portion thereof becomes closer to the supporting portion in the direction the contacting arm faces the supporting portion.
As described above, in the present invention, the contacting arm includes the first contacting portion and the second contacting portion. The first contacting portion is formed on the contacting arm extending from the base portion. The second contacting portion is situated at a closer side to the base portion than the first contacting portion. The first contacting portion is capable of elastic deformation and situated at a closer position to the supporting portion than the second contacting portion in a direction the contacting arm faces the supporting portion in the free state. Accordingly, when the terminal is pressed through the flat conductive member, the first contacting portion deforms elastically by the flat conductive member, so that the flat conductive member contacts with the second contacting portion. Thereby, the flat conductive member can contact with both of the contacting portions steadily with the sufficient contacting pressure.
Hereunder, embodiments of the present invention will be explained with reference to the accompanying drawings.
As shown in
The housing 10 includes a bottom wall 13 placed on a circuit board (not shown) and an upper wall 14 at a front portion thereof facing the bottom wall 13. A terminal hole 15 having a slit shape is formed between the bottom wall 13 and the upper wall 14, for inserting the terminal 30. The terminal hole 15 is formed in a side of the bottom wall 13, a side of the upper wall 14, and a front side of the housing 10 except where the opening portion 12 and the receiving groove 12A are formed. Since the terminal 30 is formed so that a flat surface of a metal plate is retained and aligned so that the surface of the metal plate becomes parallel to the surface of the sheet, the terminal hole 15 has a slit width (an inner width of the slit in the terminal-aligning direction) corresponding to a thickness of the terminal 30 and aligned with a specific interval in the width direction.
The pressing member 20 is made of an electrical insulating material similar to that of the housing 10. The pressing member 20 is placed at the opening portion 12 of the housing 10 and extends over a range of the opening portion 12 in the width direction. The pressing member 20 includes an operating portion 21 located an upper side of the upper wall 14 when the pressing member 20 is in an open position as shown in
The operating portion 21 has a dimension large enough to be rotated by a finger of an operator from the open position shown in
The groove portion 22 of the pressing portion 20 is formed so that a tip portion of a supporting arm (described later) of the terminal 30 can penetrate thereto. As shown in
As shown in
As described above, the terminal 30 is formed so that the flat surface of the metal plate is retained. As shown in
The base portion 31 is to be pushed into the terminal hole 15 of the housing 10 and fixed thereto. As shown in
The base portion 31 has an L character shape flipped horizontally and is fixed to the housing 10 with the vertical portion 31A and the horizontal portion 31B. When the base portion 31 is pushed into the terminal hole 15, the base portion 31 is fixed to an upper edge and a lower edge of the terminal hole 15, with an upper edge of the vertical portion 31A and a lower edge of the horizontal portion 31B as attached portions. The horizontal portion 31B and a lower inner surface of the terminal hole 15 hold each other and a protrusion 31A-1 provided on an upper surface of the vertical portion 31A (the attached portion) cuts into an inner surface of the upper edge of the terminal hole 15, thereby preventing the terminal 30 from coming off.
The supporting arm 32 extends in the rear direction, from an upper portion of the vertical portion 31A of the base portion 31 to an outside the terminal hole 15. The supporting arm 32 extends in the rear direction with a decline so that an upper surface thereof becomes gradually apart from the inner surface of the upper edge of the terminal hole 15. Accordingly, a space is formed between the supporting arm 32 and the inner surface of the upper edge of the terminal hole 15. Thereby, the supporting arm 32 can deform elastically in the vertical direction. The supporting arm 32 includes a supporting portion 32A bent into a reverse U character shape at a rear end portion thereof.
The supporting portion 32A supports the supported portion 23 of the pressing member 20 with a lower edge of a portion having the reverse U character shape. The supporting portion 32A does not have to contact with the supported portion 23 constantly if the supporting portion 32A is supported the shaft portion (not shown) of the pressing member 20 located at the end thereof. The supporting portion 32A may contact with and support the supported portion 23 at least when the supported portion 23 displaces in the upper direction receiving a reaction force from the flat conductive member P as the pressing member 20 is rotated from the open position to the closed position.
The supporting arm 32 may have elasticity so as to deform in the vertical direction, or may not have elasticity. In the embodiment, the supporting arm 32 has elasticity and deforms in the upper direction when the supporting portion 32A receives the reaction force in the upper direction from the supported portion 23 of the pressing member 20. In this case, the deformation of the supporting arm 32 is Limited by a lower surface of the upper wall 14 of the housing 10 functioning as a stopper.
The first contacting arm 33 and the second contacting arm 34 extend in the rear direction from the horizontal portion 31B of the base portion 31 having a distance in between. The first contacting arm 33 and the second contacting arm 34 are formed so as to have widths narrower than the horizontal portion 31B, respectively. The first contacting arm 33 extends from a lower position of the base portion 31, where is farther from the contacting portion P1 of the flat conductive member P than the second contacting arm 34.
The first contacting arm 33 also extends in the rear direction farther than the second contacting arm 34. Consequently, the first contacting arm 33 can deform elastically by a larger amount than the second contacting arm 34 upon receiving a force in the vertical direction, since the first contacting arm 33 can have a longer spring length than that of the second contacting arm 34. The first contacting arm 33 and the second contacting arm 34 include a first contacting portion 33A and a second contacting portion 34A protruding in the upper direction at rear ends thereof, respectively. The first contacting arm 33 is inclined in the upper direction as extending in the rear direction, and the first contacting portion 33A at the rear end of the first contacting arm 33 is situated at a position upper than the second contacting portion 34A at the rear end of the second contacting arm 34.
Further, the terminal 30 includes the connecting portion 35 protruding in the front direction from a lower front end of the base portion 31 and bent into the lower direction. The connecting portion 35 has a reverse L character shape. A lower end edge 35A of the connecting portion 35 is situated at a position contacting with a corresponding circuit portion of the circuit board and soldered to the corresponding circuit portion when the connector is placed on the circuit board.
Hereunder, in the embodiment described above, a way to use and a way of working will be explained.
(1) First, as shown in
(2) As the flat conductive member P is inserted further, the front end portion of the flat conductive member P enters into the receiving groove 12A and abuts against a front end surface thereof. Thus the front end portion of the flat conductive member P is settled into a predetermined inserted position. In the state described above, the contacting portion P1 of the flat conductive member P contacts with the first contacting portion 33A of the terminal 30 since the first contacting portion 33A is situated at the position upper than the second contacting portion 34A. In this state, the contacting portion P1 contacts lightly and unstably, or does not contact with the second contacting portion 34A.
(3) The pressing member 20 is rotated to the closed position shown in
(4) As the pressing member 20 rotates further and is set in the closed position, both of the first contacting portion 33A and the second contacting portion 34A are pressed in the lower direction. Thereby, both of the first contacting portion 33A and the second contacting portion 34B can contact with contacting portion P1 of the flat conductive member P with a sufficient contacting pressure.
(5) In the embodiment, the space is formed between the supporting arm 32 and the upper wall 14 of the housing 10. Accordingly, the supported portion 23 of the pressing member 20 pressing the flat conductive member P in the lower direction displaces elastically in the upper direction upon receiving the reaction force from the flat conductive member P as the pressing member 20 is rotated from the open position to the closed position. The supported portion 23 is pressed in the lower direction by an elastic energy generated by the elastic deformation. As a result, the contacting pressure of the flat conductive member P against the first contacting portion 33A and the second contacting portion 34A increases further.
In the present invention, it is possible to modify in many ways, not limited to the embodiment shown in FIGS. 1 and 2(A)-2(B). The second contacting portion 34A may not be capable of the elastic deformation. For example, as shown in
Similar to the embodiment described above, the first contacting portion 33A deforms elastically in the lower direction, from the position upper than the second contacting portion 34A to the same level with the second contacting portion 34A in the height direction. Consequently, the flat conductive member P also contacts with the second contacting portion 34A steadily.
In the variation shown in
Further, as opposed to the cases that each of the terminal 30 includes the first contacting arm 33 having the first contacting portion 33A, the second contacting arm 34 having the second contacting portion 34A and the supporting arm 32, as the embodiments shown in
In a variation shown in
As shown in
The embodiments described above as the connector placed horizontally on the circuit board, can be applied to a connector placed vertically on the circuit board, rotating the connector by ninety degrees.
The disclosure of Japanese Patent Application No. 2008-138954, filed on May 28, 2008 is incorporated in the application by reference.
While the invention has been explained with reference to the specific embodiments of the invention, the explanation is illustrative and the invention is limited only by the appended claims.
Number | Date | Country | Kind |
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2008-138954 | May 2008 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
6099346 | Hashiguchi et al. | Aug 2000 | A |
6332801 | Watanbe | Dec 2001 | B1 |
6837740 | Kunishi et al. | Jan 2005 | B2 |
6851968 | Tsunematsu | Feb 2005 | B2 |
7214081 | Ju | May 2007 | B1 |
7275948 | Miura et al. | Oct 2007 | B2 |
7303429 | Kim | Dec 2007 | B2 |
Number | Date | Country |
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2001-023711 | Jan 2001 | JP |
2001-143827 | May 2001 | JP |
2009-158279 | Jul 2009 | JP |
Number | Date | Country | |
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20090298355 A1 | Dec 2009 | US |