The present invention relates to a low-profile connector comprising a header and a socket which are respectively mounted on circuit boards.
In recent years, a low-profile connector is practically used for connecting electric circuits formed on two circuit boards (including flexible printed circuit board) in a manner so that the circuit boards face each other. In mobile equipment such as a mobile phone, the connector is required to be downsized and to have a low profile corresponding to the miniaturization and the low profile of the mobile equipment. On the other hand, a packaging density of the electronic components mounted on the circuit board becomes higher due to high functionality of the mobile equipment, so that number of arrangement of contacts constituting the connector is tend to be increased and the width and pitch of arrangement of the contacts become much narrower. Especially in a flip phone, the circuit boards, on which the electronic components are mounted, are separately disposed on both sides with respect to a hinge, and flexible substrates provided in the inside of the hinge are used for connecting the separated circuit boards. Thus, the application of the connector will be expanded for connecting the circuit boards each other or connecting the electronic components and the circuit boards.
The connector for connecting two circuit boards is constituted by a header corresponding to a male connector mounted on one circuit board and a socket corresponding to a female connector mounted on the other circuit board.
The header 210 comprises a header body 211 and a plurality of pairs of posts 212. The header body 211 is made of resin molding and has a groove 211a which engages with the table portion 215 of the socket body 202 of the socket 201. The post 212 is made of a conductive metal thin plate by bending substantially reverse L-shape. A rear portion of the post 212 protruding toward the outside serves as a soldering terminal 214 which is to be soldered on a circuit board. Each post 212 is fixed on the header body 211, since a base of the post 212 is inserted into the header body 211 while the header body 211 is molded in a manner so that the pairs of posts 212 are arranged at the predetermined pitch in the direction perpendicular to the paper sheet of
In such the connector, it is required to making the mounting areas of the socket and the header much narrower corresponding to the downsizing of the mobile equipment. Furthermore, it is required to provide a low-profile connector corresponding to the low profile of the mobile equipment using the circuit boards. Actually, a connecter having a pitch 0.3 to 0.5 mm of arrangement of the contacts of the socket and the posts of the header is supplied. Furthermore, a low-profile connector having a thickness called stacking height less than 1.5 mm (for example, 1.2 mm or 1.0 mm) when the header is coupled with the socket is also provided.
It is further required to make the pitch of the contacts much narrower and to make the stacking height of the connector much lower. Concretely, it is required to make the stacking height of the connector less than 1.0 mm. When the stacking height between a lower face of the soldering terminal 207 of the contact 204 of the socket 201 and an upper face the soldering terminal 214 of the post 212 of the header 210 in the above-mentioned conventional connector is made much thinner in a range between 0.9 mm to 0.8 mm, there is a limit to lengthen the length of the plate spring portion 205 of the contact 204, so that the spring characteristics of the plate spring portion 205 of the contact 204 cannot be increased. Thus, a sufficient contact pressure cannot be obtained between the plate spring portion 205 of the contact 204 and the post 212. Furthermore, when a dimension āCā between a peak of the contact portion 209 and a base of a side 206a of the fitting portion 206 of the contact 204 is made larger than a dimension āDā between the base of the side 206a and a base of the plate spring portion 205, the stress concentration occurs at the bent corner of the U-shaped plate spring portion 205 when the plate spring portion 205 is warped. Still furthermore, the shear plane at top end of the contact 204 is caught on the header 210 when the header 210 is coupled with the socket 201, so that the contact 204 may be deformed.
Still furthermore, when the stacking height of the connector is made thinner, it is necessary to make the socket body 202 of the socket 201 and the header body 211 of the header 210 thinner. Thus, there is a possibility that the thickness of the sidewalls and bottom wall of the bodies 202 and 211 become too thin to maintain a practical strength. In other words, contortion and/or crack can easily occur in the socket body 202 of the socket 201 and the header body 211 of the header 210 due to the stress generated in the socket 201 and the header 210 while the socket 201 and the header 210 are treated or mounted on the circuit boards.
An object of the present invention is to provide a low-profile connector having high reliability of connection even when the stacking height is made lower. Another object of the present invention is to provide a low-profile connector having a sufficient strength with respect to the contortion and the crack.
A low-profile connector in accordance with an aspect of the present invention is constituted by a header and a socket, which are respectively mounted on circuit boards for connecting electric circuit formed on the circuit boards. The header comprises a header body made of resin molding, and a plurality of posts made of a conductive metal thin plate and provided at a predetermined pitch on a peripheral wall of the header body. The socket comprises a socket body made of resin molding and a plurality of contacts made of a conductive metal thin plate and provide at the predetermined pitch in a guide grooves on a peripheral wall of the socket body, which are to be contacted with the posts provided on the header.
Each post is inserted into the header body and comprises a first contact portion appeared on an outer face of the peripheral wall of the header body, a second contact portion appeared on an inner face of the peripheral wall, a ceil portion formed between the first contact portion and the second contact portion and overstriding the peripheral wall, and a soldering terminal formed on an end of the second contact portion by bending substantially at right angle, at which the post is soldered on a circuit pattern of a circuit board.
Each contact comprises a plate spring portion, a fitting portion at which the contact is held on the socket body and a terminal portion to be soldered on a circuit pattern on a circuit board, which are integrally formed from a front end to a rear end of the contact. The fitting portion has a first contact portion disposed along an inner face of a peripheral wall of the socket body and to be contacted with the first contact portion of the post of the header, and a ceil portion overstriding the peripheral wall and an arm portion substantially parallel to the first contact portion. The plate spring portion has a lateral portion, a first slanted portion, a curved portion, a second slanted portion, and a doglegged second contact portion to be contacted with the second contact portion of the post of the header. The lateral portion is formed by bending substantially at right angle for protruding inwardly from a lower end of the first contact portion of the fitting portion. The first slanted portion is formed by bending at a predetermined angle with respect to the lateral portion from a top end thereof; the curved portion is formed by bending from the top end of the first slanted portion so as to be turned back substantially in the opposite direction; the second slanted portion is formed as an elongation of the fourth curved portion; and the second contact portion is formed for incurving an elongation of the second slanted portion.
By such a configuration, since no shear plane is appeared on the surface of contact portions of the post, the contact may not be deformed due to the contact be caught on the post when the header is coupled with the socket. Furthermore, since the plate spring portion of the contact can have a sufficient length for generating a necessary contact pressure, not only the electric connection between the post of the header and the contact of the socket can be much more reliable, but also the stress in the plate spring portion can be reduced. As a result, the life of the contact can be extended. Still furthermore, since the post and the contact are contacted at two points, the plate spring portion of the contact can be made tough with respect to undesirable force when the header is coupled with the socket.
A low-profile connector in accordance with another aspect of the present invention constituted by a header and a socket, which are respectively mounted on circuit boards for connecting electric circuit formed on the circuit boards. The header comprises a header body made of resin molding, and a plurality of posts provided at a predetermined pitch on a peripheral wall of the header body. The socket comprises a socket body made of resin molding and a plurality of contacts provide at the predetermined pitch on a peripheral wall of the socket body, which are to be contacted with the posts provided on the header. At least one of the header and the socket further comprises at least a reinforcing member provided in a portion of a peripheral wall of the header body and the socket body where the posts and the contacts are not provided.
By such a configuration, since the reinforcing member is provided in the header body and/or the socket body at a portion where no post and/or no contact is provided, the mechanical strength of the header body and/or the socket body with respect to external force can be increased. As a result, possibility of occurrence of contortion and/or crack becomes much smaller than that of the conventional connector.
An embodiment of the present invention is described with reference to the drawings.
As can be seen from
A plurality of pairs of through holes 13a is formed corresponding to the arrangement of the contacts 11 on the bottom wall 13 (see
A height of the socket body 10 is, for example, 0.8 mm so as to make the stacking height of the low-profile connector less than 1.0 mm. If the socket body 10 is formed only by resin molding, the possibility of occurrence of contortion or crack becomes higher due to the reduction of the strength. Thus, a pair of socket reinforcing plates 17 made of a metal thin plate is inserted into the end portions 12B of the peripheral wall 12 of the socket body 10, as shown in
As can be seen from
Details of the socket 1 are described with reference to
Details of the socket reinforcing plate 17 are shown in
The contact 11 is made of conductive metal thin plate such as beryllium copper, and formed be punching and bending the metal thin plate to a predetermined shape. Details of the contact 11 are described with reference to
The contact 11 has a plate spring portion 31, a reverse U-shaped fitting portion 32 and a terminal portion 33 which are integrally formed from a front end to a rear end of the contact 11. The fitting portion 32 further has a first arm 32a, a ceil portion 32b, a second arm 32c, a first curved portion 32d between the first arm 32a and the ceil portion 32b, a second curved portion 32e between the ceil portion 32b and the second arm 32c, and a pair of protrusions 34 formed substantially at the center of side faces of the first arm 32a. An outer face of the second curved portion 32e is a little protruded from an outer face of the second arm 32c. Furthermore, a distance D1 between the inner faces of the first arm 32a and the second arm 32c is made substantially the same as but a little smaller than a thickness of the peripheral wall 12 in the fitting groove 12a.
The terminal portion 33 further has a soldering terminal 33a formed by bending substantially at right angle for protruding outwardly from a lower end of the first arm 32a of the fitting portion 32, and a third curved portion 33b between the soldering terminal 33a and the lower end of the first arm 32a of the fitting portion 32. A width of the third curved portion 33b is a little narrower than a width of the soldering terminal 33a.
The protrusions 34 are protruded outwardly from the side faces of the first arm 32a so that a width between the protrusions 34 is made a little wider than the width of the fitting groove 12a on the peripheral wall 12 of the socket body 10. A width of the fitting portion 32 except the protrusions 34 is made a little wider than the width of the soldering terminal 33a, but a little narrower than the width of the fitting groove 12a.
A thickness of the contact 11 from the soldering terminal 33a to the first curved portion 32d of the fitting portion 32 is substantially the same as a thickness, for example, 0.1 mm of an original blank of the contact 11. Another thickness of the contact 11 from the first curved portion 32d of the fitting portion 32 to the plate spring portion 31 is made, for example, 0.08 mm, thinner than the thickness of the blank of the contact 11 by hammering the blank.
The plate spring portion 31 further has a lateral portion 31a, a first slanted portion 31b, a V-shaped fourth curved portion 31c, a second slanted portion 31d, and a doglegged contact portion 31e. The lateral portion 31a is formed by bending substantially at right angle for protruding inward from a lower end of the second arm 32c of the fitting portion 32. The width of the lateral portion 31a is the same as the width of the fitting portion 32 except the protrusions 34. The first slanted portion 31b is formed by bending at a predetermined angle from a top end of the lateral portion 31a in a manner so that a height at a top end 31i of the first slanted portion 31b becomes higher than a height at a rear end 31g of the first slanted portion 31b. Furthermore, a width at a mid portion 31h of the first slanted portion 31b is narrower than a width at the rear end 31g of the first slanted portion 31b. The fourth curved portion 31c is formed by bending from the top end 31i of the first slanted portion 31b so as to turn back substantially in the opposite direction. The second slanted portion 31d is formed as an elongation of the fourth curved portion 31c. The width of the fourth curved portion 31c and the second slanted portion 31d are the same as the width at the top end 31i of the first slanted portion 31b. The doglegged contact portion 31e is formed by incurving an elongation of the second slanted portion 31d. A width of the contact portion 31e is substantially the same as the width of the fitting portion 32 except the protrusions 34.
A peak 31f of the doglegged contact portion 31e is positioned substantially the same level as the inflection point of the fourth curved portion 31c. Since the width of the contact portion 31e is made the same as the lateral portion 31a, the clearances between the inner walls of the guide groove 14a on the table portion 14 of the socket base 10 and the side faces of the contact 11 become much smaller when the contact 11 is contained in the guide groove 14a. Thus, the movement of the contact 11 in a direction parallel to the arrangement of the contacts 11 is restricted, so that the deformation of the contact 11 can be prevented when the header 2 is coupled with the socket 1. Furthermore, the thickness of the plate spring portion 31 and a part of the fitting portion 32 including the second curved portion 32e is made thinner than the thickness of the blank of the contact 11 by hammering, so that the contacting pressure generated by warping of the contacting portion 31e can be increased owing to the work hardening. On the other hand, the thickness of the terminal portion 33 and the fitting portion 32 except the hammered portion is maintained the original thickness of the blank, so that a mechanical strength of the contact 11 suitable for preventing the deformation of the contact 11 can be maintained when the contact 11 is press-fitted into the fitting groove 12a of the socket 1 or when the header 2 is coupled with the socket 1.
For fixing the contacts 11 on the socket body 10, a blank of metal plate (not shown) is processed to form a comb having the same number, width and pitch of teeth as the arrangement of the contacts 11 in the socket 1. The comb is pressed or hammered out in a manner so that the thickness of at least a part of the comb, which will elastically contact with the contacting portions of the posts 21 of the header 2 serving as a counterpart connector when the socket 1 is coupled with the header 2, is made to be thinner than the thickness of the original blank of metal plate. Subsequently, the teeth of the comb are bent to form all the contacts 11 on one side of the socket 1. The fitting portions 32 of the contacts 11 on the same side of the socket 1 are press fitted into the fitting grooves 12a of the socket body 10 at the same time. After fixing the contacts 11 on the socket body 10 of the socket 1, the terminal portions 33 of the contacts 11 are cut from the blank of metal plate. Accordingly, the socket 1 is manufactured. At this time, the distance D1 between the inner faces of the first arm 32a and the second arm 32c is made substantially the same as or a little smaller than the thickness of the peripheral wall 12 in the fitting groove 12a, so that the fitting portion 32 of the contact 11 firmly grips the peripheral wall 12. Furthermore, the protrusions 34 of the fitting portion 32 of the contact 11 are press-fitted into the sidewalls of the fitting groove 12a. Thus, the contact 11 is firmly fixed on the socket body 10.
When the contact 11 is fitted into the fitting groove 12a on the side portion 12A of the peripheral wall 12 of the socket body 10, the plate spring portion 31 of the contact 11 is contained in the guide groove 14a of the table portion 14, and the terminal portion 33 is outwardly protruded from the side portion 12A of the peripheral wall 12. The outer face of the soldering terminal 33a of the terminal portion 33 of the contact 11 is a little protruded outwardly from the outer face 13b of the bottom wall 13 of the socket body 10. As shown in
Subsequently, details of the header 2 is described with reference to
As can be seen from
When the height of the socket body 10 is selected to be 0.8 mm so as to make the stacking height of the low-profile connector less than 1.0 mm, a height of the header body 20 is selected to be, for example, 0.58 mm. Thus, a pair of header reinforcing plates 25 made of a metal thin plate is fitted into the end portions 22B of the peripheral wall 22 of the header body 20.
Details of the header reinforcing plate 25 are described with reference to
A width of the fixing portion 25a and a lower end portion of the first arm 25b is substantially the same as but a little narrower than the width of the outer recess 22b of the end portion 22B of the peripheral wall 22. A width of the bridging portion 25c except the lower end portion of the first arm 25b is substantially the same as but a little narrower than the width of the channel 22c. A width between both outer sides of the fitting portions 25d is substantially the same as but a little wider than the width of the inner recess 22a. A width of the gap between the protrusions 25f of the fitting portions 25d is substantially the same as but a little narrower than a width of a center wall 24a of the T-shaped projection 24.
The header reinforcing plate 25 is fitted into the end portion 22B of the peripheral wall 22 of the header body 20 in a manner so that the fitting portions 25d are press-fitted into the gaps between the inner recess 22a and the T-shaped projection 24, the bridging portion 22c is fitted into the channel 22c and the fixing portion 25a and the lower end portion of the first arm 25b are fitted into the outer recess 22b. Thus, the header reinforcing plate 25 is firmly fixed on the header body 20. The lower end portions of the fitting portions 25d can be inserted into the through holes 23a, so that the header reinforcing plate 25 can precisely be positioned on the header body 20.
As shown in
The hooking protrusion 25g of the header reinforcing plate 25 will be engaged with the hooking recess 17b of the socket reinforcing plate 17 when the header 2 is coupled with the socket 1. At this time, the header reinforcing plate 25 and the socket reinforcing plate 17 are respectively fixed on the circuit board by soldering. On the other hand, it is necessary that the header reinforcing plate 25 and/or the socket reinforcing plate 17 can be warped for engaging the hooking protrusion 25g with the hooking recess 17b. In this embodiment, the reverse U-shaped bridging portion 25c of the header reinforcing plate 25 is not tightly fitted to the end portion 22B of the peripheral wall 22, so that the bridging portion 25c of the header reinforcing plate 25 can be moved or warped a little in a direction for coupling the header 2 with the socket 1. Thus, the header 2 can be coupled with the socket 1.
Hereupon, the header body 20 has a shape that the peripheral wall 22 encloses the rectangular bottom wall 23. For forming the header body 20 by injection molding of insulation resin, melted resin is injected through a gate formed on a molding die correspondingly at a position on an outer face of the header body 20. An example of the position of the gate 28 positioned at an upper left portion of the bottom wall 23 is illustrated in
The posts 21 held on the header body 20 are inserted into the header body 20 by the insert molding process. As shown in
As mentioned above, the posts 21 are inserted in the header body 20 which is formed by resin molding. For fixing the posts 21 on the molding die (not shown), a blank of metal plate (not shown) is processed to form a comb having the same number, width and pitch of teeth as the arrangement of the posts 21 in the header 2. The teeth of the comb are bent or rolled to form the posts 21 on one side of the header 2. A pair of blanks is disposed at predetermined positions of the molding die, and the melted resin is injected into the molding die. After forming the header body 20 with the blanks of metal plate, the soldering terminals 21e of the posts 21 are cut from the blank of metal plate. Accordingly, the header 2 is manufactured.
The portion of the resin filled in an inner hollow of the post 21 serves as a part of the side portion 22A of the peripheral wall 22. In other words, the first contact portion 21a, the second contact portion 21b and a part of the soldering terminal 21e of the post 21 are wound around the side portion 22A of the peripheral wall 22. Outer faces of the post 21 are substantially the same level as or a little protruded from outer faces of the other portions of the side portion 22A of the peripheral wall 22. Since no resin film covers the outer faces of the post 21, the posts 21 can electrically be contacted with the contacts 11 of the socket 1 when the header 2 is coupled with the socket 1.
As can be seen from
Action of the contact 11 when the header 2 is coupled with the socket 1 is described with reference to
Furthermore, the hooking protrusions 25g of the header reinforcing plates 25 provided on both ends of the header 2 are engaged with the hooking recesses 17b of the socket reinforcing plate 17 provided on both ends of the socket 1, as shown in
When external force for pushing the header 2 to the socket 1 is removed, elastic reaction force charged in the plate spring portion 31 is released for restituting the contact 11. The peak 31f of the contact portion 31e of the contact 11 slides on the second contact portion 21b of the post 21 upwardly. Thus, the post 21 is moved upwardly by friction force acted between the contact portion 31e of the contact 11 and the second contact portion 21b of the post 21. Since the post 21 exists between the second arm 32c of the fitting portion 32 and the peak 31f of the contact portion 31e, the contact 11 cannot restitute to the origin and the plate spring portion 31 generates a predetermined contact pressure for contacting the contact 11 with the post 21.
By such a configuration, since the lower end of the post 21 which contacts the contact 11 first is rolled to form the U-shaped contact portion, no shear plane is appeared on the surface of the post 21 inserted in the header body 20. Thus, the contact 11 may not be caught on the post 21 when the header 2 is coupled with the socket 1 and the contact 11 may not be deformed. Furthermore, since the plate spring portion 31 of the contact 11 is rolled, the plate spring portion 31 can have a sufficient length for generating a necessary contact pressure, and the stress in the plate spring portion 31 can be reduced. Still furthermore, the width of the first slanted portion 31b is made gradually narrower for dispersing the stress, so that the stress concentration in the V-shaped fourth curved portion 31c can be prevented.
Furthermore, when the hooking protrusions 25g of the header reinforcing plates 25 are engaged with the hooking recesses 17b of the socket reinforcing plate 17, clicking shock occurs so that the user can feel that the header 2 is coupled with the socket 1. Furthermore, since the header reinforcing plate 25 and the socket reinforcing plate 17 are made of metal plate, so that the hooking protrusion 25g rarely wears and the clicking shock can be maintained even when coupling and decoupling are repeated. Still furthermore, when the header 2 is coupled with the socket 1, the peripheral wall 22 of the header body 20 of the header 2 is guided by the chamfer 15a on the peripheral wall 12 of the socket body 10 of the socket 1, so that the header 2 can easily be positioned with respect to the socket 1. Still furthermore, the header 2 can also be positioned with respect to the socket 1 by contacting the projections 24 provided on the header body 20 with the recesses 14b provided on both ends of the table portion 14 of the socket body 10. After coupling the header 2 with the socket 1, the projections 24 of the header body 20 are fitted into the recesses 14b of the socket body 10, so that displacement of the header 2 with respect to the socket 1 can be prevented.
A modification of the connector is described with reference to
In this modification, the socket reinforcing plate 17 is inserted substantially for penetrating the end portion 12B of the peripheral wall 12 of the socket body 10, as shown in
As shown in
In the above-mentioned embodiment, the hooking recess 17b and the cuttings 17d are provided on the socket reinforcing plate 17 and the hooking protrusions 25g and 26d are formed on the header reinforcing plate 25 and 26. It, however, is possible to form the hooking recess or cutting on the header reinforcing plate and the hooking protrusion on the socket reinforcing plate.
Furthermore, as shown in
Still furthermore, as shown in
Still furthermore, the protrusion 21d of the post 21 and the offset below the second curved portion 32e of the contact 11 are not indispensable, when the predetermined contact pressure between the contact 11 and the post 21 is assured.
Still furthermore, the positioning legs 16 formed on the bottom wall 13 of the socket body 10 and the positioning legs 27 formed on the bottom wall 23 of the header body 20 are not indispensable, when the socket 1 and the header 2 can be precisely positioned on the circuit boards.
Still furthermore, the socket reinforcing plate 17 is inserted into the socket body 10 in the above-mentioned embodiment. It, however, is possible to press-fit the socket reinforcing plate 17 into the resin molded socket body 10.
This application is based on Japanese patent applications 2002-214319 and 2002-214321 filed in Japan, the contents of which are hereby incorporated by references.
Although the present invention has been fully described by way of example with reference to the accompanying drawings, it is to be understood that various changes and modifications will be apparent to those skilled in the art. Therefore, unless otherwise such changes and modifications depart from the scope of the present invention, they should be construed as being included therein.
Industrial Applicability
In the low-profile connector in accordance with the present invention, the socket reinforcing plates and the header reinforcing plates are provided in the header body and the socket body, so that the mechanical strength of the header body and the socket body can be increased, and the possibility of the occurrence of contortion or crack is decreased. Furthermore, the post of the header and the contact of the socket are contacted at two portions, so that the electric connection between the header and the socket can be maintained even when an external force for moving the header with respect to the socket is applied. Still furthermore, the length of the plate spring portion of the contact can be lengthen in comparison with that of the contact of the conventional connector. Thus, the contacting pressure acting between the contacting portion of the post of the header and the contacting portion of the contact of the socket is increased. Even when the stacking height of the connector is made lower, the reliability of the connection of the posts of the header and the contacts of the socket can be maintained.
Number | Date | Country | Kind |
---|---|---|---|
2002-214319 | Jul 2002 | JP | national |
2002-214321 | Jul 2002 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP03/08868 | 7/11/2003 | WO | 00 | 2/3/2004 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2004/010538 | 1/29/2004 | WO | A |
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5120256 | Walden | Jun 1992 | A |
5259789 | Patel et al. | Nov 1993 | A |
5499924 | Arisaka et al. | Mar 1996 | A |
5836773 | McHugh et al. | Nov 1998 | A |
5885092 | Ito et al. | Mar 1999 | A |
5975916 | Okura | Nov 1999 | A |
6338630 | Dong | Jan 2002 | B1 |
6623308 | Ono | Sep 2003 | B2 |
6645005 | Wu | Nov 2003 | B2 |
6821158 | Iida et al. | Nov 2004 | B2 |
Number | Date | Country |
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0800241 | Oct 1997 | EP |
0991141 | Apr 2000 | EP |
1198031 | Apr 2002 | EP |
Number | Date | Country | |
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20050009383 A1 | Jan 2005 | US |