1. Field of the Invention
The invention relates to a connector to be mounted to an electric or electronic device, in particular to a circuit board connector, and to a method of mounting or fixing a connector to an electric or electronic device.
2. Description of the Related Art
Japanese Unexamined Patent Publication No. H06-203896 discloses a circuit board connector that has a housing with opposite side surfaces. Board fixing portions are formed integrally with the housing and bulge out sideways from the bottom ends of the opposite side surfaces. The board fixing portions are formed with internally threaded holes. Screws are inserted through screw insertion holes of the circuit board and are fastened to the internally threaded holes.
The outwardly bulging board fixing portions require a large space on the circuit board. Thus, the above-described connector is not well suited for situations where space must be saved.
A circuit board connector could be miniaturized by mounting fixing members on lateral ends of a housing and soldering the fixing members to a circuit board. However, this construction has uncertain mechanical strength as compared to the screw-fastening construction. Thus, there has been a demand to improve fixing reliability to the circuit board.
The present invention was developed in view of the above problem and an object thereof is to improve fixing reliability.
The invention relates to a connector with a housing that can be mounted to an electric or electronic device, such as a circuit board. At least one fixing member is mountable in the housing and is fixable to the electric or electronic device by soldering. The fixing member includes at least one solder entering recess that opens towards the electric or electronic device and a lock is provided on or near a peripheral edge of the solder entering recess.
Solder enters the solder entering recess to increase the soldering area and to enhance a holding force on the electric/electronic device. Solder that enters the solder entering recess is locked by the lock on the peripheral edge of the solder entering recess to enhance the holding force. As a result, fixing reliability to the electric/electronic device is improved.
The solder entering recess preferably is substantially elliptical. Thus, the soldering area can be increased further as compared to a right circular solder entering recess. Further, burrs are less likely to be formed on the peripheral edge of the solder entering recess as compared to a rectangular solder entering recess.
The cross-section of the solder entering recess preferably increases gradually towards that end that faces the electric/electronic device. Thus, the soldering area can be increased even more.
The solder entering recess preferably is a through hole.
The solder entering recess preferably has a variable width along a height direction, so that the hole diameter gradually increases from an intermediate portion along the height direction toward the open end facing toward the electric or electronic device and towards a substantially opposite open end.
The fixing member preferably comprises a main portion to be mounted in a mount groove in or on the housing.
An escaping surface preferably is formed between the main portion and a solder portion where the solder entering recess is provided.
The escaping surface preferably is slanted and may be formed by striking or machining the outer edge of the intermediate portion between the main portion and a solder portion. A bent portion may be left after the solder portion is formed.
The invention also relates to a method of mounting a connector to an electric or electronic device, such as a circuit board. The method comprises providing an electric or electronic device, mounting at least one fixing member in a connector housing and soldering the fixing member to the electric or electronic device so that the solder can enter into at least one solder entering recess formed in the fixing member and open towards the electric or electronic device. The solder enters the solder entering recess and engages a locking portion near the peripheral edge of the solder entering recess.
These and other objects, features and advantages of the present invention will become more apparent upon reading of the following detailed description of preferred embodiments and accompanying drawings. It should be understood that even though embodiments are separately described, single features thereof may be combined to additional embodiments.
A circuit board connector according to the invention is identified by the letter C in
The housing 10 is wide and includes a terminal holding portion 11 for holding the terminal fittings 20. A receptacle 12 projects forward from a front peripheral edge of the terminal holding portion 11. The terminal holding portion 11 is formed with terminal insertion cavities 13 and the terminal fittings 20 are insertable the cavities 13 from behind. The terminal insertion holes 13 are arranged substantially side by side along widthwise direction WD at upper and lower stages. More specifically, twenty two terminal insertion holes 13 are arranged at the lower stage, and nine terminal insertion holes 13 are arranged at each of left and right sides of the upper stage as shown in
The receptacle 12 is a substantially rectangular tube with an open front end, and the mating housing can fit into the receptacle 12 from the front along a connection direction CD. A lock 14 projects down and in at a substantially widthwise middle position of an upper part of the receptacle 12 for engaging a lock arm of the mating housing to hold the two housings in a connected state. A mount groove 15 is provided in each of the opposite sides of the receptacle 12 for receiving the fixing member 30.
A portion of each terminal fitting 20 that projects back from the terminal holding portion 11 is bent down at a substantially right angle. A bottom end of the downward extending portion is bent substantially normal to extend back substantially along the connecting direction CD. A connector-side connecting portion 21 of each terminal fitting 20 projects forward from the front surface of the terminal holding portion 11 and is surrounded by the receptacle 12. The connecting portion 21 is electrically connectable with a mating terminal in the mating housing. A board-side connecting portion 22 is defined at the rear end of each terminal fitting 20 and is electrically connectable by soldering, (ultrasonic) welding, press-fitting or the like with a conductor path (not shown) printed on an outer surface Ka of the circuit board K. The solder attached to the board-side connecting portion 22 is not shown. The terminal fittings 20 at the upper stage are displaced along the widthwise direction WD from those at the lower stage, but the board-side connecting portions 22 of the terminal fittings 20 at the upper and lower stages are at substantially the same positions with respect to the connecting direction CD (see
As shown in
As shown in
Steps 33a are defined at the bottom end of the upper section 33 of the main panel 31 and contact steps 18a at the bottom end of the wide upper section 18 of the main panel accommodating portion 16 when the fixing member 30 is inserted into the mount groove 15. Thus, the fixing member 30 is positioned so that the bottom surface of the fixing member 30 is substantially flush with the bottom surface of the housing 10. Specified clearances are defined between the narrow bottom section 35 of the main panel 31 and the narrow lower section 19 of the main panel accommodating portion 16 when the fixing member 30 is mounted. These clearances open laterally outward to define solder inflow spaces S that permit the inflow of solder H during the soldering operation. Notches 17a are formed at the bottom end of the groove edges of the solder leg accommodating portion 17 to facilitate the inflow of the solder H (see
The solder leg 32 of the fixing member 30 is placed on the outer surface Ka of the circuit board K with the planar surface of the solder leg 32 substantially parallel to the outer surface Ka of the circuit board K. Each solder leg 32 has two solder entering holes 37 that penetrate the respective solder leg 32 along the thickness direction of the solder leg 32 and substantially along the inserting direction ID. Thus, each solder entering hole 37 is open at the side of the solder leg 32 facing towards the circuit board K and an opposite side of the solder leg 32 to permit solder H to flow therethrough. As shown in
As shown in
As shown in
The solder H is applied beforehand at positions on the outer surface Ka of the circuit board K corresponding to the parts of the circuit board connector C planned to be fixed. Thereafter, the circuit board connector C is positioned on the outer surface Ka of the circuit board K. The circuit board K and the properly positioned circuit board connector C then are passed through a high-temperature oven (not shown), in which hot air is circulated.
The solder applied to the circuit board K is melted by the heat in the oven and is attached to the peripheral edges of the board-side connecting portions 22 of the terminal fittings 20. Additionally, the molten solder H is attached to the peripheral edges of the solder legs 32 of the fixing members 30 and enters the solder entering holes 37 and the solder entering spaces 41 to be attached to the peripheral edges of these holes and spaces. The molten solder H is solidified upon cooling and the respective board-side connecting portions 22 and the solder legs 32 are secured to the circuit board K. In this way, the board-side connecting portions 22 are electrically connected with the corresponding conductor paths of the circuit board K and the solder legs 32 are fixed to the circuit board K.
As shown in
The solder entering holes 37 are substantially elliptical in plan view. Thus, the area of soldering is increased further as compared to right circular solder entering holes, and burrs are less likely to be formed at the edges of the solder entering holes 37 as compared to rectangular solder entering holes. Furthermore, the cross-sectional size of each solder entering hole 37 gradually increases towards the open end 37a facing the circuit board K. Thus, a larger area of soldering can be ensured at the open end 37a at the side of the circuit board K, thereby contributing to the holding force onto the circuit board K. The escaping surfaces 40 are formed at the outer edges of the bends 39 of the fixing members 30. Thus, large solder entering spaces 41 are ensured to provide clearances to the circuit board K. As a result, the area of soldering can be even more increased.
As described above, the solder H is locked by the locks 38 and a sufficiently large area of soldering to the circuit board K is ensured. Therefore, the holding force of the circuit board connector C onto the circuit board K is enhanced, resulting in higher fixing reliability to the circuit board K.
The invention is not limited to the above described and illustrated embodiment. For example, the following embodiments are also embraced by the technical scope of the present invention as defined by the claims. Beside the following embodiments, various changes can be made without departing from the scope and spirit of the present invention as defined by the claims.
The cross-section of each solder entering hole can be changed. For example, the cross-sectional size may be smallest at portion(s) of the solder entering hole vertically displaced from the substantially middle along the height direction HD. It is not necessary to set the same cross-sectional sizes for both upper and lower open ends, and the hole diameters at the upper and lower open ends may differ. In such a case, the lock is formed by a portion of the hole edge of each solder entering hole bulging in more than the open end at the side opposite from the circuit board.
The shape of the solder entering holes can be changed. For example, they may be right circular in plan view or rectangular in plan view. Instead of the solder entering holes whose cross-sections continuously change as in the foregoing embodiment, the locking portions may be stepped.
Although the solder entering holes are shown in the foregoing embodiment, solder entering recesses may be formed in the solder legs instead. Specifically, the solder entering recess may vertically penetrate the solder portions and be open sideways, or may be open only at the side toward the circuit board without vertically penetrating the solder legs.
The positions and the number of the solder entering holes in the solder legs can be arbitrarily changed.
The soldering method can be changed arbitrarily. For example, soldering may be carried out after the circuit board connector is placed on the circuit board without applying the solder to the circuit board beforehand.
Number | Date | Country | Kind |
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2004-060795 | Mar 2004 | JP | national |
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5-326049 | Dec 1993 | JP |
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Number | Date | Country | |
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20050221666 A1 | Oct 2005 | US |