Patent Application
20110174525
This invention relates to a method to attach a component to a substrate, more particularly, this invention relates to providing a substrate, or printed circuit board, with a through hole extending through a bond pad and into the printed circuit board, and a plate lines the through hole in the printed circuit board, applying a solder paste overlying the bond pad and into the through hole, arranging a component overlying the bond pad on the solder paste, and reflowing the solder paste forming solder that is drawn onto the bond pad, and creating a solder fillet extending within the through hole that bonds the terminal to the bond pad, and bonds the component to the printed circuit board.
It is known to bond a terminal of a component to a bond pad comprising a single uniform area. The bond pad is located on a surface of a substrate, such as a printed circuit board. The component is in contact with solder paste disposed on the bond pad. In an application utilizing surface mount technology, a plurality of terminals of an electronic component that is not a traditional surface mount component, is arranged overlying and level with the bond pad. It is suitable for a capacitor to include additional terminals in addition to the terminal used for the electrical connection, bonded to the same bond pad. The additional terminals are used for mechanical support of the capacitor. Reflow of the solder paste coalesces into solder, forming a single molten melt layer wetting the bond pad and the terminals that solidifies upon cooling. The resulting solder fillet bonds the terminals to the bond pad. The mechanical bonding strength of the solder fillet is limited to the bonding strength of the bond pad attached to the surface of the printed circuit board.
Undesired bonding characteristics are possible when bonding multiple terminals of a component to a bonding pad with a single uniform area. Congregation or pooling of solder below the terminals on the bond pad during reflow of the solder paste lifts the terminals off the bond pad resulting in a raised terminal condition. A raised terminal condition produces an incomplete solder fillet. An incomplete solder fillet is a structurally weak solder fillet having low mechanical and electrical integrity. A solder fillet with low mechanical and electrical integrity compromises effective electrical conductivity and/or mechanical functionality of the capacitor. Additionally, an absence of material, or a void condition, occurring on the solder fillet across the bonding pad as the solder cools, creates a nonuniform, incomplete solder fillet.
Therefore, what is needed is a new method and electronic assembly for bonding a terminal of a component to a bond pad creating a robust, uniform solder fillet having increased mechanical and electrical integrity, while reducing the problematic pooling of solder, raised terminal, and void anomalies, resulting in incomplete, weak solder fillets.
In accordance with the preferred embodiment of the invention, a method is provided for attaching a component to a substrate. The method includes providing a printed circuit board comprising the substrate formed of a solder-nonwettable surface and a bond pad disposed on the surface. The bond pad is formed of a solder-wettable material. The printed circuit board defines a through hole extending through the substrate and the bond pad. The through hole comprises a first portion through the substrate and a second portion through the bond pad registering with the first portion. The printed circuit board further includes a plate lining the first portion in the substrate. The plate lining is formed of a solder-wettable material. The method further includes applying a solder paste overlying the bond pad. As the solder paste is applied to the bond pad, the solder paste fills the through hole including the first portion and second portion lined by the plate. The method further includes arranging the component onto the printed circuit board. The terminal of the component is in contact with the solder paste overlying the bond pad forming an arrangement. The method yet further includes reflowing the solder paste to form a solder fillet bonding the terminal to the bond pad. The solder fillet extends into the through hole attaching the component to the printed circuit board.
In accordance with an additional embodiment of the invention, an electronic assembly comprises a printed circuit board, a component, and a solder fillet. The printed circuit board comprises a substrate being formed of a solder-nonwettable surface. A bond pad is disposed on the surface of the substrate. The bond pad is formed of a solder-wettable material. The printed circuit board defines a through hole extending through the substrate and the bond pad. The printed circuit board further includes a plate lining the through hole within the substrate. The plate is formed of a solder-wettable material. A component includes a terminal that overlies the substrate. The terminal is formed of a solder-wettable material and overlies the bond pad. A solder fillet bonds the bond pad to the terminal, and the solder fillet extends into the through hole.
This invention will be further described with reference to the accompanying drawings in which:
In accordance with the present invention, referring to
Printed circuit board 16 comprises bond pads 20 disposed on surface 14 for bonding capacitor 18. Pad 20 comprises a solder-wettable material formed of an electrically conductive metal such as brass, copper, tin, nickel, silver, or gold, or the like. Pad 20 comprises a positive terminal bond pad 22 and a negative terminal bond pad 24.
Referring to
Referring to
Referring to
Referring to
Positive terminal 26 of capacitor 18 on first section 34 of bond pad 22 is in electrical communication through a conductive pathway, or trace (not shown), within an electronic circuit (not shown) disposed on printed circuit board 16. Preferably, electrical connection of positive terminal 26 of capacitor 18 is made to first section 34 on positive terminal bond pad 22 on surface 14 of printed circuit board 16. Alternately, conductive trace (not shown) is readily adapted to electrically connect first section 34 by through hole 48 on plate 54 on a second substrate surface 56 opposite surface 14.
Referring to
Capacitor 18 further comprises a negative terminal (not shown) and second support terminals (not shown) in proximity to the negative terminal (not shown). Negative terminal (not shown), second support terminals (not shown), and negative terminal bond pad 24 have structure and through holes 48 similar to positive terminal 26, first support terminals 28, and positive terminal bond pad 22, recited herein. Referring to
A method for attaching component 11 to substrate 12, referring to
The method yet further comprises reflowing solder paste 62 forming a solder fillet 68 without overheating and damaging capacitor 18. Solder fillet 68 comprises a first solder fillet 70, a second solder fillet 72, and a third solder fillet 74. First solder fillet 70 bonds first section 34 to positive terminal 26. Second and third solder fillets 72, 74 bond first support terminals 28 to second section 36 and third section 38. Each solder fillet 70, 72, 74 is distinct from each other solder fillet. Reflowing solder paste 62 includes heating assembly 10 including solder paste 62 for a time and at a temperature effective to vaporize vaporizable vehicle 66, whereupon the solder coalesces and melts forming a singular molten melt layer (not shown) that is drawn or wicked into sections 34, 36, 38 from regions of substrate surface adjacent each section 60. Regions of substrate surface adjacent each section 60 are sized effectively to draw the singular molten melt layer (not shown) into sections 34, 36, 38 and into through holes 48. The singular molten melt layer (not shown) wets sections 34, 36, 38, terminals 26, 28, and through holes 48 in sections 34, 36, 38, and is cooled solidifying the solder to form distinct solder fillets 70, 72, 74 overlying sections 34, 36, 38. Solder fillets 70, 72, 74 extend into through holes 48 in sections 34, 36, 38.
Solder drawn into through holes 48 in sections 34, 36, 38 and subsequently cooled provides additional mechanical mounting strength for fillets 70, 72, 74 and increase electrical conductivity for capacitor 18. Solder fillets 70, 72, 74 robustly bond terminals 26, 28 to bond pad 22, thus, attaching capacitor 18 to printed circuit board 16. A solder fillet with a smooth surface (not shown) having a high reflectivity of light typically coincides with a solder joint having high mechanical integrity and high electrical conductivity.
Providing a separate section of bonding pad for each terminal that includes through holes increases the mechanical and electrical integrity of the solder fillet. Negative terminal (not shown) of capacitor 18 and second support terminals (not shown) are arranged over negative terminal bond pad 24 and reflowed in similar fashion to positive terminal 26 on positive terminal bond pad 22, as recited herein.
Part 58 overlying each section 34, 36, 38 and onto region of substrate surface adjacent each section 60 needs to be effectively sized to provide the volume of solder necessary along with drawing solder effectively into each section 34, 36, 38 and through hole 48 to produce robust solder fillets. Not providing the overprinting of part 58 onto region of substrate surface adjacent each section 60 results in an undesired weak, incomplete solder fillet. Referring to
In an alternate embodiment, component 11 is suitable to be an inductor, or a mechanical post. A mechanical post (not shown) is readily adapted to provide mechanical support to a structure disposed on printed circuit board 16.
In a further alternate embodiment, through hole location on the section of the bond pad is suitable to be at any location within an area of each section of the bond pad. The number of through holes utilized in a section is dependent on the mechanical support requirements needed for a specific component.
In yet a further alternate embodiment, the printed circuit board comprises more than one printed circuit board layer, and the through hole extends through the more than one printed circuit board layer. The component is readily adapted to be electrically connected to the electronic circuit by connection with the bond pad or the plate at any printed circuit board layer.
Thus, this invention provides a method and an assembly for robustly attaching an component to a bond pad on a substrate creating uniform solder fillets that have increased mechanical integrity and electrical conductivity on the printed circuit board. The regions of the substrate surface adjacent each section of the bond pad on the printed circuit board allow solder to be drawn into each sections and into the through holes, creating distinct, uniform solder fillets while anchoring the component to the printed circuit board as opposed to only along the surface of the printed circuit board. The solder in the through holes are an extension of the solder fillet on the bond pad providing additional mechanical strength to the solder fillet and the component. Further, plate on the through holes in the substrate is in electrical communication with the bond pad, and the bond pad and the plate are formed of an electrically conductive metal. The electrical conductivity of the bond pad and the plate provides flexibility regarding the connection of the component within an electronic circuit on the printed circuit board. The connection of the component to the electronic circuit by conductive traces is suitable to be realized on the substrate surface to the bond pad, or to the plate on the through hole on the second substrate surface opposite the first surface. A plurality of through holes is readily adapted to be disposed on the bond pad for additional mounting strength of the component to the printed circuit board. The through holes on the bond pad are suitable to be effectively used on printed circuit boards having more than one printed circuit board layer. The invention is easily integrated into existing surface mount technology manufacturing processes avoiding the need and the increased expense for additional manufacturing processes to place components to produce solder fillets comprising increased electrical and mechanical integrity.
While this invention has been described in terms of the preferred embodiment thereof, it is not intended to be so limited, but rather only to the extent set forth in the claims that follow.
