Patent Grant
7309252
This invention relates generally to electrical connectors, and, more particularly, to low profile connectors for mounting to substrates and connecting wires thereto.
Recent advances in illumination technology have resulted in the prolific use of distributed lighting assemblies in many applications. Distributed lighting assemblies are desirable, for example, for interior and exterior illumination of a vehicle, for decorative, accent, and safety lighting in business, homes, and outdoor illumination of sidewalks, swimming pools, steps, and even for directional and advertisement signage.
Conventional distributed light assemblies include a high intensity light source and a plurality of light transmission conduits (e.g., fiber optic cables, light pipes, and the like) for illuminating locations remote from the light source. A plurality of light sources (e.g., incandescent bulbs, halogen lamps, and the like) have been employed with an equal plurality of light transmission members to produce distributed lighting effects. It is difficult, however, to produce even lighting from the multiple light sources, and the assemblies are not as reliable as desired. Tubular light sources (e.g., neon, fluorescent, and the like) have been utilized to produce more even lighting, but are notably disadvantaged as requiring high voltage power supply converters to operate the tubes. Additionally, tubular light sources have poor impact resistance, rendering them unsuitable for many applications.
Recent technological advances in low voltage light sources, such as light emitting diodes (LEDs), now present low voltage light sources as viable candidates as light sources for distributed lighting assemblies. Low voltage light sources operate at a small fraction of the electrical power of conventionally used light sources and are an attractive option for use in distributed lighting assemblies due to generally lower cost and higher efficiency than conventionally used light sources. Thus far, however, obtaining a reliable and even light output from low voltage light sources in a distributed lighting assembly has proven difficult.
In certain applications, low voltage light devices including LEDs are connected to an aluminum substrate in use, and connecting wires from the low voltage light devices are hand soldered to the substrate. It would be desirable to provide a lower cost and more time efficient manner of connecting the low voltage lighting devices to the substrates. Known connectors, however, are disadvantaged for purposes.
For example, known connectors are typically too large to be effectively used with low voltage lighting devices such as LED packages, because when mounted to the substrate the relative sizes of the connectors and the LED packages can lead to shadows and a non-uniform light emission from the LEDs. Additionally, mounting the connectors to the substrate and retaining the connector to the substrate can itself become problematic due to the low profile of the LED packages.
According to an exemplary embodiment, a low profile connector assembly comprises at least one contact having a surface mount portion and a wire engagement portion extending from the surface mount portion, and a housing insertable over the at least one contact and retained to the at least one contact. The housing encloses the wire engagement portion and has a wire receiving aperture therethrough. The wire receiving aperture provides access to the wire engagement portion when the housing is retained to the contact.
Optionally, the housing and contact define a low profile dimension of approximately 10 mm or less measured substantially perpendicular to a substrate to which the surface mount portion is mounted. The wire engagement portion may include an insulation displacement contact section, a plurality of deflectable fingers configured to engage a wire, a contact beam pivoting in a plane parallel to the surface mount portion when a wire is engaged thereto, or a box clamp contact. The wire engagement portion may be configured for two stage engagement with the housing. A plurality of contacts may be provided, and the contacts may be staggered or offset from one another on opposite sides of the housing.
According to another exemplary embodiment, a low profile connector assembly for mounting to a substrate is provided. The connector assembly comprises a housing, first and second contacts each having a surface mount portion and a wire engagement portion extending from the surface mount portion, and a housing insertable over the first and second contacts and retained to the at least one contact. The housing encloses the wire engagement portion and has a first wire receiving aperture and a second wire receiving aperture each configured to receive respective wires. The wire engagement portions of the first and second contacts are configured to engage and retain the wires, wherein the first and second contacts define a low profile dimension of about 10 mm or less measured perpendicularly to the substrate on which the surface mount portions are to be mounted.
According to another exemplary embodiment, a low profile connector assembly for mounting to a substrate is provided. The connector assembly comprises a housing, and first and second contacts each having a surface mount portion and a wire engagement portion extending from the surface mount portion. Each wire engagement portion comprises a deflectable contact beam extending obliquely to a distal end of the surface mount portion. A housing is insertable over the first and second contacts and is retained to the first and second contacts. The housing encloses the contact beams and has a first wire receiving aperture and a second wire receiving aperture configured to receive respective wires. The contact beams deflect and clamp the wires within the housing.
While various embodiments low profile connectors are described below in an exemplary application of interfacing low voltage lighting devices, such as light emitting diode (LED) packages, it is understood that the low profile connector of the present invention may be beneficial in other applications as well. Low voltage lighting applications are but one potential application of the present invention, and the invention is not intended to be limited to any particular end use or application. The following embodiments are therefore provided for illustrative purposes only.
The substrate 102 is generally flat and planar, and in one embodiment is fabricated from aluminum or another substrate material familiar to those in the art. The contacts 104 are fabricated from a conductive material and in an illustrative embodiment include generally flat and planer surface mount portions 108 in an abutting relationship with the substrate 102, and wire engagement portions 110 extending generally perpendicularly from the surface mount portions 108. The wire engagement portions 110 in one embodiment are insulation displacement contact sections having a wire receiving channel 112 and upper edges (not shown in
The housing 106 has T-shaped end walls 120, 122, front and rear sides 124 and 126, and top and bottom surfaces 128 and 130. The end walls 120, 122 have a first width W1 near the bottom surface 130 and a second width W2 near the top surface 128 that is greater than the width W1. Due to the difference in widths W1 and W2, overhanging ledges 129 are formed in the housing 106 between the top and bottom surface 128 and 130.
Contact cavities 132 are formed in the housing 106 and extend from the top surface 128 to the underside of the overhanging ledges 129 opposite the top surface 128. The contact cavities 132 receive the wire engagement portions 110 of the respective contacts 104 when the housing 106 is inserted downwardly over the contacts 104 in the direction of arrow A. The wire engagement portions 110 of the contacts 104 are retained to the housing 106 with an interference fit, or by other locking and latching arrangements known in the art.
The contacts 104 in the illustrated embodiment are arranged in first and second rows corresponding the housing cavities 132, and accordingly the housing 106 includes three contact cavities 132 arranged in a row along the housing front side 124, and two contact cavities arranged in a row along the housing rear side 126. The contact cavities 132 along the rear side 126 are staggered or offset in relation to the contact cavities 132 extending along the front side 124. As such, the housing 106 may accommodate five contacts 104 oriented in opposite directions along the housing front and rear sides 124 and 126. Greater or fewer contact cavities 132 and associated contacts may be provided in similar or different arrangements in alternative embodiments.
The housing 106 further includes wire receiving apertures 134 in communication with the housing contact cavities 132 such that a connecting wire may be inserted through the wire receiving apertures 134 and into the contact cavities 132. Once the wires are inserted in into the contact cavities 132, the housing 106 may be fitted downwardly onto the contacts 104 from above. As the housing 106 is moved downward in the direction of arrow A, the wire engagement portions 110 of the contacts 104 are received in the contact cavities 132 through the overhanging ledges 129, and the wires are brought into mechanical and electrical engagement with the wire engagement portions 110 of the contacts 104. Because the wire engagement portions 110 include insulation displacement sections, the insulation displacement sections penetrate the wire insulation and the wire conductors are received in the wire channels 112.
The connector 100, in the assembled configuration, may be surface mounted to the substrate 102 using known surface mount soldering techniques. Wires are inserted into the apertures 134 and terminated to the contacts 104 by being pressed downward in the direction of arrow A to a terminated configuration. The wires, therefore, need not be individually terminated to the substrate 102, hut rater may be collectively and simultaneously engaged to the contacts 104 by virtue of the housing 106. The wires need not be stripped of insulation, and tools are not necessary to connect the wires, thereby simplifying installation and reducing installation time and cost.
Further, because the wire engagement portions 110 of the contacts 104 extend upwardly in an L-shape configuration from the contact surface mount portions 108, the connector assembly has a particularly low profile and is amenable for use with low voltage light sources, such as LED packages in distributed lighting assemblies. For example, the connector assembly 100 may extend for a total low profile dimension H, measured generally perpendicular from the top surface of the substrate 102 to the top surface 128 of the housing 106, of about 10 mm or less, and thus, unlike known connectors, the connector assembly 100 may be used with low voltage lighting devices on the substrate 102 without creating shadows in the emitted light from the devices. In a particular embodiment, H is approximately 6.35 mm when the housing 106 is fully installed over the contacts 104, although greater or lesser low profile dimensions H may be employed in other embodiments.
Additionally, the staggered contacts 104 and housing contact cavities 132 provides a compact, space saving configuration providing multiple connections in comparison to other known connectors.
The connector assembly 150 includes a substrate 152, contacts 154 mounted to the substrate 152, and a housing 156 inserted over the contacts 154 and retained thereto.
The substrate 152 is generally flat and planar, and in one embodiment is fabricated from aluminum or another substrate material familiar to those in the art. The contacts 154 are fabricated from a conductive material and in an illustrative embodiment include generally flat and planer surface mount portions 158 in an abutting relationship with the substrate 152, and wire engagement portions 160 extending generally perpendicularly from the surface mount portions 158. The wire engagement portions 160 in one embodiment are insulation displacement contact sections having a wire receiving channel 162 and upper edges 164 configured to pierce outer insulation of a wire 166 in a manner known in the art. The insulation displacement sections of the contacts 154 allow connection to connecting wires 166 of, for example, low voltage lighting devices, without stripping the wire of insulation, and thus result in time and cost savings for installing the connector assembly 150.
The housing 156 has end walls 170, 172, front and rear sides 174 and 176, and top and bottom surfaces 178 and 180. Contact cavities 182 are formed in the housing 156 and extend from the top surface 178 through the bottom surface 180. The contact cavities 182 receive the wire engagement portions 160 of the respective contacts 154 when the housing 156 is inserted downward over the contacts 154 in the direction of arrow B. The wire engagement portions 160 of the contacts 154 include an upper pair of notches 184 and a lower pair of notches 186 which cooperate with retaining features or projections in the housing cavities 182 to retain the housing 156 to the contacts 154. More specifically, the upper notches 186 receive the housing retaining features at a first elevation relative to the substrate 152, and the lower notches 186 receive the housing retaining features at a second elevation relative to the substrate 152 that is lower and closer to the substrate than the first elevation. When the housing is engaged to the upper notches 186, wires 166 may be inserted into the housing 156, and the housing may then be moved to downward in the direction of arrow B to engage the housing 156 to the lower notches 186, wherein the wires are fully engaged to the contacts 154.
The housing 156 includes wire receiving apertures 188 in communication with the housing contact cavities 182 such that a wire 166 may be inserted through the wire receiving apertures 188 and into the contact cavities 182. Once the wires 166 are inserted into the contact cavities 182, the housing 156 may be fitted downwardly onto the contacts 154 from above to enclose and protect the contacts 154. As the housing 156 is moved downward in the direction of arrow B toward the contacts 154, the wire engagement portions 160 of the contacts 154 are received in the contact cavities 182 and the wires are brought into mechanical and electrical engagement with the wire engagement portions 160 of the contacts 160. Because the wire engagement portions 154 include insulation displacement sections, the insulation displacement sections penetrate the wire insulation and the wire conductors are received in the wire channels 162.
The connector 150, in a pre-assembled state wherein the housing 156 is engaged to the upper notches 184 of the contacts 154, may be surface mounted to the substrate 152 using known surface mount soldering techniques. The wires 166 are then inserted into the housing 156 through the apertures 188 and into the contact cavities 182. Once the wires 166 are inserted, the housing 156 may be moved downwardly to engage the lower notches 186 of the contacts 154. Because of the insulation displacement sections of the contact wire engagement portions 160, the wires 166 need not be individually terminated to the substrate 102, but rather may be collectively and simultaneously engaged to the contacts 104 by virtue of the downward movement of the housing 106. The wires 166 need not be stripped of insulation, and tools are not necessary to connect the wires, thereby simplifying installation and reducing installation time and cost.
Further, because the wire engagement portions 160 of the contacts 154 extend upwardly in an L-shape configuration from the contact surface mount portions 158, the connector assembly 150 has a particularly low profile and is amenable for use with low voltage light sources, such as LED packages in distributed lighting assemblies. For example, the connector assembly 150 may extend for a total low profile dimension, measured generally perpendicularly from the top surface of the board to the top surface 178 of the housing 156, of about 10 mm or less, although greater or lesser low profile dimensions H may be employed in other embodiments. Unlike known connectors, the connector assembly 150 may therefore be used with low voltage lighting devices on the substrate 102 without creating shadows in the emitted light from the devices.
The connector assembly 200 includes the substrate 152, contacts 202 mounted to the substrate 152, and a housing 156 inserted over the contacts 202 and retained thereto.
The contacts 202 are fabricated from a conductive material and in an illustrative embodiment include generally flat and planer surface mount portions 204 in an abutting relationship with the substrate 152, and wire engagement portions 206 extending generally perpendicularly from the surface mount portions 204. The wire engagement portions 206 in one embodiment are poke-in wire engagement sections having a generally rectangular frame 208 and deflectable contact fingers 210 extending inwardly from the frame 208 to define a four sided web extending from the inner periphery of the frame 208. When a wire 212 is stripped of insulation 214 on one end thereof to expose inner conductors 216 of the wire, the conductors 216 are received through the inner web of the contact frame 208 and the fingers 210 are resiliently deflected around the respective sides of the conductors 216 to mechanically and electrically engage the conductors 216 to contacts 202. The poke-in wire engagement portions 206 allow for termination of the wires 212 to the contacts 202 with relative ease, especially in comparison to hand soldered termination of the wires 212 which is common to known distributed lighting assemblies.
While the contacts 202 in the illustrated embodiment include four deflectable fingers 210 defining a contact web, it is understood that other numbers of contact fingers (e.g., two contact fingers) may likewise be employed in alternative embodiments while still achieving the benefits of the instant invention.
The housing 156 has end walls 170, 172, front and rear sides 174 and 176, and top and bottom surfaces 178 and 180. Contact cavities 182 are formed in the housing 156 and extend from the top surface 178 through the bottom surface 180. The contact cavities 182 receive the wire engagement portions 206 of the respective contacts 202 when the housing 156 is inserted downward over the contacts 202 in the direction of arrow B. The wire engagement portions 206 of the contacts 202 are retained to the housing 156 with an interference fit in the contact cavities 182, although it is appreciated that other retention features may be employed that are known in the art to retain the contacts 202 to the housing 156.
The housing 156 includes wire receiving apertures 188 in communication with the housing contact cavities 182 such that a wire 212 may be inserted through the wire receiving apertures 188 and into the contact cavities 182. Once the housing 156 is retained to the contacts 202, wires 212 may be inserted tough the housing apertures 188 to engage the wire receiving portions 206 of the contacts 202. Because of the poke-in wire engagement portions 206 of the contacts 202, the wires 212 may be reliably connected to the contacts with reduced installation time and cost.
Further, because the wire engagement portions 206 of the contacts 202 extend upwardly in an L-shape configuration from the contact surface mount portions 204, the connector assembly 200 has a particularly low profile and is amenable for use with low voltage light sources, such as LED packages in distributed lighting assemblies. For example, the connector assembly 200 may extend for a total low profile dimension, measured generally perpendicularly from the top surface of the substrate 152 to the top surface 178 of the housing 156, of about 10 mm or less, although greater or lesser low profile dimensions may be employed in other embodiments. Unlike known connectors, the connector assembly 200 may therefore be used with low voltage lighting devices on the substrate 152 without creating shadows in the emitted light from the devices.
The connector assembly 250 includes the substrate 152, contacts 252 mounted to the substrate 152, and a housing 254 inserted over the contacts 252 and retained thereto.
The contacts 252 are fabricated from a conductive material and in an illustrative embodiment include generally flat and planer surface mount portions 256 in an abutting relationship with the substrate 152, and wire engagement portions 258 extending generally perpendicularly from the surface mount portions 256. The wire engagement portions 258 in one embodiment are box clamp contact sections having a top wall 260 and opposite side walls 262 extending from the top wall 260 in a rectangular configuration. The side walls 260 and 262 include cutout portions or windows 264 therein which cooperate with latching features on the housing 254 to retain the housing 254 to the contacts 252. The top wall 260 of the box clamp wire engaging portions 258 includes a deflectable contact beam 266 which clamps to conductors 216 of a wire 212 in the manner explained below.
The housing 254 has end walls 270, 272, front and rear sides 274 and 276, and top and bottom surfaces 278 and 280. Contact cavities 282 are formed in the housing 254 and extend from the top surface 278 through the bottom surface 280. The contact cavities 282 receive the wire engagement portions 258 of the respective contacts 252 when the housing 254 is inserted downward over the contacts 252 in the direction of arrow B and the housing 254 is latched to the retention windows 264 of the contacts 252. The housing 254 also includes wire receiving apertures 288 in communication with the housing contact cavities 282 such that a wire 212 may be inserted through the wire receiving apertures 288, into the contact cavities 282, and engaged to the wire engagement portions 258 of the contacts 252.
Because of the box clamp wire engagement portions 258 of the contacts 252, the wires 212 may be reliably connected to the contacts with reduced installation time and cost. Further, the side walls 262 of the contact wire engagement portions 258 extend upwardly in a substantially perpendicular manner to the contact surface mount portions 256, and the connector assembly 250 has a particularly low profile and is amenable for use with low voltage light sources, such as LED packages in distributed lighting assemblies. For example, the connector assembly 250 may extend for a total low profile dimension, measured generally perpendicular from the top surface of the substrate 152 to the top surface 278 (
The connector assembly 300 includes the substrate 152, contacts 302 mounted to the substrate 152, and a housing 304 inserted over the contacts 302 and retained thereto.
The contacts 302 are fabricated from a conductive material and in an illustrative embodiment each contact 302 includes a generally flat and planer surface mount portion 306 in an abutting relationship with the substrate 152, a housing engagement section 308 extending substantially perpendicular to the surface mount portions 306, and a wire engagement portion 310 extending from the housing engagement section 308.
The contact surface mount portions 306 are generally rectangular in an illustrative embodiment and lie in a common plane tangential to the substrate 152. The housing engagement portion 308 of the contacts 302 are generally flat and planar and extend perpendicularly or in an L-shape configuration from the surface mount portions 306. The housing engagement portions 308 include retaining projections or bumps 309 extending outwardly therefrom. The housing engagement portions 308 of the contacts 302 are received in slots (not shown) in the housing 304 and are retained thereto with an interference fit by virtue of the retaining projections or bumps 309.
The wire engagement portions 310 of each contact 302 includes a deflectable contact beam 312 extending obliquely from the housing engagement section 308 and also extending over and vertically spaced from the surface mount portion 306. The contact beams 312 extend along a longitudinal axis which is parallel to the surface mount portions 306, and also extend obliquely to the edges of the surface mount portion 306. That is, the contact beam 312 of each contact 302 extends at an angle with the each of the side edges of the rectangular surface mount portion 306 so that a distal end 313 of the contact beam 312 extends beyond and overhangs the distal end 315 of the surface mount portions 306 opposite the housing engagement portions 308. In an exemplary embodiment, the contacts 302 are oriented inversely to one another in a mirror image arrangement wit the contact beams 312 extending in opposite directions and away from one another. The contact beams 312 are constructed to pivot, rotate or deflect about a respective vertical axis 316 extending normally or perpendicularly to the surface mount portions 306 when engaged by a wire 212. Stated another way, the contact beams 312 may rotate in the direction of arrow E about the axis 316 such that the longitudinal axis of the contact beams 312 are deflected in a plane parallel to the plane of the surface mount portions 306 when engaged by a wire 212. That is, the distal ends 313 of the contact beams 312 are moved inwardly in the direction of arrows F and G toward the respective engagement portions 308 when engaged by a wire 212, or more particularly the conductors 216 of the wire 212.
The housing 304 has end walls 320, 322, front and rear sides 324 and 326, and top and bottom surfaces 328 and 330. Contact cavities (not shown in
The contact beams 312 provide for reliable connection to the contacts 302 with reduced installation time and cost. Further, the oblique contact beams 312 result in a particularly compact profile of the contacts 302 and the housing 304. The connector assembly 300 is therefore amenable for use with low voltage light sources, such as LED packages in distributed lighting assemblies. For example, the connector assembly 300 may extend for a total low profile dimension H1, measured generally perpendicularly from the top surface of the substrate 152 (
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.
| Number | Name | Date | Kind |
|---|---|---|---|
| 4223971 | Dola et al. | Sep 1980 | A |
| 4391484 | Foederer | Jul 1983 | A |
| 4820192 | Denkmann et al. | Apr 1989 | A |
| 4865563 | Ney et al. | Sep 1989 | A |
| 4964811 | Hayes et al. | Oct 1990 | A |
| 5091826 | Arnett et al. | Feb 1992 | A |
| 5478248 | Mitra et al. | Dec 1995 | A |
| 5547391 | Benes et al. | Aug 1996 | A |
| 5713767 | Hanson et al. | Feb 1998 | A |
| 5877673 | Kotani et al. | Mar 1999 | A |
| 5890924 | Endo et al. | Apr 1999 | A |
| 6050845 | Smalley, Jr. et al. | Apr 2000 | A |
| 6080006 | Broder | Jun 2000 | A |
| 6093053 | Horioka et al. | Jul 2000 | A |
| 6210204 | Ko et al. | Apr 2001 | B1 |
| 6741453 | Aleardi et al. | May 2004 | B1 |
| 6755678 | Ward et al. | Jun 2004 | B2 |
| 20020055295 | Itai et al. | May 2002 | A1 |
| 20040253974 | Kao et al. | Dec 2004 | A1 |
| Number | Date | Country |
|---|---|---|
| 0413156 | Feb 1991 | EP |
| 0489549 | Jan 1996 | EP |
| Number | Date | Country | |
|---|---|---|---|
| 20060189174 A1 | Aug 2006 | US |
