Connector devices are useful in attaching cables to mounting structures of connection surfaces or ports. Connectors providing solderless contact may allow for connections to be quickly and reversibly made between exposed conductors and connection pads.
In some embodiments, the present disclosure relates to a connector for providing solderless contact between a plurality of conductors and a corresponding plurality of contact pads disposed on a substrate. The connector includes an elongated beam extending along a first direction, a plurality of spaced apart resilient first fingers—each first finger extending from the beam and terminating at a finger tip—and a base including a plurality of channels extending along a second direction, each channel being configured to receive n conductors, n being an integer and at least one, the channel corresponding to n resilient first fingers facing a front end of the channel, the finger tips of the n resilient first fingers being lower than the front end of the channel, such that when the channel receives n conductors with a front portion of each conductor extending beyond the front end of the channel and bent so that a front end of the conductor is disposed under a corresponding finger tip, and the connector is positioned on a substrate with the corresponding finger tip disposed on a corresponding contact pad, the corresponding finger tip securely holds the front end of the conductor in contact with the contact pad.
In another embodiment, the present disclosure relates to a connector for providing solderless contact between a plurality of conductors and a corresponding plurality of contact pads disposed on a substrate including a body and a plurality of spaced apart fingers, each finger extending from the body and terminating at a resilient finger tip, such that when a front portion of each conductor in a plurality of conductors is disposed on a corresponding contact pad in a plurality of contact pads disposed on a substrate, the resilient finger tips securely hold the front portions in contact with the contact pads.
Connector 100 includes an elongated beam. Elongated beam 110, in the illustration of
Protruding or extending from elongated beam 110 are spaced apart fingers 112, each having fingertips 114. Fingers 112 may be any suitable size and any suitable shape. For example, fingers 112 may include a first leg and a second leg, where the first leg extends from elongated beam 110 toward along the same direction as primary channels 122 and secondary channels 124, and the second leg makes an oblique angle with the first leg and terminates at fingertip 114. The oblique angle may be acute or obtuse. Fingers 112 may also extend or protrude from any part of elongated beam 110. For example, elongated beam 110 may have a top surface, a bottom surface, and a side surface connecting the top and bottom surface, and one or more of fingers 112 may extend from the side surface or the bottom surface. In some embodiments, fingers 112 are formed from the same material as elongated beam 110. In some embodiments, elongated beam 110 and fingers 112 form part of the same unitary body. Fingers 112 may be formed from a suitable material to be considered resilient; that is, to recover from deformation as the force is removed. Such resilient fingers may be bent or flexed without permanent deformation. The suitable degree resilience may depend on the application, including the design and configuration of both the mounting frame and the mechanism through which connector 100 is mated. Fingers 112 may be formed from at least one of a rubber, a plastic, or an elastomer. In some embodiments, fingers 112 may have an electrically conductive interior while having an electrically insulative exterior; for example, fingers 112 may be metal and may be surrounded by a dielectric. Fingers 112 may include one or more linear segments, one or more curved segments, or some combination of the two. Fingers 112 may be arranged in spaced apart pairs on elongated beam 110, or they may be spaced apart and not paired with another finger. In many embodiments fingers 112 will include both single fingers and pairs of fingers. Pairs of fingers may be spaced apart by a certain first distance (between the fingers of the pair) while the pairs of fingers may be separated by a larger second distance. In other words, the distance between a finger and an immediately adjacent finger may be either a first distance or a second distance greater than the first distance. In some embodiments, the fingers extending from elongated beam 110 may not extend above a maximum height of the beam. In some embodiments, fingers 112 may have a different shape for top surfaces and bottom surfaces. Fingers 112, further, need not all be the same shape. In some embodiments, each fingertip of each pair of fingers may be electrically insulative, while the fingertip of each single finger may be electrically inductive. Fingertips 114 may be rounded, pointed, multi-tipped, flat, or may have any other suitable shape. In some embodiments, fingertips 114 may be electrically insulative. In some embodiments, fingertips 114 may be electrically conductive. Some fingertips may be electrically insulative while others are electrically conductive.
Base 120 includes primary channels 122 and secondary channels 124, which may be collectively referred to as channels. Base 120 may be a substantially planar surface. In some embodiments base 120 has substantially the same width as the length (i.e. the longitudinal direction) of elongated beam 110. Base 120 may be primarily used to support a cable configured to fit within connector 100. Base 120 may have any suitable length and thickness. In some embodiments, the thickness of base 120 may vary along at least one of its length or width. In some embodiments, base 120, elongated beam 110, and fingers 112 may form a unitary construction.
Base 120 includes channels. Primary channels 122, in the configuration shown in
Side 130 may be attached to elongated beam 110 or base 120. In some embodiments, side 130 is attached to both elongated beam 110 and base 120 and forms a unitary construction. Connector 100 may include side 130 on one, two, three, or more sides, depending on the geometry of base 120 and the desired overall shape of connector 100. Side 130 may be made from the same material as or a different material from other parts of connector 100.
Overall, connector 100 may be formed through any suitable process, including injection molding, metal or powder injection molding, or the like. Any suitable material, including plastics, metals, polymers, or other organic or inorganic material may be used, and the materials may be selected to be lightweight, physically durable, flexible or pliable, warp- or melt-resistant, or otherwise optimized for the ambient conditions of the desired use. For some applications, it may be desirable for connector 100 to be electrically non-conducting for safety reasons, or to prevent static discharge. In some embodiments, parts of connector 100 such as elongated beam 110 and sides 130 may be disconnectable or easily reattachable.
Substrate 440 may be any suitable mounting surface, including any combination or combination of materials. Substrate 440 is at least in part electrically non-conductive. Substrate may be any suitable shape and size, not necessarily thin and substantially planar as depicted in
Cable 450 includes conductors 452 and drain wire 454, insulation 456, and jacket 458. In some embodiments, cable 450 may be a flat or substantially flat ribbon cable. Conductors 452 can include or be formed from any suitable electrically conductive material, and may be selected for its electrical or physical properties, for example, conductivity, coefficient of thermal expansion, malleability, or ductility. Suitable materials include copper, aluminum, and silver. Drain wire 454 may have similar characteristics or be formed from a similar material as conductors 452, or it may have different dimensions or composition. Insulation 456 can include any suitable dielectric material for insulating conductor 452 and may be selected for flexibility, melting point, dielectric constant, or any other physical or electrical property or properties. Suitable materials include polyethylene, polyethylene foam, or polytetrafluoroethylene. The materials for both conductors 452 and insulation 456 may be selected to give an overall nominal characteristic impedance within a desired range. Drain wire 454 may be uninsulated. In some embodiments, the front portions or ends of conductors 452 or drain wire 454 may be coined or plated (for example, with gold) to improve contact or conductivity. Conductors and drain wire may be any suitable wire gauge.
Jacket 458 may be any suitable material to impart desirable external properties on cable 450, such as abrasion or fire-resistance. In some embodiments, a flexible material may be selected to preserve desired physical properties of cable 450. Jacket 458 may also be thick to prevent damage or wear to the internal conductors 452 associated with use. In some embodiments, jacket 458 may also include one or more conductive layers along the interior perimeter of jacket 458, such as a braided copper layer or silver plating. Conductive layers may help prevent electromagnetic fields within the cable from radiating into the external environment or from interfering with nearby electronic components. In some embodiments, jacket 458 may be formed from a polymeric material.
In the overall connected configuration of
Frame 770 is attached to substrate 740 and provides a mounting mechanism for the connector to attach. Frame 770 may have a front wall and opposing substantially parallel side walls, as depicted in
Directly and solderlessly connecting a connector to a board such as substrate 740 in
The following are a list of items of the present disclosure:
Item 1 is a connector for providing solderless contact between a plurality of conductors and a corresponding plurality of contact pads disposed on a substrate, the connector comprising:
an elongated beam extending along a first direction;
a plurality of spaced apart resilient first fingers, each first finger extending from the beam and terminating at a finger tip; and
a base comprising a plurality of channels extending along a second direction, each channel being configured to receive n conductors, n being an integer and at least one, the channel corresponding to n resilient first fingers facing a front end of the channel, the finger tips of the n resilient first fingers being lower than the front end of the channel, such that when the channel receives n conductors with a front portion of each conductor extending beyond the front end of the channel and bent so that a front end of the conductor is disposed under a corresponding finger tip, and the connector is positioned on a substrate with the corresponding finger tip disposed on a corresponding contact pad, the corresponding finger tip securely holds the front end of the conductor in contact with the contact pad.
Item 2 is the connector of item 1, wherein the elongated beam, the plurality of spaced apart resilient first fingers, and the base form a unitary construction.
Item 3 is the connector of item 1 being a unitary construction.
Item 4 is the connector of item 1, wherein the first direction is perpendicular to the second direction.
Item 5 is the connector of item 1 having a transverse direction and a longitudinal direction, the first direction being parallel to the transverse direction, the second direction being parallel to the longitudinal direction.
Item 6 is the connector of item 1 having a transverse direction and a longitudinal direction, the first direction being parallel to the transverse direction, the second direction making an oblique angle with the longitudinal direction.
Item 7 is the connector of item 1, wherein each channel has a rear end opposite the front end of the channel, the rear end being higher than the front end.
Item 8 is the connector of item 1 for providing solderless contact between a plurality of conductors and a corresponding plurality of contact pads disposed on a top surface of a substrate, wherein the first direction is parallel to the top surface.
Item 9 is the connector of item 1 for providing solderless contact between a plurality of conductors and a corresponding plurality of contact pads disposed on a top surface of a substrate, wherein the second direction is parallel to the top surface.
Item 10 is the connector of item 1 for providing solderless contact between a plurality of conductors and a corresponding plurality of contact pads disposed on a top surface of a substrate, wherein the second direction makes an oblique angle with the top surface.
Item 11 is the connector of item 1, wherein each channel has a rear end opposite the front end of the channel, such that when the tip securely holds the front end of the conductor in contact with the contact pad, the front end of the channel is closer to the substrate and the rear end of the channel is farther from the substrate.
Item 12 is the connector of item 1, wherein the elongated beam has a maximum length along the longitudinal direction of the elongated beam and a maximum width in a transverse direction perpendicular to the longitudinal direction, a ratio of the maximum length to the maximum width being at least 5, or at least 10, or at least 20, or at least 30.
Item 13 is the connector of item 1, wherein the elongated beam has a top surface, a bottom surface, and a side surface connecting the top surface to the bottom surface, at least one first finger extending from the side surface of the elongated beam.
Item 14 is a the connector of item 1, wherein the elongated beam has a top surface, a bottom surface, and a side surface connecting the top surface to the bottom surface, each first finger extending from the side surface of the elongated beam.
Item 15 is the connector of item 1, wherein the elongated beam has a top surface, a bottom surface, and a side surface connecting the top surface to the bottom surface, at least one first finger extending from the bottom surface of the elongated beam.
Item 16 is the connector of item 1, wherein the elongated beam has a top surface, a bottom surface, and a side surface connecting the top surface to the bottom surface, each first finger extending from the bottom surface of the elongated beam.
Item 17 is the connector of item 1, wherein each first finger comprises a first leg extending from the elongated beam along the second direction toward the plurality of channels, and a second leg extending from an end point of the first leg and terminating at the finger tip, the first leg making an oblique angle with the second leg.
Item 18 is the connector of item 17, wherein the oblique angle is an acute angle.
Item 19 is the connector of item 17, wherein the oblique angle is an obtuse angle.
Item 20 is the connector of item 1, wherein each finger tip comprises an electrically conductive interior and an electrically insulative exterior.
Item 21 is the connector of item 1, wherein each finger tip comprises a metal and a dielectric covering the metal.
Item 22 is the connector of item 1, wherein each finger tip is electrically insulative.
Item 23 is the connector of item 1, wherein the finger tip of at least one first finger is electrically conductive and the finger tip of at least one other first finger is electrically insulative.
Item 24 is the connector of item 1, wherein each finger comprises a resilient material.
Item 25 is the connector of item 1, wherein each finger comprises at least one of a rubber, a plastic and an elastomer.
Item 26 is the connector of item 1, wherein the plurality of spaced apart resilient first fingers comprises at least one pair of first fingers, the first fingers of the at least one pair of first fingers being separated from each other by a first distance, the at least one pair of first fingers being separated from an immediately adjacent first finger by a second distance greater than the first distance.
Item 27 is the connector of item 1, wherein the plurality of spaced apart resilient first fingers forms a plurality of spaced apart single first fingers and pairs of first fingers.
Item 28 is the connector of item 27, wherein the finger tip of each single first finger is adapted to securely hold a front end of a drain wire in contact with a contact pad, and the finger tips of each pair of first fingers are adapted to securely hold front ends of conductors of a differential pair in contact with contact pads.
Item 29 is the connector of item 27, wherein the finger tip of each single first finger is electrically conductive, and the finger tips of each pair of first fingers are electrically insulative.
Item 30 is the connector of item 1, wherein each channel has an arcuate cross-section in a direction normal to the second direction.
Item 31 is the connector of item 1, wherein each two neighboring channels in the plurality of channels are separated by a ridge.
Item 32 is the connector of item 1, wherein the plurality of channels comprises:
a plurality of first channels, each first channel being configured to receive m insulated conductors, m being an integer and at least two, the first channel corresponding to m resilient first fingers facing a front end of the first channel, the finger tips of the m resilient first fingers being lower than the first channel; and
a plurality of second channels, each second channel being configured to receive p uninsulated conductors, p being an integer and at least one, the second channel corresponding to p resilient first fingers facing a front end of the second channel, the finger tips of the p resilient first fingers being lower than the second channel.
Item 33 is the connector of item 32 further comprising (m−1) spaced apart second fingers extending from the front end of each first channel toward the elongated beam, such that when the first channel receives m conductors with a front portion of each conductor extending beyond the front end of the channel, each second finger is disposed between the front portions of two neighboring conductors.
Item 34 is the connector of item 1, wherein each channel is configured to receive 1 or 2 conductors.
Item 35 is the connector of item 1, wherein when the finger tip securely holds the front end of the conductor in contact with the contact pad, the conductor generally has a Z shape between the front end of the channel and the contact pad.
Item 36 is the connector of item 1 further comprising an electrically conductive shield comprising a shield finger associated with a channel, the shield finger extending from a front end of the shield toward the finger tip of a first finger corresponding to the channel and terminating at a shield tip disposed under the finger tip, such that when the channel receives a conductor with a front portion of the conductor extending beyond the front end of the channel and bent so that a front end of the conductor is disposed under the finger tip, and the connector is positioned on a substrate with the finger tip disposed on a corresponding contact pad, the finger tip securely holds the front end of the conductor in contact with the contact pad and the shield tip.
Item 37 is the connector of item 1, wherein the shield finger has a linear staircase shape.
Item 38 is a connector assembly comprising:
the connector of item 1 for providing solderless contact between a plurality of conductors and a corresponding plurality of contact pads disposed on a substrate; and
a frame for guiding a placement of the connector on the substrate, the frame comprising a front wall and opposing substantially parallel side walls extending from opposing ends of the front wall, the front wall and the side walls defining, at least partially, an open rear of the frame, such that when the frame is secured to the substrate with the contact pads located between the opposing side walls, the connector makes contact with the substrate by being inserted into the frame from the open rear of the frame, the side walls guiding the connector towards the front wall.
Item 39 is the connector assembly of item 38, wherein the frame further comprises a top wall extending along, but not as far as, the side walls.
Item 40 is the connector assembly of item 39, wherein the top wall and the side walls define a top opening next to the top wall at the rear of the frame.
Item 41 is the connector assembly of item 38, wherein the connector is initially inserted into the frame along a first direction making an oblique angle with the substrate in order to prevent the connector from running into a back stop protruding from a top of at least one of the side walls, followed by further insertion of the connector along a second direction parallel to the substrate after the connector moves past the back stop.
Item 42 is the connector assembly of item 38, wherein the frame further comprises a spring at the front wall, such that when the connector is inserted into the frame and makes contact with the substrate, the spring pushes the connector against the back stop.
Item 43 is a connector for providing solderless contact between a plurality of conductors and a corresponding plurality of contact pads disposed on a substrate, the connector comprising:
a body;
a plurality of spaced apart fingers, each finger extending from the body and terminating at a resilient finger tip, such that when a front portion of each conductor in a plurality of conductors is disposed on a corresponding contact pad in a plurality of contact pads disposed on a substrate, the resilient finger tips securely hold the front portions in contact with the contact pads.
Item 44 is the connector of item 43, wherein the body and the plurality of spaced apart fingers form a unitary construction.
Item 45 is the connector of item 43, being a unitary construction.
Item 46 is the connector of item 43, wherein each finger comprises a first leg extending from the body and a second leg extending from an end point of the first leg and terminating at the finger tip, the first leg making an oblique angle with the second leg.
Item 47 is the connector of item 46, wherein the oblique angle is an acute angle.
Item 48 is the connector of item 46, wherein the oblique angle is an obtuse angle.
Item 49 is the connector of item 43, wherein each finger tip comprises an electrically conductive interior and an electrically insulative exterior.
Item 50 is the connector of item 43, wherein each finger tip comprises a metal and a dielectric covering the metal.
Item 51 is the connector of item 43, wherein each finger tip is electrically insulative.
Item 52 is the connector of item 43, wherein the finger tip of at least one finger is electrically conductive and the finger tip of at least one other finger is electrically insulative.
Item 53 is the connector of item 43, wherein the plurality of spaced apart fingers comprises at least one pair of fingers, the fingers of the at least one pair of fingers being separated from each other by a first distance, the at least one pair of fingers being separated from an immediately adjacent finger by a second distance greater than the first distance.
Item 54 is the connector of item 43, wherein the plurality of spaced apart fingers forms a plurality of spaced apart single fingers and pairs of fingers.
Item 55 is the connector of item 54, wherein the finger tip of each single finger is adapted to securely hold a front end of a drain wire in contact with a contact pad, and the finger tips of each pair of fingers are adapted to securely hold front ends of conductors of a differential pair in contact with contact pads.
Item 56 is the connector of item 43, wherein when the finger tip securely holds the front end of the conductor in contact with the contact pad, the conductor generally has a Z shape between the front end of the channel and the contact pad.
Item 57 is a connector assembly comprising:
the connector of item 43 for providing solderless contact between a plurality of conductors and a corresponding plurality of contact pads disposed on a substrate; and
a frame for guiding a placement of the connector on the substrate, the frame comprising a front wall and opposing substantially parallel side walls extending from opposing ends of the front wall, the front wall and the side walls defining, at least partially, an open rear of the frame, such that when the frame is secured to the substrate with the contact pads located between the opposing side walls, the connector makes contact with the substrate by being inserted into the frame from the open rear of the frame, the side walls guiding the connector towards the front wall.
Item 58 is the connector assembly of item 57, wherein the frame further comprises a top wall extending along, but not as far as, the side walls.
Item 59 is the connector assembly of item 58, wherein the top wall and the side walls define a top opening next to the top wall at the rear of the frame.
Item 60 is the connector assembly of item 57, wherein the connector is initially inserted into the frame along a first direction making an oblique angle with the substrate in order to prevent the connector from running into a back stop protruding from a top of at least one of the side walls, followed by further insertion of the connector along a second direction parallel to the substrate after the connector moves past the back stop.
Item 61 is the connector assembly of item 57, wherein the frame further comprises a spring at the front wall, such that when the connector is inserted into the frame and makes contact with the substrate, the spring pushes the connector against the back stop.
Descriptions for elements in figures should be understood to apply equally to corresponding elements in other figures, unless indicated otherwise. The present invention should not be considered limited to the particular embodiments described above, as such embodiments are described in detail in order to facilitate explanation of various aspects of the invention. Rather, the present invention should be understood to cover all aspects of the invention, including various modifications, equivalent processes, and alternative devices falling within the scope of the invention as defined by the appended claims and their equivalents.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/US15/12341 | 1/22/2015 | WO | 00 |
Number | Date | Country | |
---|---|---|---|
61931332 | Jan 2014 | US |