The subject matter relates to an improved electrical terminal and more particularly to an improved wire trap for the electrical connection and retention of an electrical conductor within an electrical terminal of an electrical connector. The subject matter also relates to improved mating electrical connector housings capable of blind assembly and which, in their connected or engaged position, the external surface of the connector housings substantially lack external features capable of inadvertently capturing a portion of an element brought into physical contact with the external surface.
Electrical terminals are well known in the connector industry. Typically, the terminals include a pin and mating socket, together with a conductor connecting portion. In the event that the terminals are connected to wires, the terminals include a wire connecting section. One such form of wire connecting section is the wire crimp, where the wire is stripped and placed in a terminal end, and then crimped in place where the metal deforms about the conductor to form the electrical connection.
It is desirable in certain applications to not require a crimped connection. Typically, this is in the situation where the wires are stripped on site, and where crimping tools are not readily available. An example of such a situation would be in the lighting industry where overhead lights are installed, and it is easier for the installer to not require a crimped connection.
However, problems can arise with non-crimped connections. For example, inadequate retention forces applied against the wires in the electrical terminal can result in inadvertent withdrawal of the wires from the electrical terminal, causing a discontinuity in the electrical circuit.
What is needed is an electrical terminal construction for providing reliable, crimpless electrical connections.
The present invention relates to an electrical terminal including a body having a first end, a second end, and a channel having an axis, the channel extending at least through the first end toward the second end. The channel is configured and disposed to receive an electrical conductor. A contact gripping element is intermediate of the first and second ends and extends into the channel at an angle from the axis. The contact gripping element is associated with the body. The contact gripping element terminates at an end having a reduced thickness, the contact gripping element being configured to exert a contact gripping contact force on the electrical conductor. In several variations, the contact gripping element is a beam or a leaf spring. Further embodiments include where the contact gripping element is resiliently moveable in a radial direction and where the insertion of the electrical conductor exerts a radial force upon the contact gripping element.
The present invention further relates to an electrical terminal for positioning in a connector housing. The electrical terminal includes a body having a first end, a second end, and a channel, the channel having an axis extending at least through the first end toward the second end, the channel configured and disposed to receive an electrical conductor. A contact gripping element is intermediate of the first and second ends and extends into the channel at an angle from the axis. The contact gripping element is associated with the body. The contact gripping element terminates at an end having a reduced thickness, the contact gripping element being configured to exert a contact gripping contact force on the electrical conductor. The body includes a locking portion configured to lock the body in the connector housing. The locking portion defines a locking shoulder, and the locking portion being positioned through the channel, whereby the locking shoulder is backed up by the body.
The present invention yet further relates to an electrical terminal for positioning in a connector housing. The electrical terminal includes a body having a first end, a second end, and a channel having an axis extending at least through the first end toward the second end, the channel configured and disposed to receive an electrical conductor. A contact gripping element is intermediate of the first and second ends and extends into the channel at an angle from the axis. The contact gripping element is associated with the body. The contact gripping element terminates at an end having a reduced thickness, the contact gripping element being configured to exert a contact gripping contact force on the electrical conductor. The body includes a locking portion configured to lock the body in a housing.
The present invention further relates to an electrical connector assembly including a first and a second electrical connector connectable along an axis, each electrical connector having a first and a second end. Each electrical connector includes a housing configured and dimensioned for receiving at least one electrical terminal, each electrical terminal of the first electrical connector making physical contact with a corresponding electrical terminal of the second electrical connector during connection thereof. A first keying arrangement polarizes to assure proper orientation of the first electrical connector with the second electrical connector during connection thereof. The housing of the first electrical connector has an extension portion extending longitudinally past the first end of the first electrical connector. The extension portion partially receives the first end of the second electrical connector to substantially axially align the first and second electrical connectors. The axial alignment is achieved prior to physical contact between corresponding electrical terminals of the first and second electrical connectors.
In another variation, the body includes a longitudinal seam extending along a length of the body from the open end to a second end of the body. Furthermore, the contact gripping element is transverse to the seam. In one embodiment, the body is configured such that the seam widens upon insertion of the electrical conductor into the channel. More preferably, the seam is configured to reduce the radial force applied upon the contact gripping element.
The seam comprises a way for relaxing stress on the contact gripping element. When an electrical conductor is inserted into the channel, the electrical conductor places a radial force on the contact gripping element. During insertion of the electrical conductor, the electrical conductor can place a force on the inside surface of the body on the side opposite of the contact gripping element. Since the contact gripping element is resiliently biased in the channel, this radial force may put stress on the contact gripping element at the point of association to the body of the electrical terminal. When the seam is transverse to the contact gripping element, the seam can widen and reduce the radial force placed upon the contact gripping element by the electrical conductor.
In yet another embodiment, a terminal for retention of an electrical conductor comprises an electrical terminal including a contact gripping element, a channel and an aperture. The contact gripping element is disposed through the aperture. The contact gripping element has a distal end disposed in the channel and is configured to be displaced by the electrical conductor where the contact gripping element is configured to exert a contact gripping force on the electrical conductor disposed in the channel. In two variations, the contact gripping element is an arch and a leaf spring.
Further embodiments include where the contact gripping element is resiliently moveable in a radial direction and where the insertion of the electrical conductor exerts a radial force upon the contact gripping element.
In another variation, the body includes a longitudinal seam extending along a length of the body from the open end to a second end of the body. Furthermore, the contact gripping element is transverse to the seam. Preferably, the body is configured such that the seam widens upon insertion of the electrical conductor into the channel. More preferably, the seam is configured to reduce the radial force applied upon the contact gripping element.
In one embodiment, the seam comprises a way for relaxing stress on the contact gripping element. When an electrical conductor is inserted into the channel, the electrical conductor places a radial force on the contact gripping element. During insertion of the electrical conductor, the electrical conductor can place a force on the inside surface of the body on the side opposite of the contact gripping element. Since the contact gripping element is disposed in the channel, this radial force may put stress on the contact gripping element at the point of association to the body of the electrical terminal. When the seam is transverse to the contact gripping element, the seam can widen and reduce the radial force placed upon the contact gripping element by the electrical conductor.
In another embodiment, an electrical terminal comprises a body having an aperture and a locking member extending from the body and at least partially out of the aperture where the locking member is configured to back up to the body. The locking member is configured to be biased by a housing. The locking member is configured to be biased from a first position to a second position which is toward the center of the body during insertion of the body into a housing, and to return to a third position away from the center of the body upon further insertion into the housing. The locking member extends through the aperture and backs up to the body. The locking member provides a structural member to abut the housing. The electrical terminal cannot freely move in a longitudinal direction relative to the housing because of the locking member abutting the housing.
The body includes a longitudinal seam extending along a length of the body. The locking member may be transverse to the seam. The aperture is located across the body from where the locking member associates with the body.
In yet another embodiment, the body further comprises a plurality of locking members, a plurality of point of connections, a plurality of apertures and a plurality of distal ends. At least one of the point of connections is configured to extend away from an adjacent side of the body, at least one of the distal ends configured to extend toward the adjacent side of the body. At least one of the distal ends has a greater width in a circumferential direction than at least one of the point of connections. In a variation at least one of the distal ends is configured to back up to the body during the body insertion into the housing. The electrical terminal cannot freely move in a longitudinal direction relative to the housing because of the locking member abutting the housing. In a variation at least one of the distal ends is disposed in a channel of the body through at least one of the apertures. In another variation at least one of the distal ends is not disposed in a channel of the body through at least one of the apertures. In a separate variation at least one of the apertures is defined by a cutout of a point of connection and at least one of the distal ends.
The body includes a projection where the projection is configured to abut a shoulder of the housing during the body insertion into the housing to thereby prevent further insertion of the body into the housing beyond a locking position. In a variation the projection is a rib where the rib is circumferentially disposed around the body.
An advantage of the present invention is that the terminal can be configured for installation in the connector housing from either direction. That is, the terminal can be installed in the same direction in the connector housing that the electrical conductor is received in the terminal, or in the opposite direction.
A further advantage of the present invention is that the contact gripping element reliably secures the electrical conductor.
A still further advantage of the present invention is that the electrical conductor can be secured without the need for a special tool.
A yet further advantage of the present invention is that the assembled or engaged connector housings substantially lack exterior surface features capable of inadvertently capturing a portion of an element brought into physical contact with the external surface.
An additional advantage of the present invention is an electrical assembly having mating connector housings that are capable of blind assembly.
Other features and advantages of the present invention will be apparent from the following more detailed description of the preferred embodiment, taken in conjunction with the accompanying drawings which illustrate, by way of example, the principles of the invention.
Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
The present invention, referring to
Terminal 2 is preferably stamped and formed from a flat blank material, where the flat blank is roll formed into a pin or socket or similar configuration, and where the side edges of the blank are formed into an abutting longitudinal seam 34. The stamped terminal is comprised of an adequately conductive material, such as a copper alloy material. Locking member 6 is stamped from the blank which forms an opening in body 4, and locking member 6 is thereafter formed to extend through aperture 10.
Body 4 further includes projection 12. As further shown in
Body 4 further includes contact gripping element 28, aperture 30, channel 32 and seam 34. As best shown in
With reference now to
With respect now to
More particularly, the locking sections are formed by stretching and compressing the beam sections 20, such that the sections 20 are longer than the apertures 24 through which they were stamped. Thus, when the sections 20 are formed, and as best shown in
At the same time, the sections are formed such that they contact each other when biased inwardly. As shown in
With the individual components as previously described, the function of one embodiment of electrical terminal 2 will now be described in greater detail. The following described function is equally applicable to other disclosed embodiments.
As best shown in
To achieve the installed position of terminal 2 in connector housing 36, an end 46 adjacent locking portion or member 6 is directed into end 52 of connector housing 36. End 46 and locking member 6 pass inside and through the region of reduced cross section defined between shoulders 38, 40 until projection 12 abuts shoulder 40. Just prior to projection 12 abutting second shoulder 40, locking member 6, which is resiliently biased to enable locking member 6 to pass inside the region of reduced cross section, emerges from the region of reduced cross section and returns, or at least partially returns, to its previous unbiased position. In other words, the tip of locking member 6 returns to its unbiased position, or returns to the extent not prevented by channel 37, upon passing through the reduced cross section of channel 37, i.e., extending past first shoulder 38.
Once locking member 6 returns to its unbiased position, the locking member 6 prevents movement of the terminal 2 in the direction opposite the direction of installation, thereby locking the terminal 2 in position in channel 37. A partially stripped wire 48 having a portion of conductor 50 extending therefrom is directed toward end 52 of connector housing 36, into channel 37, toward end 44 of terminal 2, 14 and into channel 32 of the terminal. As shown in
Stated another way, contact gripping element 28 is resiliently biased into channel 32. An insulated wire 48 may be prepared such that the conductor 50 is exposed, and the electrical conductor 50 may be inserted through open end 44 and into channel 32 of electrical terminal 2, 14, whereupon distal contact section or end 42 of contact gripping element 28 is resiliently moved in a radial direction to exert a contact gripping and contacting force on the electrical conductor 50.
As longitudinal seam 34 is positioned radially transverse to contact gripping element 28, body 4 can be configured in one embodiment to reduce stress applied on the contact gripping element 6 when an electrical conductor is inserted into channel 32, as the seam can slightly open and relieve the stress in the elongate beam section of contact gripping element 28. As shown in
However, in another terminal embodiment which can be used in accordance with this invention, seam 34 could be configured to apply an additional compressive spring force to the conductor 50 to provide improved retention.
It should be appreciated that the embodiment of
As shown in
In addition to angle 66, end 42 of contact gripping element 28 is constructed to be of reduced thickness to achieve improved retention of conductor 50. In a preferred embodiment, this reduced thickness is achieved by a chamfer formed at an angle 64 of about 30 degrees from a surface 70 of contact gripping element 28. In another embodiment, the chamfer angle 64 is at least 20 degrees, but other angular magnitudes can range from about 20 degrees to about 50 degrees, although still other angles less than 20 degrees or greater than 50 degrees can be used. Although a chamfer is directed to removal or forming of material resulting in a planar surface, it is to be understood that removal or forming of material resulting in a reduced thickness of end 42 may be achieved having a nonplanar, and even curved surface adjacent end 42. In addition, the magnitude of the reduced thickness of end 42 is preferably less than half of the original material thickness used to construct the contact gripping element 28, although a lesser percentage reduction is possible. In one embodiment, the thickness is between about 0.007 and 0.003 inch. By reducing the thickness of end 42 of contact gripping element 28, a condition known as skipping is substantially eliminated. Skipping can occur when end 42 fails to maintain physical contact with the surface of conductor 50 when an axial force is applied in a direction opposite the direction of installation of the conductor 50 in the terminal 2. In other words, when subjected to an axial removal force, end 42 fails to properly engage conductor 50, permitting at least partial removal of conductor 50 from terminal 2.
Reducing the thickness of end 42, while not necessarily reduced to the extent produced by sharpening end 42 to a keen or pointed edge, helps provide enhanced retention of the conductor 50. In addition, sharpening end 42 to a keen or pointed edge can cause end 42 to slice through and sever conductor 50 as a result of an axial removal force applied to conductor 50. Therefore, the axial removal force associated with an end 42 having a keen or pointed edge is less, and typically considerably less, than the axial removal force associated with an end 42 having a reduced thickness that has not been sharpened to a keen or pointed edge.
It is to be understood that the actual dimension of reduced thickness of the end 42, the magnitude of the angle 64 of chamfer, the magnitude of angle 66 can vary depending upon the material used to construct electrical terminal 56, the thickness of the material of the electrical terminal, the length of contact gripping element and the amount of constriction of neck 60, among other material or environmental parameters, so that varying any one of these parameters can affect the optimum retention of conductor 50. In one embodiment, sufficient forces associated with removal of conductor 50 results in contact gripping element 28 collapsing upon itself, versus the contact gripping element 28 releasing its hold from conductor 50. It is also to be understood that while the end 42 is shown as a straight or linear, that nonlinear profiles can also be used.
To achieve the installed position of terminal 56 in connector housing 136, end 44 adjacent contact gripping element 28 is directed into end 54 of connector housing 136. End 44 is further directed inside channel 37 until end 44 abuts a region of reduced cross-section, such as a shoulder 68 as shown in
Referring to
As shown in
One embodiment of connector housing 136 further includes a pair of opposed non-cantilevered resilient portions 146 (
As a result of a compressive force applied to the non-cantilevered resilient portions 146, elastic deformation of each non-cantilevered resilient portion 146 toward base 148 pivotably urges pivot portion 170 toward end 52 of connector housing 136. In response to the pivoting movement of pivot portion 170, the end of flange 156 opposite pivot portion 170, including retainer 158, is urged away from base 148 of connector housing 136. Sufficient movement of retainer 158 disengages retainer 158 from retainer 164 of connector housing 138 (
Referring to
The novel construction of connector housings 136, 138 permit “blind assembly” of connector housings 136, 138 to each other. The term blind assembly is defined to mean that connector housings 136, 138 can be assembled to each other without requiring the installer to visually perceive the connector housings 136, 138 while attempting to engage or connect the connector housings 136, 138. Achieving blind assembly with known art connector housing constructions is extremely difficult unless the installer possesses extraordinary manual dexterity and coordination, or is lucky. This need for visual perception is typically required, since the connector housings require simultaneous axial alignment and alignment of keying arrangements before any meaningful amount of mating engagement could begin to occur.
While the connector housings 136, 138 of the present invention still require simultaneous axial alignment and alignment of keying arrangement before mating engagement can occur, the provision of extension portion 150 (
Once partial preliminary assembly has been achieved, as described above, by virtue of the curved portions 160 defining an oval slot that is conformally received by the larger oval slot defined by the inside surfaces of extension portion 150, the ends 54, 140 of the connector housings 136, 138 are substantially guided into axial alignment. However, in addition to axial alignment, to achieve connection of the connector housings 136, 138, the keying arrangements 152, 154 (
Alternately, the installer can rotate both of the computer housings 136, 138 about a longitudinal axis that is parallel to axis 144 (
However, it is to be understood that even when substantially continuous physical contact between the ends 54, 140 of connector housings 136, 138 is not maintained, or possibly not ever established during the rotation(s) of connector housings 136, 138, by maintaining sufficient partial preliminary assembly between end 140 of connector housing 138 inside extension portion 150, substantial axial alignment between connector housings 136, 138 is similarly maintained.
It is to be understood that the widths or angular arrangements of the ridges 162 (
In summary, extension portion 150 permits partial preliminary assembly which provides additional stability for achieving connection without requiring visual perception of the connectors. Such capability is extremely desirable where there is a lack of light and/or an extremely limited or awkward installation environment. In such instances, once the wires leading to the connector housings are determined, it is possible simply to grasp one wire in each hand, sliding the wires through each hand until a connector housing rests in each hand. Once a connector housing is positioned in each hand, the connector housings can be easily connected, as previously discussed. Therefore, it is a relatively straightforward matter to both locate and assemble or connect/engage or disconnect/disengage connector housings without benefit of visual assistance.
It is to be understood that while the extension portion 150 (
An additional advantageous aspect of the connector housings 136, 138 is that upon connection therebetween, the external surface 176 (
While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.
This application is a divisional of U.S. Utility application Ser. No. 11/532,075, filed Sep. 14, 2006, and entitled “Electrical Contact with Wire Trap. U.S. Utility application Ser. No. 11/532,075 is a continuation in part of application Ser. No. 11/343,570, filed Jan. 31, 2006, and a continuation in part of Application No. 60/736,636, filed Jan. 31, 2006. All three disclosures of which are incorporated as if fully rewritten herein.
Number | Date | Country | |
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60736636 | Nov 2005 | US |
Number | Date | Country | |
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Parent | 11532075 | Sep 2006 | US |
Child | 12313815 | US |
Number | Date | Country | |
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Parent | 11343570 | Jan 2006 | US |
Child | 11532075 | US |