Disclosed are electrical terminal assemblies for forming electrical connections between wire conductors and rigid conductors, and in particular screwless electrical terminal assemblies in which a spring presses the wire conductor against the rigid conductor.
Connector blocks that include “screwless” electrical terminals or spring terminals for forming electrical connections between rigid conductors or current bars in the connector block and wire conductors are known. The spring terminal utilizes a compressed spring that generates a spring force pressing the wire conductor against the current bar to form the electrical connection therebetween.
A known type of spring terminal utilizes the current bar as a spring retainer. A portion of the current bar is formed as a spring retainer that retains both ends of the compressed spring. The current bar is made of expensive electrically conductive material (typically a copper alloy). Forming the spring retainer in the current bar is expensive both in material cost and manufacturing cost.
Another type of known spring terminal includes a spring in which the spring has a first leg that lies against one side of the current bar and an extension attached to a second leg, with an opening in the extension to receive the current bar. The second leg presses against the second side of the current bar to maintain the spring in the compressed condition. Manufacture and assembly of the spring with the current bar is relatively expensive.
Yet another known type of spring terminal the current bar extends along one wall of a rigid U-shaped member, the spring compressed between the other wall and the contact bar. In this type of spring terminal the U-shaped member effectively compresses the spring between the legs of the member. The U-shaped member is a relatively large component and so material cost is high.
Thus there is a need for a connector block having spring terminals that utilize a spring retainer that is not formed as part of the current bar, has relatively low cost, and is easier to assemble.
Disclosed in one or more embodiments is a connector block having improved spring terminals that includes a spring retainer that is not formed as part of the current bar, is a relatively low cost member, and enables the spring terminal to be installed in the connector block at low cost.
A spring terminal includes a current bar, a spring retainer, and a spring, the spring retainer not integral with the current bar and not integral with the spring.
The spring includes first and second end portions, with the spring compressed between a first portion of the current bar and a first portion of the spring retainer, the first end portion of the spring in pressure contact with the first portion of the current bar and the second end portion of the spring in pressure contact with the first portion of the spring retainer. The spring urges the spring retainer in a first direction away from the first portion of the current bar.
The spring retainer includes a first abutment surface facing the first direction and the current bar includes a first abutment surface facing the first abutment surface of the spring retainer. The first abutment surface of the current bar is located to engage the first abutment surface of the spring retainer with movement of the spring retainer in the first direction whereby the first abutment surface of the current bar resists movement of the spring retainer urged by the spring away from the first portion of the current bar.
The spring retainer is preferably formed as a stamped member from metal plate. Because the spring retainer is not formed in the current bar, the spring retainer can be made from a low-cost material such as steel having better material properties to function as a spring retainer.
In a preferred embodiment, the first and second portions of the current bar are joined together by a ninety-degree bend. The second portion of the current bar includes a notch formed on a peripheral surface of the current bar that includes the abutment surface of the current bar. The spring retainer includes a flange that is closely received in the notch, the abutment surface of the spring retainer located on the flange surface facing the abutment surface of the current bar.
The spring terminal disclosed herein has a number of advantages. The spring retainer is a low-cost component with reduced manufacturing cost. Identical spring retainers can be used with connector blocks having multiple current bars with different bar geometries, simplifying and reducing inventory costs. The spring terminal is easy to assemble.
Other objects and features will become apparent as the description proceeds, especially when taken in conjunction with the accompanying drawing sheets.
The figures illustrate a connector block 10 for forming electrical connections between wire conductors and current bars 16 carried by the connector block 10. The connector block 10 includes a housing 12 and a number of like electrical terminal or spring terminal assemblies 14 in the housing 12, each terminal assembly 14 configured to form an electrical connection between a wire conductor and a respective current bar 16. Because in the illustrated embodiment the terminal assemblies 14 are identical assemblies (although each of the current bars have different geometries), only a single terminal assembly will be described in detail.
The terminal assembly 14 includes an end portion of a conductor bar or current bar 16, a spring 18, and a support plate or spring retainer 20, the spring retainer 20 a body separate from and not integral with the current bar 16 or the spring 18. A respective pusher tool or actuator tool 94 is associated with each terminal assembly 14 and is used to open and close the terminal assembly 14 when inserting or removing a wire conductor.
The current bar 16 is an elongate and rigid electrically-conducting member having a generally rectangular cross-section. The current bar 16 has a terminal end portion 22 and a tail end portion 24. The terminal end portion 22 forms part of the terminal assembly 14 and includes a first, free end contact portion 26 and a second retention portion 28 joined to the contact portion 26 by a right-angle bend 30. The tail end portion 24 extends away from the retention portion 28 to a free end portion 32 configured for making an electrical connection with another circuit element. The illustrated tail end portion 24 is configured to electrically connect to a circuit board, and the tail end portion of each current bar of the conductor block has a different geometry. Other current bar geometries and configurations, including the tail end portion 24 itself forming part of another terminal assembly 14 are possible.
The conductor contact portion 26 has a flat contact surface 34, with a pawl or tooth 35 extending from the surface 34.
The conductor retention portion 28 has a through-opening 36 extending through the thickness of the current bar and spaced from the bend 30. The opening 36 is formed as a rectangular notch in an upper peripheral surface 38 of the retention portion 28.
The spring 18 is a V-spring or leaf-spring made from spring steel and has a first end portion or first leg 40 and a second end portion or second leg 42, the legs 40, 42 extending outwardly away from each other from an arcuate center spring portion 44
The spring retainer 20 is formed from relatively thin steel plate and includes a generally flat, triangular web 46 having a first side 48 and a second side 50, the sides 48, 50 defining a right angle, with first and second flanges 52, 54 extending in the same direction away from the web 46. The first flange 52 has a generally flat inner surface 56 that is perpendicular to the web 46. The second flange 54 has a curved upper flange portion 58 that bends away from the web 46 and a lower flange portion 60 that has a generally flat inner surface 62, the surface 62 perpendicular to the web 46 and also perpendicular to the first flange surface 56.
The housing 12 is made of or molded from a non-conductive material such as plastic resin as is known in the connector block art, and includes a side wall 64 closing a first side of the housing 12 and a peripheral wall 66 extending from the side wall to the second side of the housing, the peripheral wall 66 defining the interior of the housing 12. The housing 12 is configured to be a slice housing, that is, so configured that a number of housings 12 can be placed side-by-side and connected to adjacent housings 12 to form the connector block 10. An example of a connector block formed from a number of slice housings is disclosed in Correll, U.S. Pat. No. 7,491,096, and incorporated by reference as if fully set forth herein. In other embodiments the connector block 10 can be formed from a single housing 12.
The housing 12 has conventional walls, posts, and lugs extending from the sidewall 64 and the peripheral wall 66 to receive and support the current bars 16 in the housing 12 and to interconnect adjacent slice housings 12; these features are conventional and so will not be described herein. The housing 12 also includes structural elements associated with the terminal assemblies 14; each set is associated with a respective terminal assembly 14. A description of only one set of elements will be described below.
A “vertical” wall 68 and a “horizontal” wall 70 extend from the sidewall 64 and are configured to extend along and support the current bar conductor portion 26 and the retainer portion 28 respectively. A spring post 72 extends from the sidewall 64 and carries the center spring portion 44 to mount the spring 18 in the housing 12. An “L” shaped wall 74 extends from the sidewall 64 and is spaced from the sidewall 68. The leg 74 includes a “vertical” wall leg 76 parallel to and facing the vertical wall and a second, shorter “horizontal” wall leg 78 facing the horizontal wall 70.
The horizontal wall 70 includes a notch 80 formed on the inner side of the wall, the notch 80 sized and positioned to closely receive the spring retainer second flange 54. The vertical wall leg 76 includes a notch 82 formed on the inner side of the wall leg, the notch 82 sized and positioned to closely receive the spring retainer first flange 52. The upper ends of each notch 80, 82 have opposed tapered surfaces that assist in guiding the respective spring retainer flanges 52, 54 into the notch.
A tool opening 84 and a conductor wire opening 86 extend through the peripheral wall 66. The tool opening 84 is offset from the spring post 72 towards the vertical wall 68. The conductor wire opening 86 is aligned with the contact surface 34 of the current bar 14 so that a conductor wire inserted through the conductor opening 86 is immediately adjacent the contact surface 34.
Assembly and operation of the spring terminal 14 is described next. The current bar 14 is placed in the housing 12, with the terminal portion 22 extending along the vertical housing wall 68 and the retainer portion 28 extending along the horizontal housing wall 70. The spring 18 is compressed, placed on the spring post 72, and released. The spring 18 is configured such that upon release, the first spring leg 40 makes pressure contact with the current bar contact face 34 and the second spring leg 42 makes pressure contact with the vertical wall leg 76.
The spring retainer 20 is then installed by being placed over the current bar 18 with the first flange 52 over and aligned with the wall leg notch 82 and the second flange 54 over and aligned with the horizontal wall notch 80. The spring retainer 20 is then moved towards the housing 12, with the horizontal wall leg 78 assisting in the proper lateral positioning of the spring retainer 20 relative to the housing 12. As the flanges 52, 54 are received in the respective notches 82, 80 the first flange 52 moves into contact with the spring leg 42, moving the second spring leg 42 away from the wall leg 74 and causing the spring leg 42 to be in pressure contact with the first flange contact surface 56. In this way, the spring 18 is compressed between the current bar 14 and the first spring retainer flange 52, with the spring force applied by the leg 74 carried by the metal spring retainer 20 instead of by the resin wall leg 74.
When the spring retainer 20 is fully installed in the housing 12, the first spring retainer flange 52 is closely received in the vertical notch 82 and the second spring retainer flange 54 is closely received in the horizontal notch 84. The first flange contact surface 56 faces the current bar contact surface 34, and the spring 18 compressed between the two surfaces 56, 34. The second flange upper portion 58 extends through and is closely received in the slot or notch 36 of the current bar retainer portion 28, and the second flange lower portion 60 is closely received in the horizontal wall notch 80 and faces and extends along the outside of the current bar retainer portion 28.
The spring force generated by the spring 18 biases or urges the spring retainer 20 away from the current bar contact surface 34. The spring force also urges the second flange upper portion 58 towards the side of the notch 36 away from the contact surface 34. Because the upper flange portion 58 is closely received in the notch 36, the notch surface 88 facing the flange portion 58 and the flange surface 90 facing that side of the notch 80 form facing cooperating abutment surfaces. By curving the upper flange portion 58, the surface areas of the cooperating abutment surfaces 88, 90 are increased. The abutment surfaces 88, 90 are disposed to engage one another and resist movement of the spring retainer 20 away from the current bar contact surface 34. In this way, a portion of the spring force is transmitted from the spring retainer 20 to the current bar 16, reducing the force applied to the resin housing components to resist relative movement of the spring retainer 20. The second flange lower portion 60 further cooperates with the current bar 16 to resist twisting of the spring retainer 20 urged by the spring force.
The left-most terminal assembly 14 as viewed in
The middle terminal assembly 14 as viewed in
The right-most terminal assembly 14 as viewed in
While the spring 18 is further compressed by the tool 94, additional spring force is applied to the spring retainer 20 urging the retainer 20 away from the current bar contact surface 34. This additional spring force is distributed by the abutment surfaces 88, 90 from the spring retainer 18 to the current bar 16 to reduce additional loading of the resin housing components by the additional spring compression.
In other embodiments, a connector block 10 could include only a single current bar 16, or could have a number of current bars 16 in which the current bar terminal portions 22 have varying geometries wherein each terminal assembly 14 utilizes a different-shaped spring 18 and/or a different-shaped spring retainer 20. In yet other possible embodiments the current bar retainer portion slot 36 could be formed as a through-hole totally surrounded by the current bar. In yet further possible embodiments the spring retainer upper flange portion 58 could fit in the slot 36 with clearance such that the engagement surfaces 88, 90 engage each other with movement of the spring retainer 20 away from the contact surface 34 only when the tool 92 is deflecting the spring 18, the vertical wall leg 74 supporting the spring retainer 18 against the spring force otherwise.
While one or more embodiments have been described, it is understood that this is capable of modification and that the disclosure is not limited to the precise details set forth but includes such changes and alterations as fall within the purview of the following claims.
Number | Date | Country | |
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Parent | 13630264 | Sep 2012 | US |
Child | 14248660 | US |