The invention relates to splices for splicing together first and second cables.
Splicing connectors may be used to join a variety of electrical conductors, including high-voltage power lines. Some splicing connectors allow a user to simply input two different conductors into the connector. Such splicing connectors, commonly referred to as automatic splices, may be used by utility linemen to quickly connect lengths of suspended cables during installation or repair of downed power lines.
An automatic splice typically includes a housing having an opening on each axial end for receiving cables. After the cables are inserted, the housing includes clamps for maintaining the cables in a relative position. The automatic splice is then capable of conducting electricity from one cable to the other. Seating the cables properly in the housing is important to ensure a secure and lasting connection. This seating is especially true in exposed cables undergoing stress from different directions, such as from wind, ice, galloping or additional loading that may occur in regular use.
Utility linemen use automatic splices in normal or emergency power restoration situations, under a variety situations and environmental conditions. Applying significant force to insert the cables or knowing if the cable has been fully inserted may be difficult for the lineman. Automatic splices typically have non-transparent casings or housings, making visual inspection of the cables positioning impossible. If a cable is not properly or fully inserted, the retaining clamps will not function as intended. Failure of a spliced connection can release live cables, risking dangerous conditions to people and property, especially in the instance of live power lines.
A cable splice includes a casing, a jaw assembly, a biasing member, a guide, and a bullet cup. The casing has an opening and an interior cavity. The jaw assembly is positioned in the interior cavity and moveable between a loading position and a terminated position. The biasing member biases the jaw assembly towards the terminated position. The guide includes a receiving end and a shaft extending at least partially into the interior cavity. The bullet cup extends at least partially into the guide and is positioned in the jaw assembly in the loading position.
A cable splice includes a casing, a jaw assembly, a biasing member, a guide, and a bullet cup. The casing has an opening and an interior cavity. The jaw assembly is positioned in the interior cavity and moveable between a loading position and a terminated position. The biasing member biases the jaw assembly towards the terminated position. The guide includes a receiving end and a shaft extending at least partially into the interior cavity. The bullet cup is positioned in the jaw assembly in the loading position and has a first chamber with a first diameter and a second chamber with a second diameter less than the first diameter.
A cable splice includes a casing, a jaw assembly, a biasing member, a guide, and a bullet cup. The casing has an outer surface, a first set of dimples formed on the outer surface, an opening, and an interior cavity. The jaw assembly is positioned in the interior cavity and moveable between a loading position and a terminated position. The biasing member biases said jaw assembly towards the terminated position. The guide includes a receiving end and a shaft extending at least partially into the interior cavity and centered in the interior cavity by the first set of dimples. The bullet cup is positioned in the jaw assembly in the loading position.
The aspects and features of various exemplary embodiments will be more apparent from the description of those exemplary embodiments taken with reference to the accompanying drawings, in which:
In accordance with an exemplary embodiment, an automatic splice 10 includes a casing 12, a guide 14, a bullet cup 16, a clamp in the form of a jaw assembly 18, a biasing member 20, and a center stop 22. The casing 12 includes a substantially tubular body having a first casing end 26 and a second casing end 28 tapering from a cylindrical central region 30, and having an internal cavity 32. The internal cavity may also be divided into a tapered first chamber 34, a tapered second chamber 36, and a cylindrical central chamber 38. One guide 14, bullet cup 16, and jaw assembly 18 are positioned in each of the first and second chambers 34, 36. The center stop 22 is positioned in the central chamber 38 and a pair of biasing members 20 extends from first and second sides of the central chamber 38, respectively.
As shown in
As best shown in
In various exemplary embodiments, the casing 12 includes one or more sets of dimples 48. For example, the central region 30 includes a first set of dimples 48A and a second set of dimples 48B, and the first and second casing ends 26, 28 include a third and fourth set of dimples 48C, 48D, respectively. The first and second sets of dimples 48A, 48B retain the center stop 22. The third set of dimples 48C helps to maintain the guide 14 centered in the casing 12 and concentric with the bullet cup 16. The third set of dimples 48C may directly contact the guide 14 in a centered position or they may be spaced from the guide 14 and positioned to contact the guide 14 if it becomes off-center.
As best shown in
The guide 14 includes a receiving end 50 having a funnel-shaped body surrounding an aperture and a cylindrical shaft 52 extending from the receiving end 50. The receiving end 50 is positioned outside of the casing 12, while the shaft 52 extends into the first chamber 34. In alternative exemplary embodiments, the receiving end 50 and the shaft 52 are positioned either partly or entirely, in the first chamber 34. The receiving end 50 may be a variety of shapes and sizes, depending on relevant factors such as the cable shape and size. The guide 14 may arcuately transition between the receiving end 48 and the shaft 50.
The shaft 52 has a first inner surface defining a first section 54 with a first diameter and a second inner surface defining a second section 56 with a second diameter. The diameter of the first section 54 is less than the diameter of the second section 56. The shaft has a substantially constant outer diameter with a stop 58 and a flange 60. The stop 58 is a projection extending partially or continuously around the shaft 52. For example, the stop 58 need not entirely encircle the shaft 52, and may include a single projection of a determined length or arc, as well as multiple discrete projections. The stop 58 may have different shapes and sizes, including various arcuate and planar surfaces. In the exemplary embodiment shown, the stop 58 has a right-trapezoidal shape in transverse cross-section, with a front stop surface and an angled rear wall. This allows the stop 58 to easily pass along the inner casing surface 42 during insertion of the guide 14 into the casing 12, but assists in preventing the guide 14 from subsequently exiting the casing 12. The stop 58 may impede the withdrawal of the guide 14 from the casing 12 by friction engagement with the tapered inner casing surface 42 at a certain point, or the inner casing surface 42 may be provided with a corresponding projection or tab to engage the stop 58.
The flange 60 extends partially around the shaft 52 to have a substantially C-shaped cross section. In various exemplary embodiments, the flange 60 may be broken up into sections to form ribs. A slot 62 extends into the shaft 52 and is positioned between the ends of the first flange 58. The slot 62 may extend partially into the shaft 52 or entirely through the shaft 52. The flange 60 and slot 62 allow the guide 14 to be placed into casings 12 having different inner diameters. The flange 60 engages the inner casing surface 42 providing a secure fit between the casing 12 and the guide 14, assisting in retaining the guide 14 in position and preventing unwanted movement relative to the casing 12. The slot 62 allows for a certain amount of compression of the shaft 52, allowing the guide 14 to fit into casings 12 having smaller inner diameters.
As best shown in
According to the exemplary embodiment, the bullet cup 16 has a cylindrical outer surface with an open first end and a semi-spherical, closed second end, although a variety of shapes, sizes, and configurations may be used. The bullet cup 16 has a first inner surface surrounding a first chamber 64 with a first diameter proximate to the first end and a second inner surface surrounding a second chamber 66 with a second diameter proximate to the second end. The diameter of the first chamber 64 is greater than the diameter of the second chamber 66, resulting in the bullet cup 16 having a thicker, inner rear wall 67. When the bullet cup 16 is positioned in the jaw assembly 18, the thicker rear wall 67 provides additional support against the force exerted by the jaw assembly 18 on the bullet cup 16, helping to prevent the bullet cup 16 from becoming crushed, deformed, or dislodged. The inner surface surrounding the first chamber 64 has a tapered portion 68, tapering towards the open first end of the bullet cup 16.
As best shown in
Optionally, an identification ring 70 may be included on the automatic splice 10 positioned adjacent the receiving end 48 of the guide 14. The identification ring 70 may be integral with the guide 14 or it may be a separate component that is attached to the guide 14, for example, by sliding the identification ring 70 over the shaft 52. In various exemplary embodiments, the identification ring 70 may use markings or be colored as well as pattern coded to identify the size and type of cables or conductors that are spliced together. For example, if different sized cables are spliced together, the identification rings 70 on either end of the casing may have a different color.
As best shown in
The jaw assembly 18 is positioned between the guide 14 and the biasing member 20. As best shown in
The upper jaw member 76 and the lower jaw member 78 are substantially identical as shown in
The jaw members 76, 78 include one or more radially extending projections 88 and one or more corresponding openings 90. The projections 88 and openings 90 may have a variety of sizes or shapes. The projections 88 and openings 90 are staggered, so that a single part may be used for the upper jaw member 76 and the lower jaw member 78. When placed together, the projections 88 from the upper jaw member 76 will mate with the openings 90 of the lower jaw member 78 and vice versa. This mating relationship couples the upper jaw member 76 to the lower jaw member 78 to prevent one jaw member from moving axially relative to the other jaw, ensuring substantially uniform axial movement between the jaw members 76, 78. The projections 88 extend radially inwardly and have a length preventing disengagement as the jaw members 76, 78 are moved radially away from one another by being pushed towards the central region 30, but also prevents the projections 88 from interfering with movement of the jaw members 76, 78 as they are biased towards the first casing end 26 by extending through the openings 90 and contacting the inner casing surface 42.
As best shown in
The first and second ends 92, 94 of the exemplary biasing member 20 have two or more coils that are approximately in contact. The end coils therefore have a pitch approximately equal to half the thickness of the coils. In an exemplary embodiment, the first two coils and at least half a turn of the second coil are approximately in contact with one another. The coils on the first and second ends 92, 94 have a first outer diameter. The center portion of the biasing member has a number of coils with a second outer diameter that is greater than the first outer diameter. This configuration increases the stiffness of the spring. In various exemplary embodiments, the length, outer diameter, number of coils, and configuration of the spring may vary depending on the required force.
As best shown in
As best shown in
With the automatic splice 10 in the initial, or loading, position, a first cable C1 and a second cable C2 may be loaded into respective ends of the casing 12. Certain cables may utilize multiple strands that can spread or divert as the end of the cable is introduced into the casing 12. The guide 14 receiving end 50 acts to contain the strands of the cables C1, C2 and guide them into and through the respective first and second casing apertures 44, 46.
After passing into the guide 14 a certain distance, the cable C1 engages the bullet cup 16. In various exemplary embodiments the bullet cup 16 is connected to the guide as shown in
After the cable C1 fully engages the bullet cup 16, the exertion of axial pressure by a user pushes the bullet cup 16 and the cable C1 through the jaw assembly 18. Because the bullet cup 16 is already positioned in the jaw assembly 18, the user need not exert substantial force to open the jaw assembly 18 or load the biasing member 20. Moreover, the clamping of the bullet cup 16 and its initial position in the jaw assembly 18 secures the bullet cup 16 such that it will not dislodge and rotate or tumble as it is traveling through the jaw assembly 18, preventing an early termination of the jaw assembly 18 before the cable C1 is fully inserted. The connected bullet cup 16 and initial position in the jaw assembly 18 also prevent any splayed ends of the cable C1 from interfering with the jaw assembly 18 or the biasing member 20 that would adversely affect the connection made by the automatic splice 10.
As best shown in
According to various exemplary embodiments, as the jaw assembly 18 moves forward, it will urge at least a portion of the guide 14 out of the casing 12. Movement of the guide 14 out of the casing 12 can indicate that the cable C1 has been properly terminated, and a user can be sure of a secure connection. The guide 14 may be provided with various indicia, such as markings or colors on the shaft 52 to make it easier for a user to tell that the cable C1 has been secured or to indicate how far the jaw assembly 18 has traveled.
The pilot cup 217 is initially positioned in the jaw assembly 18 to stabilize and provide extra support, helping to prevent misalignment or preactivation of the jaw assembly 18. As best shown in the exemplary embodiment of
As best shown in
The foregoing detailed description of the certain exemplary embodiments has been provided for the purpose of explaining the principles of the invention and its practical application, thereby enabling others skilled in the art to understand the invention for various embodiments and with various modifications as are suited to the particular use contemplated. This description is not necessarily intended to be exhaustive or to limit the invention to the exemplary embodiments disclosed. Any of the embodiments and/or elements disclosed herein may be combined with one another to form various additional embodiments not specifically disclosed. Accordingly, additional embodiments are possible and are intended to be encompassed within this specification and the scope of the appended claims. The specification describes specific examples to accomplish a more general goal that may be accomplished in another way.
As used in this application, the terms “front,” “rear,” “upper,” “lower,” “upwardly,” “downwardly,” and other orientational descriptors are intended to facilitate the description of the exemplary embodiments of the present invention, and are not intended to limit the structure of the exemplary embodiments of the present invention to any particular position or orientation. Terms of degree, such as “substantially” or “approximately” are understood by those of ordinary skill to refer to reasonable ranges outside of the given value, for example, general tolerances associated with manufacturing, assembly, and use of the described embodiments.
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Number | Date | Country | |
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20160006139 A1 | Jan 2016 | US |