Patent Application
20200411210
This disclosure relates to the field of overhead electrical cables for the transmission and distribution of electricity.
Overhead electrical cables for the transmission and distribution of electricity typically include a bare aluminum electrical conductor having sufficient diameter (e.g., cross-sectional area) to safely transmit electricity at high voltages. Although aluminum has a high ratio of conductivity to mass, some aluminum alloys are too weak to be self-supporting when strung between support structures (e.g., between towers), leading to large sags, and a central strength member must be used to support the aluminum conductor. In a typical configuration, individual metal (e.g., aluminum) conductive strands are helically wound around and supported by the central strength member. When installed, the strength member bears the majority of the mechanical (e.g., tensile) load and is installed under high tensile loading. Traditionally, the strength member is comprised of a plurality of steel strands that are twisted together, a cable configuration referred to as aluminum conductor steel reinforced (ACSR). Recently, other materials have been utilized for the strength member, such as advanced fiber-reinforced composite materials having high tensile strength, low coefficient of thermal expansion (CTE) and other desirable thermal and mechanical properties.
One example of an overhead electrical cable having such a composite strength member is the ACCC® overhead electrical cable available from CTC Global Corporation of Irvine, Calif., USA. See, for example, U.S. Pat. No. 7,368,162 by Hiel et al, which is incorporated herein by reference in its entirety. The use of such composite strength members advantageously enables the use of high conductivity, fully annealed aluminum for the outer conductive strands. The modulus of elasticity of the carbon fibers used in the ACCC® composite strength member is higher than the modulus of steel (about 235 GPa for carbon fiber vs. about 200 GPa for steel). In the ACCC® strength member, however, an outer layer of glass fibers (elastic modulus of about 45.6 GPa) that surrounds the carbon results in a combined modulus of the ACCC® composite strength member of about GPa, lower than steel. This outer layer of glass fibers is used to improve impact resistance and increase conductor flexibility, and also serves to insulate the carbon fibers from the aluminum strands to prevent galvanic corrosion.
A number of design criteria go into the configuration of an overhead electrical cable, and the design criteria often depend upon the local climate at the location where the electrical cable is deployed. For example, when the electrical cable is installed in cold climate areas where snow and ice events are common, ice may accumulate on the surface of the outer conductor under low-load or line-off conditions, when little or no current is flowing through a bare overhead electrical cable, due to a lack of heat that is normally present under regular operating conditions. Electrical utilities in very heavy ice areas use an ice thickness of as much as 2 inches (50 mm) to calculate iced conductor weight. The added weight of ice accumulation will increase tension on the cable and may cause a significant increase in cable sag, i.e., an increase in the vertical distance between the support points and the lowest point of the cable. High voltage bare overhead electrical cables often traverse roadways, trees and/or lower voltage overhead electrical distribution cables. If these high voltage transmission cables become loaded with ice and sag too close to these objects, they become very dangerous and can lead to failures and the resulting power outages.
At the same time, the overhead electrical cables must also be able to safely transmit increased electrical loads (e.g., increased voltage) during the warmer summer months when electrical demands are at their highest. Such increased loads can raise the temperature of the cable (due to resistance heating), causing the cable to thermally expand (lengthen) and sag toward the ground, creating the same problems that may be experienced due to ice loading.
One solution to these problems is to utilize higher towers to support the cables. However, this solution comes with an increased cost. Another solution to the ice loading problem is to utilize a strength member having a very high tensile strength, such as a strength member of a fiber-reinforced composite, and to install the cable between support structures at a very high tension.
Heavy ice loading can cause permanent elongation of an overhead electrical cable. As a result of an increase in cable tension due to the added weight of ice, the cable may be stretched beyond its initial yield point, which can prevent it from returning to its initial sag or tension condition after the ice is abated. The improved elasticity of fiber-reinforced composite strength member, such as the ACCC® strength member, allows the cable to return to its initial sag and tension condition after the ice load has dissipated.
There is a need for an overhead electrical cable having a composite strength member that is capable of use under both heavy ice loading conditions and under conditions of very high current, while providing the other benefits associated with the use of the composite strength member.
In one embodiment, such an overhead electrical cable is disclosed. The overhead electrical cable comprises a strength member and a first conductive layer surrounding the strength member, where the first conductive layer comprises strands of a first aluminum material. A second conductive layer surrounds the first conductive layer, where the second conductive layer comprises strands of a second aluminum material. The second aluminum material has at least one material property that is different than the same material property of the first aluminum material.
The foregoing overhead electrical cable may be characterized as having feature refinements and/or additional features, which may be implemented alone or in any combination. In one characterization, the different material property between the first and second aluminum materials is selected from the group of properties consisting of yield stress, elastic modulus, hardness, electrical conductivity and tensile strength. In one particular characterization, one different material property is yield stress. In one refinement, the second aluminum material has a yield stress that is greater than the yield stress of the first aluminum material. In another particular characterization, the different material property between the first and second aluminum materials is tensile strength. In one refinement, the second aluminum material has a tensile strength that is less than the tensile strength of the first aluminum material. In yet another characterization, the different material property between the first and second aluminum materials is electrical conductivity. In one refinement, the second aluminum material has an electrical conductivity that is greater than the electrical conductivity of the first aluminum material.
In another characterization, at least one of the first and the second aluminum materials has an electrical conductivity of at least about 60% IACS (International Annealed Copper Standard). In a further refinement, at least one of the first and the second aluminum materials has a conductivity of at least about 62% IACS. In yet a further refinement, the second aluminum material has an electrical conductivity of at least about 62% IACS. In another characterization, the second aluminum material is a 1350-O annealed aluminum alloy. In yet another characterization, the first aluminum material is a hardened aluminum alloy. In another characterization, the first aluminum material is selected from an aluminum-zirconium (AlZr) aluminum alloy and a 1350-H19 aluminum alloy.
The conductive strands may have a variety of cross-sections, including circular, oval and polygonal. In one characterization, at least one of the first aluminum material strands and the second aluminum material strands are trapezoidal strands. In a further refinement, both of the first aluminum material strands and the second aluminum material strands are trapezoidal strands. The overhead electrical cable may comprise more than two layers of conductive strands. In one characterization, the overhead electrical cable comprises a third conductive layer disposed between the first conductive layer and the second conductive layer. In one refinement, the third conductive layer includes conductive strands of a third aluminum material that is different than the first aluminum material and different than the second aluminum material. In another refinement, the third conductive layer comprises strands of the first aluminum material. In yet another refinement, the third conductive layer comprises strands of the second aluminum material. In yet another characterization, the overhead electrical cable comprises at least a fourth conductive layer disposed between the third conductive layer and the second conductive layer.
In another characterization, the strength member comprises a fiber-reinforced composite strength element. In one refinement, the fiber-reinforced composite strength element comprises substantially continuous reinforcing carbon fibers disposed in a binding matrix. In another refinement, the strength member has a diameter of not greater than about 30 mm. In a further refinement, the strength member has a diameter of at least about 3 mm. In another characterization, the strength member has an ultimate tensile strength (UTS) of at least about 1700 MPa.
In another embodiment, a method for the manufacture of an overhead electrical cable is disclosed. The method includes the steps of wrapping a plurality of first strands of a first aluminum material onto a strength member to form a first conductive layer, and wrapping a plurality of second strands of a second aluminum material around the first conductive layer to form a second conductive layer. The second aluminum material has at least one material property having a value that is different than a value of the same material property of the first aluminum material.
The foregoing method may be characterized as having refinements and/or additional steps, which may be implemented alone or in any combination. In one characterization, the plurality of first strands of the first aluminum material have a trapezoidal cross-section. In one refinement, the plurality of second strands of the second aluminum material have a trapezoidal cross-section.
In another characterization, the method comprises wrapping a plurality of third strands of a third aluminum material around the first conductive layer before the wrapping of the second conductive strands around the first conductive layer. In a further refinement, the method includes the step of wrapping a plurality of fourth strands of a fourth aluminum material around the first conductive layer before the wrapping of the third conductive strands around the first conductive layer.
In another embodiment, a method for the installation of an electrical transmission line is disclosed. The method includes the steps of stringing an overhead electrical cable between at least two support structures and applying tension to the overhead electrical cable. While the overhead electrical cable is under the applied tension, first and second ends of the overhead electrical cable are clipped such that the overhead electrical cable is at least partially supported by the two support structures and is strung at a clipped-in tension. The overhead electrical cable comprises, a strength member, a first conductive layer surrounding the strength member, the first conductive layer comprising strands of a first aluminum material, and a second conductive layer surrounding the first conductive layer, the second conductive layer comprising conductive strands of a second aluminum material that is different than the first aluminum material, wherein the second aluminum material has at least one material property that is different that the same material property of the first aluminum material.
In one embodiment, a bare overhead electrical cable is disclosed. The overhead electrical cable includes a strength member, a first conductive layer surrounding the strength member, and a second conductive layer surrounding the first conductive layer. The first conductive layer includes strands of a first conductive material, and the second conductive layer comprises strands of a second conductive material. The second conductive material has at least one material property that is different than (e.g., has a different value than) the same material property of the first conductive material.
The first conductive strands 126 and the second conductive strands 128 are fabricated from an electrically conductive material, particularly a metal such as copper or aluminum. For bare overhead electrical cables, aluminum is generally preferred due to its good conductivity and low density (e.g., light weight). As is discussed in more detail below, according to one embodiment, the first conductive layer 120 includes strands 126 of a first aluminum material, and the second conductive layer 122 includes strands 128 of a second aluminum material, where the second aluminum material has at least one material property that is different than (e.g., has a different value than) the same material property of the first aluminum material.
As illustrated in
As illustrated in
The configurations for an overhead electrical cable illustrated in
According to the present disclosure, at least one material property of the conductive strands in one conductive layer are different than (e.g., have a different value than) the same material property of the conductive strands in another conductive layer. That is, the conductive (e.g., metallic) materials from which the respective conductive strands are formed may have a different chemical composition (e.g., may be a different alloy), and/or may have been processed in a manner that results in a different material property. For example, heat treatment (e.g., annealing) of some metallic materials may produce a conductive strand with different properties compared to a conductive strand of the same material (same chemical composition) that has not been heat treated. Similarly, work hardening of an alloy with the same chemical composition may result in different mechanical properties.
By way of example, the material property that is different among the conductive strands may be one or more of yield stress, elastic modulus, hardness, tensile strength and electrical conductivity. In one particular embodiment, the at least one material property that is different among the conductive strands is the yield stress. The elastic modulus (i.e., Young's Modulus) is the tensile elasticity of the conductive strand, i.e., the ratio of tensile stress to tensile strain. As the material is subjected to a tensile stress, the material will begin to yield (plastically deform) at some tensile stress, and this point is called the yield stress. Different aluminum alloys and different tempers among similar alloys may have different yield stresses. In one particular characterization, the yield stress of an outer conductive layer (e.g., of the outer layer strands) is greater than the yield stress of an inner conductive layer (e.g., than the inner layer strands). That is, when a tensile stress is applied to the conductive layers, an inner conductive layer will plastically deform (yield) before plastic deformation of the outer conductive layer. For example, referring to
In another characterization, one material property that is different among certain conductive strands is tensile strength. In one particular characterization, an outmost conductive layer has a tensile strength that is greater than the tensile strength of an inner conductive layer. For example, referring to
Table I illustrates the conductivity, tensile strength, yield stress and maximum (continuous) operating temperature for several aluminum materials.
In another characterization, one material property that is different among certain conductive strands is hardness. Hardness is a measure of localized resistance to plastic deformation, e.g., from mechanical indentation or abrasion. In one particular characterization, an outmost conductive layer has a hardness that is greater than the hardness of an inner conductive layer. For example, referring to
In another characterization, one material property that is different among certain conductive strands is electrical conductivity. In one particular characterization, an outmost conductive layer has an electrical conductivity that is greater than the electrical conductivity of an inner conductive layer. For example, referring to
As is discussed above with respect to the figures, the overhead electrical cable includes a strength member around which the conductive layers are wrapped. The strength member may include a plurality of strength elements (e.g.,
One particular example of such a fiber-reinforced composite strength member is used in the ACCC® overhead electrical cable that is manufactured by CTC Global Corporation of Irvine, Calif., USA. Such an overhead electrical cable is illustrated, for example, in U.S. Pat. No. 7,368,162 by Hiel et al. This strength member includes a high-strength carbon fiber inner core surrounded by a glass fiber layer to provide improved flexibility, and to provide resistance to galvanic corrosion of the aluminum conductor by shielding the carbon fibers from the aluminum.
In one characterization, the strength member has a diameter of at least about 3 mm, such as at least about 5 mm. Such a strength member can advantageously have a high tensile strength when fabricated using, e.g., high strength carbon fibers. For example, the strength member may have an ultimate tensile strength (UTS) of at least about 1700 MPa, such as at least about 1800 MPa, at least about 1900 MPa, or even at least about 2000 MPa. In another characterization, the strength member has a rated breaking strength of at least about 100 kN, such as at least about 125 kN, or even at least about 150 kN.
The configuration of the conductive (e.g., aluminum) strands disclosed herein may be particularly useful in regions that experience heavy ice loading. In this regard, to further reduce the effects of ice loading, the overhead electrical cable may utilize a strength member having a large diameter and/or a very high tensile strength. In one characterization, the strength member has a diameter of at least about 8 mm, such as at least about 9 mm, or even at least about 10 mm. As a practical matter, e.g., for storage and transportation, the diameter of the strength member will not be greater than about 30 mm, such as not greater than about 20 mm. In another characterization, the strength member has an ultimate tensile strength (UTS) of at least about 2200 MPa, such as at least about 2300 MPa, such as at least about 2400 MPa, or even at least about 2500 MPa. Although not limited to any particular maximum UTS, the UTS will typically be not greater than about 3700 MPa. In another characterization, the strength member has a rated breaking strength of at least about 150 kN, such as at least about 160 kN, at least about 170 kN, or even at least about 180 kN.
Overhead cables that use a fiber-reinforced composite strength member have a thermal knee-point. Initially, the tensile load of an installed cable is shared by the strength member and the conductive strands. As the cable's temperature rises with increased current, the coefficient of thermal expansion (CTE) of the conductive strands causes them to elongate faster than the lower CTE strength member. As temperature increases, the conductive strands relax and transfer their tensile load to the strength member. The apex of this transfer is referred to as the thermal knee-point. Because the CTE of the strength member is lower than the CTE of the conductive strands, conductor sag above the thermal knee-point decreases. The ACCC conductor's lower CTE and lower thermal knee-point may reduce thermal sag, i.e., sag due to thermal expansion of the cable.
A strength member having a very high tensile strength, such as in the ACCC® configuration, enables the use of conductive strands of fully annealed aluminum. Fully annealed aluminum has a higher conductivity than non-annealed aluminum, and therefore can increase ampacity and reduce line losses. However, fully annealed aluminum lacks in some physical properties. For example, the use of fully annealed aluminum may result in increased line sag under static loads (e.g., ice loading) since only a relatively small tensile strain will plastically deform the aluminum, reducing tension in the conductor. In one configuration, the overhead electrical cable includes an inner conductive layer of an annealed aluminum and an outer conductive layer of a harder aluminum, such as an Al—Zr alloy. For example, referring to
The present disclosure also relates to methods for the fabrication of an overhead electrical cable, e.g., for the fabrication of an overhead electrical cable as described in any of the embodiments above. In one example, a method for the manufacture of an overhead electrical cable is disclosed, comprising the steps of first wrapping a plurality of conductive strands of a first aluminum material onto a strength member to form a first conductive layer, and second wrapping a plurality of conductive strands of a second aluminum material onto the first conductive layer to form a second conductive layer. The second aluminum material has at least one material property having a property value that is different than the property value of the same material property of the first aluminum material.
The present disclosure also relates to methods for the installation of an electrical transmission line. In one embodiment, the method includes the steps of stringing an overhead electrical cable between at least two support structures, applying tension to the overhead electrical cable, and while the overhead electrical cable is under the applied tension, clipping first and second ends of the overhead electrical cable such that the overhead electrical cable is at least partially supported by the two support structures. The overhead electrical cable includes a strength member, a first conductive layer surrounding the strength member, the first conductive layer comprising conductive strands of a first aluminum material, and a second conductive layer surrounding the first conductive layer, the second conductive layer comprising conductive strands of a second aluminum material that is different than the first aluminum material. The second aluminum material has at least one material property that is different that the same material property of the first aluminum material.
The present disclosure also relates to an overhead electrical transmission line comprising an overhead electrical cable. The overhead electrical cable is strung under high tension onto at least two support towers. The overhead electrical cable includes a strength member, a first conductive layer surrounding the strength member, the first conductive layer comprising conductive strands of a first aluminum material, and a second conductive layer surrounding the first conductive layer, the second conductive layer comprising conductive strands of a second aluminum material that is different than the first aluminum material. The second aluminum material has at least one material property that is different that the same material property of the first aluminum material.
While various embodiments of an overhead electrical cable, a method for making an overhead electrical cable, a method for the installation of an electrical transmission line and an overhead electrical transmission line have been described in detail, it is apparent that modifications and adaptations of those embodiments will occur to those skilled in the art. However, it is to be expressly understood that such modifications and adaptations are within the spirit and scope of the present disclosure.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US2019/020855 | 3/5/2019 | WO | 00 |
| Number | Date | Country | |
|---|---|---|---|
| 62638436 | Mar 2018 | US |
