Self-Supporting Stripline RF Transmission Cable

Abstract

A stripline RF transmission cable has a flat inner conductor surrounded by a dielectric layer that is surrounded by an outer conductor. A jacket with an attachment feature surrounds the outer conductor. The attachment feature may be a fin aligned parallel or normal to the inner conductor. The attachment feature may be continuous or periodic along a longitudinal extent of the cable. The attachment feature may include male and female portions dimensioned to couple with one another, enabling adjacent cables to be attached to one another.

Description

BACKGROUND

1. Field of the Invention

RF Transmission systems are used to transmit RF signals from point to point, for example, from an antenna to a transceiver or the like. Common forms of RF transmission systems include coaxial cables and striplines.

2. Description of Related Art

Prior coaxial cables typically have a coaxial configuration with a circular outer conductor evenly spaced away from a circular inner conductor by a dielectric support such as polyethylene foam or the like. The electrical properties of the dielectric support and spacing between the inner and outer conductor define a characteristic impedance of the coaxial cable. Circumferential uniformity of the spacing between the inner and outer conductor prevents introduction of impedance discontinuities into the coaxial cable that would otherwise degrade electrical performance.

An industry standard characteristic impedance is 50 ohms. Coaxial cables configured for 50 ohm characteristic impedance generally have an increased inner conductor diameter compared to higher characteristic impedance coaxial cables such that the metal inner conductor material cost is a significant portion of the entire cost of the resulting coaxial cable. To minimize material costs, the inner and outer conductors may be configured as thin metal layers for which structural support is then provided by less expensive materials. For example, commonly owned U.S. Pat. No. 6,800,809, titled “Coaxial Cable and Method of Making Same”, by Moe et al, issued Oct. 5, 2004, hereby incorporated by reference in the entirety, discloses a coaxial cable structure wherein the inner conductor is formed by applying a metallic strip around a cylindrical filler and support structure comprising a cylindrical plastic rod support structure with a foamed dielectric layer therearound. The resulting inner conductor structure has significant materials cost and weight savings compared to coaxial cables utilizing solid metal inner conductors. However, these structures can incur additional manufacturing costs, due to the multiple additional manufacturing steps required to sequentially apply each layer of the structure.

One limitation with respect to metal conductors and/or structural supports replacing solid metal conductors is bend radius. Generally, a larger diameter coaxial cable will have a reduced bend radius before the coaxial cable is distorted and/or buckled by bending. In particular, structures may buckle and/or be displaced out of coaxial alignment by cable bending in excess of the allowed bend radius, resulting in cable collapse and/or degraded electrical performance.

A further cable consideration is supporting and securing the cable along its length, for example as the cable is routed and secured along a radio tower. Prior cables configured for hanging in the air, such as telephone and/or CATV cables between utility poles and a residence, have been configured with encapsulated messenger wires to increase the strength of the cable and/or provide a sturdy attachment point separate from the signal conductor portion of the cable. Thereby, the cable strength is improved and the cable may be secured with reduced risk of damage to the signal conductor portion of the cable. However, messenger wires may increase the materials cost and overall weight of the cable.

A stripline is a flat conductor sandwiched between parallel interconnected ground planes. Striplines have the advantage of being non-dispersive and may be utilized for transmitting high frequency RF signals. Striplines may be cost effectively generated using printed circuit board technology or the like. However, striplines may be expensive to manufacture in longer lengths/larger dimensions. Further, where a solid stacked printed circuit board type stripline structure is not utilized, the conductor sandwich is generally not self supporting and/or aligning, compared to a coaxial cable, and as such may require significant additional support/reinforcing structure.

Competition within the RF cable industry has focused attention upon reducing materials and manufacturing costs, electrical characteristic uniformity, defect reduction, installation simplification and overall improved manufacturing quality control.

Therefore, it is an object of the invention to provide a coaxial cable and method of manufacture that overcomes deficiencies in such prior art.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with a general description of the invention given above, and the detailed description of the embodiments given below, serve to explain the principles of the invention. Like reference numbers in the drawing figures refer to the same feature or element and may not be described in detail for every drawing figure in which they appear.

FIG. 1 is a schematic isometric view of an exemplary cable, with layers of the conductors, dielectric spacer and outer jacket stripped back.

FIG. 2 is a schematic end view of the cable of FIG. 1.

FIG. 3 is a schematic isometric view demonstrating a bend radius of the cable of FIG. 1.

FIG. 4 is a schematic isometric view of an alternative cable, with layers of the conductors, dielectric spacer and outer jacket stripped back.

FIG. 5 is a schematic end view of an alternative embodiment cable utilizing varied dielectric layer dielectric constant distribution.

FIG. 6 is a schematic end view of another alternative embodiment cable utilizing varied dielectric layer dielectric constant distribution.

FIG. 7 is a schematic end view of an alternative embodiment cable utilizing cavities for varied dielectric layer dielectric constant distribution.

FIG. 8 is a schematic end view of an alternative embodiment cable utilizing sequential vertical layers of varied dielectric constant in the dielectric layer.

FIG. 9 is a schematic end view of an alternative embodiment cable utilizing dielectric rods for varied dielectric layer dielectric constant distribution.

FIG. 10 is a schematic end view of an alternative embodiment cable utilizing dielectric rods for varied dielectric layer dielectric constant distribution.

FIG. 11 is a schematic end view of an alternative embodiment cable utilizing varied outer conductor spacing to modify operating current distribution within the cable.

FIG. 12 is a schematic end view of another alternative embodiment cable utilizing drain wires for varied outer conductor spacing to modify operating current distribution within the cable.

FIG. 13 is a schematic isometric view of an oval cross-section cable with an attachment feature provided as a rib extending from the jacket, parallel to the inner conductor.

FIG. 14 is a schematic isometric view of an oval cross-section cable with an attachment feature provided as a rib extending from the jacket, parallel to the inner conductor, including apertures.

FIG. 15 is a schematic end view of an oval cross-section cable with a fin extending from the jacket coplanar with a bottom section of the outer conductor.

FIG. 16 is a schematic end view of an hour glass-shaped cross-section cable with a fin extending from a bottom of the cable parallel with the inner conductor.

FIG. 17 is a schematic end view of an oval cross-section cable with a fin extending from the jacket at either side of the cable, coplanar with the inner conductor.

FIG. 18 is a schematic end view of an hour glass-shaped cross-section cable with a fin with a fin extending from the jacket at either side of the cable, coplanar with the inner conductor.

FIG. 19 is a schematic end view of an oval cross-section cable with a fin extending from the jacket, normal to the inner conductor.

FIG. 20 is a schematic end view of an hour glass-shaped cross-section cable with a fin extending from the jacket, normal to the inner conductor.

FIG. 21 is a schematic end view of an oval cross-section cable with a fin extending from the jacket, normal to the inner conductor. The fin provided with an additional layer.

FIG. 22 is a schematic end view of an hour glass-shaped cross-section cable with a fin extending from the jacket, normal to the inner conductor. The fin provided with an additional layer

FIG. 23 is a schematic end view of an oval cross-section cable with a fin extending from the jacket, normal to the inner conductor. The fin provided with an additional layer overlapping the fin.

FIG. 24 is a schematic end view of an hour glass-shaped cross-section cable with a fin extending from the jacket, normal to the inner conductor. The fin provided with an additional layer overlapping the fin.

FIG. 25 is a schematic end view of an oval cross-section cable with a fin extending from the jacket, normal to the inner conductor. The fin encapsulating an additional layer.

FIG. 26 is a schematic end view of an hour glass-shaped cross-section cable with a fin extending from the jacket, normal to the inner conductor. The fin encapsulating an additional layer.

FIG. 27 is a schematic isometric view of a cable with a fin extending from the jacket, normal to the inner conductor, with slots formed in the fin.

FIG. 28 is a schematic end view of an hour glass-shaped section cable with a fin loop extending from the jacket.

FIG. 29 is a schematic end view of an hourglass cross-section cable with a fin loop extending from the jacket.

FIG. 30 is a schematic end view of an oval cross-section cable with a fin loop extending from the jacket, an additional layer provided in the fin loop.

FIG. 31 is a schematic end view of an hour glass-shaped cross-section cable with a fin loop extending from the jacket, an additional layer provided in the fin loop.

FIG. 32 is a schematic view of FIG. 30, demonstrated with a fastener piercing the fin loop, a tear-out resistance of the fin loop improved by the presence of the additional layer.

FIG. 33 is a schematic end view of a pair of oval cross-section cables coupled to one another, top-to-bottom, by respective attachment features.

FIG. 34 is a schematic end view of a pair of hour glass-shaped cross-section cables coupled to one another, top-to-bottom, by respective attachment features.

FIG. 35 is a schematic end view of a pair of oval cross-section cables coupled to one another, side-to-side, by respective attachment features.

FIG. 36 is a schematic end view of a pair of oval cross-section cables coupled to one another, side-to-side, by respective attachment features.

FIG. 37 is a schematic isometric view of an exemplary jacket provided with side extending male and female attachment features according to the cables of FIG. 35.

DETAILED DESCRIPTION

The inventors have recognized that the prior accepted coaxial cable design paradigm of concentric circular cross-section design geometries results in unnecessarily large coaxial cables with reduced bend radius, excess metal material costs and/or significant additional manufacturing process requirements.

The inventors have further recognized that the application of a flat inner conductor, compared to a conventional circular inner conductor configuration, enables modification of the coaxial cable to improve a thermal dissipation characteristic of the cable with a reduced trade-off in electrical and/or mechanical performance.

An exemplary stripline RF transmission cable 1 is demonstrated in FIGS. 1-3. As best shown in FIG. 1, the inner conductor 5 of the cable 1, extending between a pair of inner conductor edges 3, is a flat metallic strip. A top section 10 and a bottom section 15 of the outer conductor 25 are aligned parallel to the inner conductor 5 with widths equal to the inner conductor width. The top and bottom sections 10, 15 transition at each side into convex edge sections 20. Thus, the circumference of the inner conductor 5 is entirely sealed within an outer conductor 25 comprising the top section 10, bottom section 15 and edge sections 20.

The dimensions/curvature of the edge sections 20 may be selected, for example, for ease of manufacture. Preferably, the edge sections 20 and any transition thereto from the top and bottom sections 10, 15 is generally smooth, without sharp angles or edges. As best shown in FIG. 2, the edge sections 20 may be provided as circular arcs with an arc radius R, with respect to each side of the inner conductor 5, equivalent to the spacing between each of the top and bottom sections 10, 15 and the inner conductor 5, resulting in a generally equal spacing between any point on the circumference of the inner conductor 5 and the nearest point of the outer conductor 25, minimizing outer conductor material requirements.

The desired spacing between the inner conductor 5 and the outer conductor 25 may be obtained with high levels of precision via application of a uniformly dimensioned spacer structure with dielectric properties, referred to as the dielectric layer 30, and then surrounding the dielectric layer 30 with the outer conductor 25. Thereby, the cable 1 may be provided in essentially unlimited continuous lengths with a uniform cross-section at any point along the cable 1.

The inner conductor 5 metallic strip may be formed as solid rolled metal material such as copper, aluminum, steel or the like. For additional strength and/or cost efficiency, the inner conductor 5 may be provided as copper-coated aluminum or copper-coated steel.

Alternatively, the inner conductor 5 may be provided as a substrate 40 such as a polymer and/or fiber strip that is metal coated or metalized, for example as shown in FIG. 4. One skilled in the art will appreciate that such alternative inner conductor configurations may enable further metal material reductions and/or an enhanced strength characteristic enabling a corresponding reduction of the outer conductor strength characteristics.

The dielectric layer 30 may be applied as a continuous wall of plastic dielectric material around the outer surface of the inner conductor 5. The dielectric layer 30 may be a low loss dielectric material comprising a suitable plastic such as polyethylene, polypropylene, and/or polystyrene. The dielectric material may be of an expanded cellular foam composition, and in particular, a closed cell foam composition for resistance to moisture transmission. Any cells of the cellular foam composition may be uniform in size. One suitable foam dielectric material is an expanded high density polyethylene polymer as disclosed in commonly owned U.S. Pat. No. 4,104,481, titled “Coaxial Cable with Improved Properties and Process of Making Same” by Wilkenloh et al, issued Aug. 1, 1978, hereby incorporated by reference in the entirety. Additionally, expanded blends of high and low density polyethylene may be applied as the foam dielectric.

Although the dielectric layer 30 generally consists of a uniform layer of foam material, as described in greater detail herein below, the dielectric layer 30 can have a gradient or graduated density varied across the dielectric layer cross-section such that the density of the dielectric increases and/or decreases radially from the inner conductor 5 to the outer diameter of the dielectric layer 30, either in a continuous or a step-wise fashion. Alternatively, the dielectric layer 30 may be applied in a sandwich configuration as two or more separate layers together forming the entirety of the dielectric layer 30 surrounding the inner conductor 5.

The dielectric layer 30 may be bonded to the inner conductor 5 by a thin layer of adhesive. Additionally, a thin solid polymer layer and another thin adhesive layer may be present, protecting the outer surface of the inner conductor 5 (for example, as it is collected on reels during cable manufacture processing).

The outer conductor 25 is electrically continuous, entirely surrounding the circumference of the dielectric layer 30 to eliminate radiation and/or entry of interfering electrical signals. The outer conductor 25 may be a solid material such as aluminum or copper material sealed around the dielectric layer as a contiguous portion by seam welding or the like. Alternatively, helically wrapped and/or overlapping folded configurations utilizing, for example, metal foil and/or braided type outer conductor 25 may also be utilized.

If desired, a protective jacket 35 of polymer materials such as polyethylene, polyvinyl chloride, polyurethane and/or rubbers may be applied to the outer diameter of the outer conductor. The jacket 35 may comprise laminated multiple jacket layers to improve toughness, strippability, burn resistance, the reduction of smoke generation, ultraviolet and weatherability resistance, protection against rodent gnaw-through, strength resistance, chemical resistance and/or cut-through resistance. For ease of installation, an attachment feature 75 may be provided integrated with the jacket 35.

The flattened characteristic of the cable 1 has inherent bend radius advantages. As best shown in FIG. 3, the bend radius of the cable perpendicular to the horizontal plane of the inner conductor 5 is reduced compared to a conventional coaxial cable of equivalent materials dimensioned for the same characteristic impedance. Since the cable thickness between the top section 10 and the bottom section 15 is thinner than the diameter of a comparable coaxial cable, distortion or buckling of the outer conductor 25 is less likely at a given bend radius. A tighter bend radius also improves warehousing and transport aspects of the cable 1, as the cable 1 may be packaged more efficiently, for example provided coiled upon smaller diameter spool cores which require less overall space.

Electrical modeling of stripline-type RF cable structures with top and bottom sections with a width similar to that of the inner conductor (as shown in FIGS. 1-4) demonstrates that the electric field generated by transmission of an RF signal along the cable 1 and the corresponding current density with respect to a cross-section of the cable 1 is greater along the inner conductor edges 3 at either side of the inner conductor 5 than at a mid-section 7 of the inner conductor. Uneven current density generates higher resistivity and increased signal loss. Therefore, the cable configuration may have an increased attenuation characteristic, compared to conventional circular/coaxial type RF cable structures where the inner conductor circumferences are equal.

To obtain the materials and structural benefits of the stripline RF transmission cable 1 as described herein, the electric field strength and corresponding current density may be balanced by increasing the current density proximate the mid-section 7 of the inner conductor 5. The current density may be balanced, for example, by modifying the dielectric constant of the dielectric layer 30 to provide an average dielectric constant that is lower between the inner conductor edges 3 and the respective adjacent edge sections 20 than between a mid-section 7 of the inner conductor 5 and the top and the bottom sections 10,15. Thereby, the resulting current density may be adjusted to be more evenly distributed across the cable cross-section to reduce attenuation.

The dielectric layer 30 may be formed with layers of, for example, expanded open and/or closed-cell foam dielectric material, where the different layers of the dielectric material have a varied dielectric constant. The differential between dielectric constants and the amount of space within the dielectric layer 30 allocated to each type of material may be utilized to obtain the desired average dielectric constant of the dielectric layer 30 in each region of the cross-section of the cable 1.

As shown for example in FIG. 5, a dome-shaped increased dielectric constant portion 45 of the dielectric layer 30 may be applied proximate the top section 10 and the bottom section 15 extending inward toward the mid-section 7 of the inner conductor 5. Alternatively, the dome-shaped increased dielectric constant portion 45 of the dielectric layer 30 proximate the inner conductor 5 may be positioned extending outward from the mid-section 7 of the inner conductor 5 towards the top and bottom sections 10,15, as shown for example in FIG. 6.

Air may be utilized as a low cost dielectric material. As shown for example in FIG. 7, one or more areas of the dielectric layer 30 proximate the edge sections 20 may be applied as a cavity 50 extending along a longitudinal axis of the cable 1. Such cavities 50 may be modeled as air (pressurized or unpressurized) with a dielectric constant of approximately 1 and the remainder of the adjacent dielectric material of the dielectric layer 30 again selected and spaced accordingly to provide the desired dielectric constant distribution across the cross-section of the dielectric layer 30 when averaged with the cavity portions allocated to air dielectric.

As shown for example in FIG. 8, multiple layers of dielectric material may be applied, for example, as a plurality of vertical layers aligned normal to the horizontal plane of the inner conductor 5, a dielectric constant of each of the vertical layers provided so that the resulting overall dielectric layer dielectric constant increases towards the mid-section 7 of the inner conductor 5 to provide the desired aggregate dielectric constant distribution across the cross-section of the dielectric layer 30. Alternatively, for example as shown in FIG. 9, the dielectric material may be applied as simultaneous high and low (relative to one another) dielectric constant dielectric material streams through multiple nozzles with the proportions controlled with respect to cross-section position by the nozzle distribution or the like so that a position varied mixed stream of dielectric material is applied to obtain a desired (e.g., generally smooth) gradient of the dielectric constant across the cable cross-section, so that the resulting overall dielectric constant of the dielectric layer 30 increases in a generally smooth gradient from the edge sections 20 towards the mid-section 7 of the inner conductor 5.

The materials selected for the dielectric layer 30, in addition to providing varying dielectric constants for tuning the dielectric layer cross-section dielectric profile for attenuation reduction, may also be selected to enhance structural characteristics of the resulting cable 1. For example, as shown in FIG. 10, the dielectric layer 30 may be provided with first and second dielectric rods 55 located proximate a top side 60 and a bottom side 65 of the mid-section 7 of the inner conductor 5. The dielectric rods 55, in addition to having a dielectric constant greater than the surrounding dielectric material, may be for example fiberglass or other high strength dielectric materials that improve the strength characteristics of the resulting cable 1. Thereby, the thickness of the inner conductor 5 and/or outer conductor 25 may be reduced to obtain overall materials cost reductions without compromising strength characteristics of the resulting cable 1.

Alternatively and/or additionally, the electric field strength and corresponding current density may also be balanced by adjusting the distance between the outer conductor 25 and the mid-section 7 of the inner conductor 5. For example, as shown in FIG. 11, the outer conductor 25 may be provided spaced farther away from each inner conductor edge 3 than from the mid-section 7 of the inner conductor 5, creating a generally hour glass-shaped cross-section. The distance between the outer conductor 25 and the mid-section 7 of the inner conductor 5 may be less than, for example, 0.7 of a distance between the inner conductor edges 3 and the outer conductor 25 (at the edge sections 20).

The dimensions may also be modified, for example as shown in FIG. 12, by applying a drainwire 70 coupled to the inner diameter of the outer conductor 25, one proximate either side of the mid-section 7 of the inner conductor 5. Because each of the drain wires 70 is electrically coupled to the adjacent inner diameter of the outer conductor 25, each drain wire 70 becomes an inwardly projecting extension of the inner diameter of the outer conductor 25, again forming the generally hour glass cross-section to average the resulting current density for attenuation reduction. As described with respect to the dielectric rods 55 of FIG. 10, the drain wires 70 may similarly increase structural characteristics of the resulting cable, enabling cost saving reduction of the metal thicknesses applied to the inner conductor 5 and/or outer conductor 25.

The attachment feature 75 may be formed as an extension of the jacket 35, for example as shown in FIGS. 13-18, as a longitudinal fin 80 aligned parallel with a horizontal plane of the inner conductor 5. As shown in FIG. 13, the fin 80 may be provided ready for perforation by a fastener anywhere along the longitudinal extent, for example as required by the position of support structure relative to the cable in a specific installation, or configured with a plurality of pre-applied apertures 85 spaced periodically along the fin, for example as shown in FIG. 14.

The fin 80 may be provided extending from the cable 1 coplanar with the top or bottom sections 10, 15, as shown for example in FIGS. 13-16, for flush mounting of the cable 1 to a desired support structure. The fin 80 may also be positioned coplanar with the inner conductor 5 with a fin 80 extending from one or both sides of the cable 1, for example as shown in FIGS. 17 and 18, for ease of mounting to a range of varied surfaces.

Alternatively, the fin 80 may be arranged, for example as shown in FIGS. 19-27, normal to the horizontal plane of the inner conductor 5. To reduce the impact of the fin 80 on the bending characteristic of the cable 1, the fin 80 may be provided with a plurality of longitudinally spaced slots 81, as shown for example in FIG. 27.

The strength characteristics of the fin 80 may be configured, for example, by selecting the jacket 35 material and/or the dimensions of the fin 80, including a thickness of the fin 80. Further, the fin 80 may be reinforced by application of a reinforcing layer 90 to the fin 80 as a single layer (FIGS. 21-22) or an overlapping layer (FIG. 23-24). The reinforcing layer 90 may be a further portion of the jacket 35 material or a higher strength material selected for longitudinal and/or tear strength characteristics. The reinforcing layer 90 may be applied, for example, as filaments and/or woven meshes of metal, glass reinforced plastic, fiberglass, aramid or the like. The reinforcing layer 90 may be entirely enclosed within the fin 80, for example as shown in FIGS. 25-26.

Alternatively, for example as shown in FIGS. 28-32, the attachment feature 75 may be provided in a double wall configuration as a fin loop 82 extending from both the top and bottom sections 10, 15 of the cable 1 to distribute the attachment feature 75 connection to more than a single point along the circumference of the jacket 35. The loop of the attachment feature 75 formed between the top and bottom sections 10, 15 may include a reinforcing layer 90 disposed in the fin loop 82, for example, positioned equidistant from the cable 1. Thereby, a fastener 83 may be inserted through each of the double walls and tear out inhibited by the reinforcing layer 90, as demonstrated in FIG. 32.

The attachment feature 75 may be provided, for example as shown in FIGS. 33-36, as complementary male portions 92 and female portions 94 at opposite sides of the cable 1, for example the top and bottom or left and right sides with respect to a horizontal plane of the inner conductor 5, configured to mate with corresponding features of adjacent cables 1 and/or mounting points. Thereby, the several cables 1 may be easily aligned supporting one another in compact space saving parallel runs. For example as shown in FIGS. 33 and 34, the male portion 92 may be provided as a projection rib 96 that seats within a female portion 94 provided as a groove 98. Where the male and female portions 92, 94 are continuous along the longitudinal extent, manufacture via extrusion and or cutting elements in the process line is simplified and the interconnection therebetween may be made without requiring longitudinal alignment between the male and female portions 92, 94.

Alternatively, the male and female portions 92, 94 may be provided periodically along the longitudinal extent, for example as shown in FIGS. 35-37, as male protrusions 100 that snap-fit into female seats 102, to provide a longitudinal interlock characteristic to the attachment feature 75.

In further embodiments, the attachment feature 75 may be provided as a longitudinally periodic attachment to the cable 1 that is then encapsulated by the application of the jacket 35 around both the outer conductor and at least a base portion of the attachment feature 75. For example, the attachment feature 75 may be provided as a clip with a male protrusion configured for direct mating with a standard attachment point, such as a three quarter inch hole often provided on tower structures for “snap-in” type cable hangers. Because of the non-circular cross-section of the cable 1, the clip portion of the attachment feature may anchor upon the cable without requiring additional anti-rotation structure or reinforcement.

One skilled in the art will appreciate that the cable 1 has numerous advantages over a conventional circular cross-section coaxial cable. Because the desired inner conductor surface area is obtained without applying a solid or hollow tubular inner conductor, a metal material reduction of one half or more may be obtained. Alternatively, because complex inner conductor structures which attempt to substitute the solid cylindrical inner conductor with a metal coated inner conductor structure are eliminated, required manufacturing process steps may be reduced. The attachment features 75 provided integral with the jacket 35 may simplify installation of the cables 1 and/or enable easy alignment of multiple adjacent cables 1 in close quarters to conserve space. Because the attachment features 75 are integrated with the jacket 35, separate attachment hardware requirements, such as cable hangers, and their respective installation steps, may be eliminated.

Table of Parts
1   cable
3   inner conductor edge
5   inner conductor
7   mid-section
10  top section
15  bottom section
20  edge section
25  outer conductor
30  dielectric layer
32  thermally conductive material
35  jacket
40  substrate
45  increased dielectric constant portion
50  cavity
55  dielectric rod
60  top side
65  bottom side
70  drain wire
75  attachment feature
80  fin
81  slot
82  fin loop
83  fastener
85  aperture
90  additional layer
92  male portion
94  female portion
96  projection rib
98  groove
100 male protrusion
102 female seat

Where in the foregoing description reference has been made to ratios, integers or components having known equivalents then such equivalents are herein incorporated as if individually set forth.

While the present invention has been illustrated by the description of the embodiments thereof, and while the embodiments have been described in considerable detail, it is not the intention of the applicant to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will readily appear to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details, representative apparatus, methods, and illustrative examples shown and described. Accordingly, departures may be made from such details without departure from the spirit or scope of applicant's general inventive concept. Further, it is to be appreciated that improvements and/or modifications may be made thereto without departing from the scope or spirit of the present invention as defined by the following claims.

Claims

1. A self supporting stripline RF transmission cable, comprising: a flat inner conductor extending between a pair of inner conductor edges;the inner conductor surrounded by a dielectric layer;an outer conductor surrounding the dielectric layer; anda jacket surrounding the outer conductor;the outer conductor provided with a flat top section and a flat bottom section; the top section and the bottom section transitioning to a pair of edge sections which interconnect the top section with the bottom section;the jacket provided with an attachment feature.

2. The cable of claim 1, wherein the attachment feature is a longitudinal fin extending from the jacket one of parallel and normal to a horizontal plane of the inner conductor.

3. The cable of claim 2, further including periodic slots in the fin; the slots aligned normal to a longitudinal axis of the cable.

4. The cable of claim 1, wherein the attachment feature is a fin loop between a first location proximate the top section and a second location proximate the bottom section.

5. The cable of claim 1, wherein the attachment feature further includes a reinforcing layer.

6. The cable of claim 5, wherein the reinforcing layer is encapsulated within the attachment feature.

7. The cable of claim 1, wherein the attachment feature is a male portion and a female portion provided on opposite sides of the cable; the male portion and the female portion dimensioned to couple with one another.

8. The cable of claim 1, wherein the attachment feature is continuous along a longitudinal extent of the cable.

9. The cable of claim 1, wherein the attachment feature is periodic along a longitudinal extent of the cable.

10. The cable of claim 1, wherein the attachment feature is at least one clip with a protrusion; the clip coupled to the outer conductor and at least the clip encapsulated by the jacket.

11. A self supporting stripline RF transmission cable, comprising: a flat inner conductor extending between a pair of inner conductor edges;the inner conductor surrounded by a dielectric layer; andan outer conductor surrounding the dielectric layer; anda jacket surrounding the outer conductor;the outer conductor provided spaced farther away from each inner conductor edge than from a midsection of the inner conductor;the jacket provided with an attachment feature.

12. The cable of claim 11, wherein the attachment feature is a longitudinal fin extending from the jacket one of parallel and normal to a horizontal plane of the inner conductor.

13. The cable of claim 12, further including periodic slots in the fin; the slots aligned normal to a longitudinal axis of the cable.

14. The cable of claim 11, wherein the attachment feature is a fin loop between opposite sides of the cable.

15. The cable of claim 11, wherein the attachment feature further includes a reinforcing layer.

16. The cable of claim 15, wherein the reinforcing layer is encapsulated within the attachment feature.

17. The cable of claim 11, wherein the attachment feature is a male portion and a female portion provided on opposite sides of the cable; the male portion and the female portion dimensioned to couple with one another.

18. The cable of claim 11, wherein the attachment feature is continuous along a longitudinal extent of the cable.

19. The cable of claim 11, wherein the attachment feature is periodic along a longitudinal extent of the cable.

20. The cable of claim 11, wherein the attachment feature is at least one clip with a protrusion; the clip coupled to the outer conductor and at least the clip encapsulated by the jacket.