Patent Description:
Optic fiber cables are broadly used to provide fast, high bandwidth data services for telecommunication networks. The optic fibers waveguides or cores are extremely delicate, requiring mechanical protections throughout the length of the cable. Optic fiber ribbon cable is a type of optic fiber cable incorporates a plurality of ribbons for communicating the optical information. Ribbons are formed by disposing a plurality of optic fiber cores in the ribbon matrix. The cores of the ribbons are spaced evenly in a flat array of a common plane directed along the longitude axis of the cable. The ribbon matrix provides structural support and geometrical guide for precisely placing the optic fiber cores evenly across the matrix according to industrial standards. The number of cores within a ribbon may vary, which is usually a number of a power of <NUM>, such as <NUM>, <NUM>, etc. An optic fiber ribbon of the prior art is known from <CIT>.

Conventionally, a plurality of optic fiber ribbons in the optic fiber ribbon cable are stacked together within loose tubes contained in the cable thereby increasing the total fiber counts the cable may carry. In conventional art, the outer dimensions of ribbon matrices are flat with a flat rectangular shape cross-sectionally. The ribbons are stacked on top of the flat side of each ribbon's matrix. The ribbons stacked together are usually of the same fiber count each, therefore the stacked ribbons usually form a rectangular or square shape cross-sectionally. This design is partially due to the fact that the ribbon matrix has a flat rectangular outer dimension thus the ribbons tend to remain flat on the ribbon's common plane. The ribbons are resistant to bending sideways. When bent, one side of the ribbon matrix will be under tension forces and the other side will be under compression forces. If the bending force is too strong or prolonged, the ribbon matrix will be strained, stress or damaged.

However, the tubes where the stacked ribbons are contained generally are round, with a circular cross-sectional shape. To accommodate the rectangular or squared stacks of the ribbons, the tubes need to be sufficiently big, with the diameters not smaller than the longer side of the rectangular or the side of the square. Cross-sectionally, the portions of the circle circumscribed by the rectangular or square become wasted space, in the sense that they increase the overall cable dimensions and increase for the same fibre count. For multi-tube ribbon cables, where a plurality of tubes is contained in a cable, the problem is even more acerbated, as there are more spaces between the tubes.

Therefore, there is a need to provide an optic fiber ribbon cable that increases the total fiber count by utilizing the wasted spaces due to the circumscription of the stack to the tube.

The invention is a bendable optic fiber ribbon as defined in claim <NUM>.

A primary object of the present disclosure is to provide a fiber optic cable with a plurality of bendable optic fiber ribbons.

The object of this invention is to provide a bendable ribbon conductive to receiving bending forces which can be used in connection with the fiber optic cable with bendable ribbon and increase the fiber count of the cable.

Having thus described the disclosure in general terms, reference will now be made to the accompanying figures, wherein:.

It should be noted that the accompanying figures are intended to present illustrations of exemplary embodiments of the present disclosure. These figures are not intended to limit the scope of the present disclosure. It should also be noted that accompanying figures are not necessarily drawn to scale.

For a more complete understanding of the present invention parts, reference is now made to the following descriptions:.

The following detailed description is of the best currently contemplated modes of carrying out exemplary embodiments of the invention. The description is not to be taken in a limiting sense, but is made merely for the purpose of illustrating the general principles of the invention.

Reference will now be made in detail to selected embodiments of the present disclosure in conjunction with accompanying figures. The embodiments described herein are not intended to limit the scope of the disclosure, and the present disclosure should not be construed as limited to the embodiments described. This disclosure may be embodied in different forms without departing from the scope of the appended claims. It should be understood that the accompanying figures are intended and provided to illustrate embodiments of the disclosure described below and are not necessarily drawn to scale. In the drawings, like numbers refer to like elements throughout, and thicknesses and dimensions of some components may be exaggerated for providing better clarity and ease of understanding.

It should be noted that the terms "first", "second", and the like, herein do not denote any order, ranking, quantity, or importance, but rather are used to distinguish one element from another. Further, the terms "a" and "an" herein do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced item.

<FIG> is a perspective view of the bendable ribbon according to a preferred embodiment of the present invention. Referring to <FIG>, bendable ribbon <NUM> comprises a ribbon matrix <NUM>, wherein a plurality of optic fibers <NUM> is disposed in parallel between a first side and a second side along the longitude axis of the bendable ribbon <NUM>. The ribbon matrix <NUM> provides structural support and geometrical guide for precisely placing the plurality of optic fibers evenly across the matrix according to industrial standards. The number of the optic fibers within the ribbon matrix <NUM> may vary, which is usually a number of power of <NUM>, such as <NUM>, <NUM>, etc..

The ribbon matrix <NUM> comprises the first side and the second side. The first side is a top curved side <NUM> and the second side is a bottom flat side <NUM>. The top curved side <NUM> has a cross-sectional shape of a periodical waveform <NUM>. The specific shape of the waveforms <NUM> can be configured to a variety of waveforms as will be further described in the present invention below. According to the present invention, each of the waveforms <NUM> is formed over a single fiber with the optic fiber located in the center of the waveform. As such, each optic fiber of the plurality of optic fibers <NUM> is still sufficiently protected by the ribbon matrix as in prior art. The pitch distance a between the center of neighboring optic fibers can be configured to any pitch dimension of conventional optic fiber ribbon. As such the bendable ribbons of present invention can be configured to be compatible with any current or future optic fiber ribbon connectors.

<FIG> is a close-up cross-sectional view of two neighboring optic fibers of the bendable ribbon <NUM> according to a preferred embodiment of the present invention. Referring to <FIG>, each of the neighboring fibers comprises several of layers forming concentric circles, including a fiber core <NUM>, a cladding <NUM> wrapping around the fiber core <NUM>, and an acrylic coating <NUM>, e.g. soft coating and hard coating, wrapping around the cladding <NUM>. There may be other layers and/or components between and/or around the fiber core <NUM>, cladding <NUM> and coating <NUM> not illustrated herein. It is to be understood by people of ordinary skill of the art that ribbons having more or less layers/components than illustrated herein are within scope of the present invention. According to a preferred embodiment of the present invention, the fiber core <NUM> has a diameter of substantially <NUM>, the cladding <NUM> has an outer surface to center distance of substantially <NUM> micrometer (µm), and the coating <NUM> has an outer surface to center distance of substantially <NUM>-<NUM> micrometer (µm). As illustrated in connection with <FIG>, a preferred pitch distance (a) between respective centers of two adjacent optic fibers of the plurality of optic fibers (<NUM>) is about <NUM>.

Each optic fiber of the plurality of optic fibers <NUM> has a diameter of about <NUM> or <NUM> microns. In an embodiment of the present disclosure, each optic fiber of the plurality of optic fibers may have any suitable diameter.

In addition, the distance between the center of the optic fiber <NUM> and peak of the top curved side <NUM> of the ribbon matrix <NUM> is about <NUM> millimeter. Further, the distance between the center of the optic fiber <NUM> and the flat side <NUM> of the ribbon matrix <NUM> is about <NUM> millimeter. Furthermore, the bending gaps between neighboring curved surfaces has an angle of about <NUM> degree.

Further referring to <FIG>, points C are the peaks of the waveforms <NUM> are, whereas point B is the valley of between the neighboring waveforms <NUM>. Points A are located on the opposite sides of the surface curves between the peaks C and valley B of each waveform <NUM>. As will be further illustrated below, when the ribbon is bent, the points A on the neighboring waveforms will be closing in to each other across the bending gap <NUM> in between them, which results in the reduction of structural forces that work to break the ribbon with matrix that do not have the bending gap <NUM>. According to the claimed invention, the ribbon <NUM> further includes a cut on the ribbon matrix from point B to B'. When the ribbon is not bent or bent from a direction pointing from the bottom side <NUM> to the curved side <NUM>, the cut between B and B' remains closed. However, when the ribbon is bent from the curved side <NUM> to the bottom side <NUM>, the cut from B to B' will open up, further extending the bending gap <NUM> to the point B' as illustrated in <FIG> below.

Conventional ribbons may have markings to be labeled or printed on the outside of the ribbon matrix. With a curved side <NUM>, printing or labeling on that side may not be feasible or have a corrugated look hard to read if marked on this side. According to the claimed invention, the bottom flat side <NUM> provides a planar side for labeling, printing and other marking means as conventional ribbons. In this regard, the present invention supports cable identification of conventional printing means. Furthermore, the bottom flat side <NUM> also provides a basis plane during heat stripping and splicing, providing convenience in operations for technicians. As such, the claimed invention supports a bending from the bottom flat side <NUM> to the curved side <NUM>. According to another embodiment not being part of the claimed invention, when marking is not a concern or improved marking on curved side <NUM> is sufficient, both the curved side <NUM> and the bottom side <NUM> are curved. This embodiment supports a bi-directional bending to both sides.

The present invention provides advantage over the prior art optic fiber ribbons by having a curved side <NUM> that facilitates the bending of the optic fiber ribbons without unduly stress the ribbon matrix <NUM> by reducing the impact of tension and compression forces. This advantage of the present invention will be further illustrated in connection with <FIG> (prior art) and <FIG> (embodiment useful for understanding but not being part of the claimed invention). <FIG> (prior art) is a cross-sectional view of conventional optic fiber ribbon cable in a bending position. Referring to <FIG>, when the conventional optic fiber ribbon <NUM> is bent from the sides of the bottom side <NUM> towards the top side <NUM> of the ribbon as illustrated in <FIG>, and/or bent from the top side <NUM> to the bottom side <NUM> in the center, center pointing compression forces <NUM> will be exerted on the top side <NUM>, whereas peripheral-pointing tension forces <NUM> will be exerted on the bottom side 320A. The compression forces <NUM> and tension forces <NUM> also interact, converging and concentrating on breaking points D's where the ribbon matrix is most prone to be broken. The ribbon matrix may become broken or otherwise damaged if the force is intense or persists. To overcome the disadvantage of the conventional ribbon cable, the present invention proposes the curved top side to reduce the tension and compression forces when bent as illustrated in <FIG>.

<FIG> is a cross-sectional view of the optic fiber ribbon in a bending position according to an embodiment not being part of the claimed invention. Now referring to <FIG>, the ribbon <NUM> is in a bending position. The fiber ribbon <NUM> is bent from the sides of the bottom side <NUM> towards the top side <NUM> of the ribbon as illustrated in <FIG>, and/or bent from the top side <NUM> to the bottom side <NUM> in the center, center pointing compression forces <NUM> will be exerted on the top side <NUM>, whereas peripheral-pointing tension forces <NUM> will be exerted on the bottom side <NUM>. As illustrated in <FIG> and <FIG>, in bending position, bending gaps <NUM> between the neighboring waveforms <NUM> are pushed together, along the curvature between the valley points Bs and the peak points Cs of the waveforms <NUM>. The curvature provides a guided bending pathway for the bendable ribbon <NUM>. During bending, the neighboring waveforms <NUM> are "curled" together. The points A on the neighboring waveforms <NUM> will touch each other. As illustrated herein, the bending gaps <NUM> are devoid of the materials of the ribbon matrix, resulting in the reduction of the tension and compression forces that would be otherwise created should the space be filled with matrix material as illustrated in <FIG>.

<FIG> is a cross-sectional view of the optic fiber ribbon in another bending position according to a preferred embodiment of the present invention. Referring to <FIG>, the bendable ribbon can be bent in a reverse bend, namely bending in a direction pointing from the curved side <NUM> to the bottom side <NUM>. The reverse bend may be opted by users in consideration of factors such as the formfactor of the waveforms <NUM>. As illustrated in <FIG>, the valley points B are pressed during a bending action in the direction shown in <FIG>. When the points A are touching each other, the valley points B are subject to compression, causing strain of on the ribbon. Depending on the particular curve of waveform <NUM> as further described in connection with <FIG>, the surface along the arcs from points B to A may all be subjected to more or less compression causing stress and strain on the ribbon. As such, a reverse bend as shown in <FIG> may be more advantageous depending on the material and/or manufacturing process of the ribbon matrix. As shown in <FIG>, when the ribbon is bent from the curved side <NUM> to the bottom side <NUM>, the cut from B to B' will open up, further extending the bending gap <NUM> from B to point B'. The additional space in the bending gap <NUM> in <FIG> helps to reduce the reverse bending curve's diameter for similar amount of strain on the structure of the ribbon matrix.

The curves of the waveform <NUM> are configured of a plurality of curves. <FIG> illustrates a plurality of cross-sectional view of the curves of the waveform <NUM>. <FIG> illustrates an optic fiber ribbon with the waveform <NUM> having a cross-sectional view of a partial circle. <FIG> illustrates an optic fiber ribbon with the waveform <NUM> having a cross sectional view of a substantially triangular shape. <FIG> illustrates an optic fiber ribbon with the waveform <NUM> having a cross sectional view of a substantially a trapezoid shape, not to be used in the claimed invention. <FIG> illustrates an optic fiber ribbon with the waveform <NUM> having a cross sectional view of substantially parabolical curves. It is to be understood by people of ordinary skill of the art, the above plurality of waveforms are by way of illustration not limitation. Any other cross-sectional shape of the waveforms <NUM> that have curved surfaces as defined in claim <NUM> and that have bending gaps between the neighboring domes that allow the optic fiber ribbon to be bent towards the center is within the scope of the present invention.

The bendable ribbons may be used in connection with ribbon cables to increase the fiber counts of the cable. The optic ribbon cable with bendable ribbon will be illustrated in connection with <FIG> and <FIG>. <FIG> (prior art) is a conventional multitube single jacket fiber optic cable with ribbons 500A. The conventional multitube single jacket fiber optic cable 500A comprises a core 510A, loose tubes 520A and a jacket 530A. Within the loose tubes 520A, a plurality of stacked ribbon 540A is located therein. As is clearly illustrated in <FIG>, due to the manner the ribbon cables are stacked, there are empty spaces 550A within the loose tubes and empty spaces between the loose tubes 520A and the cable jacket 530A. The empty spaces 550A cannot be used for placing more stacked ribbon cables, because of the dimensional limitation, thereby wasting the space and limiting the total fiber counts that the conventional cable 500A may carry.

<FIG> illustrates the multitube single jacket fiber optic cable with bendable optic fiber ribbon according to a preferred embodiment of the present invention. Now referring to <FIG>, the fiber optic cable 500B comprises a cable core 510B, a cable jacket 530B and a plurality of bendable optic fiber ribbons 540B. The plurality of bendable optic fiber ribbons 540B is arranged in concentric rings layering on top of each other. Alternatively, the plurality of bendable optic fiber ribbons 540B are arranged in a spiral manner (not shown), with the plurality of optic fiber ribbon 540B located side-by-side to each other and generally circling the core 510B. As such, the plurality of the optic fiber ribbons 540B fills the space between the cable core 510B and the cable jacket 530B in a geometrically tighter manner compared to the conventional cable 500A. The wasted spaces such as 550A and 560A as illustrated in <FIG> are thus eliminated. More ribbon optic cables can be accommodated enhancing the total fiber counts a cable can carry.

The above descriptions of the embodiments of the present disclosure are provided for demonstration to persons skilled in the art, instead of exhaustively listing all the embodiments or limiting the present disclosure to a single disclosed embodiment. In view of the above, various replacements and variations to the present disclosure are apparent to persons skilled in the art. Therefore, although some alternative embodiments have been discussed in detail, other embodiments are apparent or can be readily derived by a person skilled in the art. The present disclosure is intended to cover all the replacements, modifications and variations to the present disclosure that have been discussed here as well as other embodiments consistent with the scope as defined by the appended claims.

Claim 1:
A bendable optic fiber ribbon (<NUM>), comprising:
a plurality of optic fibers (<NUM>) configured for optical communications;
and a ribbon matrix (<NUM>) comprising a first side wherein the first side is a top curved side (<NUM>) and the top curved side (<NUM>) has a cross sectional shape of a periodical waveform (<NUM>) and a second side is a bottom flat side, wherein the plurality of optic fibers (<NUM>) is disposed in parallel between the first side and the second side along a longitudinal axis of the bendable optic fiber ribbon,
wherein the periodical waveform (<NUM>) of the first side comprises a plurality of curved surfaces with bending gaps (<NUM>) between neighboring curved surfaces, wherein each of the curved surfaces is formed over a single optic fiber with the optic fiber located in the center of the corresponding curved surface, wherein said bending gaps (<NUM>) are configured to reduce at least one of a compression force (<NUM>) and a tension force (<NUM>) received by the bendable optic fiber ribbon (<NUM>) when at least one bending force is applied to the bendable optic fiber ribbon (<NUM>),
characterized in that the bending gaps (<NUM>) have a cut from a valley point (B) to another point (B') located inside the ribbon matrix (<NUM>) wherein the cut between valley point (B) and the another point (B') remains closed when the bendable optic fiber ribbon is not bent or bent from the bottom side (<NUM>) to the top curved side (<NUM>) and the cut between valley point (B) and the another point (B') will open up when the bendable optic fiber ribbon is bent from the top curved side (<NUM>) to the bottom side (<NUM>).