Abstract:
An optical-electric composite cable includes an optical fiber, an inner tubular cover enclosing the optical fiber, a plurality of electric wires arranged outside the inner tubular cover, a binding member collectively bundling the plurality of electric wires, and an outer tubular cover covering an outer periphery of the binding member. A gap exists between the binding member and the outer tubular cover.

Description:
The present application is based on Japanese patent application No. 2013-163027 filed on Aug. 6, 2013, the entire contents of which are incorporated herein by reference. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The invention relates to an optical-electric composite cable having an optical fiber(s) and plural electric wires. 
     2. Description of the Related Art 
     An optical-electric composite cable is known that is used for e.g. signal transmission between electronic devices such as personal computer or display and that an optical fiber and plural electric wires are collectively covered by a sheath. Some optical-electric composite cables are configured to prevent an increase in optical loss caused by microbending of the optical fiber (slight bending of a central axis of a core caused by pressure (lateral pressure) applied from a side surface) (See e.g. JP-A-2011-018544 and JP-A-2012-009156). 
     The optical-electric composite cable disclosed in JP-A-2011-018544 is constructed such that an optical fiber is arranged in the center and plural covered conductors are arranged to surround the optical fiber. In addition, high-tensile fiber such as Kevlar (trademark) is filled between the optical fiber and the plural covered conductors. In this optical-electric composite cable, an external force from outside of the sheath is absorbed by a covering of the covered conductor and is also dispersed by the high-tensile fiber, and it is thereby possible to reduce lateral pressure acting on the optical fiber. 
     The optical-electric composite cable disclosed in JP-A-2012-009156 is constructed such that an optical fiber is arranged so as to be in contact with an inner peripheral surface of a protective tube and plural electric wires are arranged around an outer periphery of the protective tube. In this optical-electric composite cable, since the optical fiber is protected from an external force by the protective tube, bending or twisting of the optical fiber due to the external force is suppressed and an increase in transmission loss is thus suppressed. 
     The related arts may be JP-A-2011-018544, JP-A-2012-009156 and Japanese patent application No. 2012-206722 (i.e., JP-B-5273284) 
     SUMMARY OF THE INVENTION 
     The optical-electric composite cable disclosed in JP-A-2011-018544 may have the problem that since the high-tensile fiber between the optical fiber and the plural covered conductors is filled at a density allowing the external force to be dispersed, there is no gap around the optical fiber and the external force may act as lateral pressure on the optical fiber via the high-tensile fiber. 
     The optical-electric composite cable disclosed in JP-A-2012-009156 may have the problem that bending or twisting of the optical fiber caused by the external force can be prevented if the protective tube is sufficiently strengthened against the external force which may act on the optical-electric composite cable, but this causes a decrease in flexibility of the cable. 
     It is an object of the invention to provide an optical-electric composite cable that is adapted to reduce an optical loss caused by the microbending of optical fiber while suppressing a decrease in flexibility. 
     (1) According to one embodiment of the invention, an optical-electric composite cable comprises:
         an optical fiber;   an inner tubular cover enclosing the optical fiber;   a plurality of electric wires arranged outside the inner tubular cover;   a binding member collectively bundling the plurality of electric wires; and   an outer tubular cover covering an outer periphery of the binding member,   wherein a gap exists between the binding member and the outer tubular cover.
 
In the above embodiment (1) of the invention, the following modifications and changes can be made.
   (i) The gap is not less than 50 μm.   (ii) The binding member is helically wound around the plurality of electric wires so as to be in contact with the outer periphery of the plurality of electric wires.   (iii) A winding pitch of the binding member is not less than 5 mm and not more than 200 mm.   (iv) The plurality of electric wires are arranged so that the radial center of each electric wire is located on a circle having a diameter Pd and centered at the central axis of the inner tubular cover, and the following inequality is satisfied:
 
15≦ P/Pd≦ 30
 
where P is the winding pitch of the binding member.
   (v) An elastic modulus of the outer tubular cover is not less than 0.01 GPa and not more than 1 GPa.   (vi) The binding member comprises one of a paper tape, a polytetrafluoroethylene (PTFE) tape and a polyethylene terephthalate (PET) tape.   (vii) The binding member further comprises a shield layer on an outer periphery of the tape.   (viii) The binding member comprises a conductive tape.   (ix) The plurality of electric wires are helically wound along an outer peripheral surface of the inner tubular cover so as to be interposed between the inner tubular cover and the binding member, and   wherein the cable is configured to reduce a load applied to the inner tubular cover by an external force from the outer periphery side of the binding member by contact between adjacent electric wires and sliding of the electric wires with respect to the inner tubular cover.       

     Effect of the Invention 
     According to one embodiment of the invention, an optical-electric composite cable can be provided that is adapted to reduce an optical loss caused by the microbending of optical fiber while suppressing a decrease in flexibility. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Next, the present invention will be explained in more detail in conjunction with appended drawings, wherein: 
         FIG. 1  is a cross sectional view showing an optical-electric composite cable in a first embodiment of the present invention; 
         FIG. 2  is a perspective view showing a structure of the optical-electric composite cable in the first embodiment of the invention; 
         FIG. 3  is an explanatory cross sectional view showing arrangement of electric wires in the optical-electric composite cable; 
         FIG. 4  is a side view showing the optical-electric composite cable in  FIG. 1 , where illustrations of a sheath and a shield layer are omitted; 
         FIG. 5  is a side view showing the optical-electric composite cable in  FIG. 1  in a bent state, where illustrations of a sheath, a shield layer and a tape are omitted; and 
         FIG. 6  is a cross sectional view showing an optical-electric composite cable in a second embodiment. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     First Embodiment 
     The first embodiment of the invention will be described in reference to  FIGS. 1, 2 and 3 .  FIG. 1  is a cross sectional view showing an optical-electric composite cable  100  in the first embodiment of the invention.  FIG. 2  is a perspective view showing a structure of the optical-electric composite cable  100 . In  FIG. 2 , illustrations of core wires  410  and  420  of electric wires  4  are omitted.  FIG. 3  is an explanatory cross sectional view showing arrangement of the electric wires  4  in the optical-electric composite cable  100 . 
     The optical-electric composite cable  100  is provided with optical fibers  1 , a tube  3  as a resin inner tubular cover for housing the optical fibers  1 , plural electric wires  4  arranged on the outside of the tube  3 , a binding member  5  for bundling the plural electric wires  4  all together and a sheath  6  as a resin outer tubular cover arranged on the outer periphery of the binding member  5 . 
     In the first embodiment, four optical fibers  1  and a fiber bundle  2  formed by bundling fibers such as aramid or Kevlar (trademark) are housed in a first housing portion  3   a  inside the tube  3 . The fiber bundle  2  is an example of a fibrous reinforcement member for increasing tensile strength of the optical-electric composite cable  100 . The fiber bundle  2  is desirably filled so that a ratio of void space inside the tube  3  is not less than 35%. However, the fiber bundle  2  does not need to be provided when the required tensile strength is ensured by the tube  3  or the sheath  6 . 
     The optical fiber  1  has a core  10  in the center, a clad  11  covering an outer periphery of the core  10  and a covering  12  for covering an outer periphery of the clad  11 . In the first embodiment, each of the four optical fibers  1  has the same structure and the same outer diameter. In this regard, however, the four optical fibers  1  may have outer diameters different from each other. In addition, the optical fiber  1  may be either a multi-mode optical fiber or a single-mode optical fiber. 
     The tube  3  is formed of fluorinated ethylene propylene (FEP), perfluoroalkoxy alkane (PFA), polyvinylidene fluoride (PVDF) or polyether ether ketone (PEEK). In addition, an elastic modulus of the tube  3  is desirably not less than 0.3 GPa and not more than 4.0 GPa. If the elastic modulus of the tube  3  is less than 0.3 GPa, an effect of protecting the optical fiber  1  is poor. On the other hand, the elastic modulus of more than 4.0 GPa causes a decrease in flexibility of the optical-electric composite cable  100 . 
     The plural electric wires  4  are housed in an annular second housing portion  5   a  between an inner peripheral surface of the binding member  5  and an outer peripheral surface of the tube  3 . In the first embodiment, ten electric wires  4  each having a circular cross section are arranged along the outer periphery of the tube  3  so as not to overlap each other in a radial direction. In addition, the radial center of each electric wire  4  is located on a circle having a diameter Pd and centered at the central axis of the tube  3 . 
     In addition, in the first embodiment, the ten electric wires  4  are composed four power lines  41  and six signal lines  42 . The power line  41  is formed by covering plural twisted core wires  410  with a resin insulation  411 . The signal line  42  is formed by covering plural twisted core wires  420  with a resin insulation  421 . The power line  41  is used for supplying power from an electronic device connected to one end of the optical-electric composite cable  100  to another electronic device connected to another end of the optical-electric composite cable  100 . The signal line  42  is used for transmitting and receiving signals between the electronic device and the other electronic device. Alternatively, some of electric wires  4  may be a non-conductive inclusion such as a dummy wire. 
     The insulations  411  and  421  are preferably formed of fluorinated ethylene propylene (FEP), perfluoroalkoxy (PFA), polyvinylidene fluoride (PVDF), polyethylene (PE), polyvinyl chloride (PVC) or ethylene-vinyl acetate copolymer (EVA) resin. These materials enhance slide between the tube  3  and the electric wire  4  and it is thus possible to prevent twisting or deformation of the tube  3  during production. In addition, since the electric wires  4  can efficiently move when the optical-electric composite cable  100  is bent, a force which is applied to the tube  3  from the electric wires  4  can be suppressed. In other words, it is possible to prevent deformation of the tube  3  and thus to reduce lateral pressure toward the optical fiber  1 . The insulations  411  and  421  may be formed of polytetrafluoroethylene (PTFE), polypropylene (PP), polyethylene terephthalate (PET) or polyphenylene sulfide (PPS), etc. 
     The binding member  5  is composed of a resin tape  51  for bundling the plural electric wires  4  and a shield layer  52  provided on an outer periphery of the tape  51 . 
       FIG. 4  is a side view showing the optical-electric composite cable  100  in  FIG. 1 , where illustrations of the sheath  6  and the shield layer  52  are omitted. The tape  51  is helically wound around the plural electric wires  4  so as to be in contact with outer surfaces the electric wires  4 . A winding pitch of the tape  51  is desirably not less than 5 mm and not more than 200 mm. The winding pitch P of the tape  51  in such a range allows flexibility of the optical-electric composite cable  100  to be ensured while reliably bundling the electric wires  4 . When the winding pitch of the tape  51  is less than 5 mm, flexibility of the optical-electric composite cable  100  is impaired. When the winding pitch of the tape  51  is more than 200 mm, breakage of the tape  51  is likely to occur at the time of bending the optical-electric composite cable  100 . 
     In addition, it is desirable to satisfy the following inequality (1):
 
15≦ P/Pd≦ 30  (1)
 
where Pd is a diameter of the circle on which the plural electric wires  4  are arranged and P is the winding pitch of the tape  51 . When P/Pd is less than 15, flexibility of the optical-electric composite cable  100  is impaired. When P/Pd is more than 30, breakage of the tape  51  is likely to occur at the time of bending the optical-electric composite cable  100 .
 
     The tape  51  is a paper tape, a polytetrafluoroethylene (PTFE) tape or a polyethylene terephthalate (PET) excellent in flexibility. 
     The shield layer  52  is, e.g., a braid formed by braiding multiple conductor wires. The conductor wire is formed of aluminum, copper, copper alloy, etc., or such materials plated with nickel, tin or silver, etc. 
     The sheath  6  is formed of a resin having excellent flexibility such as polyethylene (PE), polyvinyl chloride (PVC), polyurethane (PU), silicone or tetrafluoroethylene-hexafluoropropylene-vinylidene fluoride terpolymer (THV). The outer diameter of the sheath  6  is, e.g., 5.9 mm. In addition, an elastic modulus of the sheath  6  is desirably not less than 0.01 GPa and not more than 1 GPa. When the elastic modulus of the sheath  6  is less than 0.01 GP, the optical-electric composite cable  100  can be excessively bent and excessive lateral pressure may be applied to the optical fiber  1 . When the elastic modulus of the sheath  6  is more than 1 GP, flexibility of the optical-electric composite cable  100  decreases. Furthermore, it is desirable that the sheath  6  have a lower elastic modulus than the tube  3 . 
     A gap  6   a  is provided between the shield layer  52  and the sheath  6 . Providing the gap  6   a  improves flexibility of the optical-electric composite cable  100  as compared to without the gap  6   a  and also reduces lateral pressure applied to the optical fiber  1  when the optical-electric composite cable  100  is bent. That is, in case of not providing the gap  6   a , the electric wires  4  and the tube  3  which have higher elastic modulus than the sheath  6  are also bent together with the sheath  6 , hence, it is difficult to bend the optical-electric composite cable  100 . In addition, bending applied to the sheath  6  is transferred to the tube  3  without being released, which may cause excessive lateral pressure to be applied to the optical fiber in the tube  3 . 
     On the other hand, since the gap  6   a  is provided between the shield layer  52  and the sheath  6  in the present embodiment, the binding member  5  and the members therein move in the sheath  6  and escape from bending stress applied to the sheath  6  when the optical-electric composite cable  100  is bent. Therefore, at a certain level of bending, only the sheath  6  is bent and the binding member  5  and the members therein move in the sheath  6  without being bent, which allows flexibility of the optical-electric composite cable  100  to be increased. In addition, since the binding member  5  and the members therein move in the sheath  6  and escape from bending stress, lateral pressure applied to the optical fiber  1  is suppressed. 
     The size of the gap  6   a  is defined as the shortest distance between the outer peripheral surface of the binding member  5  and the inner peripheral surface of the sheath  6  in a state that the tube  3  and the sheath  6  are arranged so that the respective central axes coincide with each other, i.e., in a state that the binding member  5  and the members therein are arranged in the center of the optical-electric composite cable  100 . The gap  6   a  is desirably from 50 μm to 3000 μm. When the gap  6   a  is less than 50 μm, the space in the sheath  6  allowing the binding member  5  and the members therein to move is too narrow and the effect thereof is poor. When the gap  6   a  is more than 3000 μm, the entire diameter of the optical-electric composite cable  100  becomes too large. 
     The plural electric wires  4  are helically wound along an outer peripheral surface of the tube  3  so as to be interposed between the tube  3  and the binding member  5 , as shown in  FIG. 2 . That is, central axes of the electric wires  4  are inclined with respect to a direction parallel to the central axis of the tube  3 . A helical winding pitch of the plural electric wires  4  (a distance in a direction along the central axis of the tube  3  for winding a given electric wire  4  once around the tube  3 ) is desirably, e.g., not less than 5 mm and not more than 150 mm. 
     Since the plural electric wires  4  are helically arranged, flexibility of the optical-electric composite cable  100  is increased as compared to the case where the electric wires  4  are linearly arranged parallel to the central axis of the tube  3 , and lateral pressure applied to the optical fiber  1  when bending the optical-electric composite cable  100  is suppressed. That is, when the plural electric wires  4  are arranged parallel to the central axis of the tube  3 , it is difficult to bend due to tension generated in an electric wire  4  located on the outer side of the bent portion and the tube  3  is pressed by the tension. In addition, a compressive force which compresses the electric wire  4  in an axial direction acts on an electric wire  4  located on the inner side of the bent portion and impedes bending of the optical-electric composite cable  100 , and in addition to this, outwardly bulging curvature is generated on the electric wire  4  due to the compressive force and presses the tube  3 . Therefore, the tube  3  is pressed from the inner and outer sides of the bent portion, and lateral pressure acts on the optical fiber  1  when a bend radius is small. 
     On the other hand, in the first embodiment, since the plural electric wires  4  are helically arranged as shown in  FIG. 5 , no specific electric wire  4  is arranged throughout the inner or outer side of the bent portion of the optical-electric composite cable  100  (in a region longer than the helical winding pitch). In other words, each electric wire  4  is present on the outer side or inner side of the bent portion with respect to the tube  3  only in a region which is a half or less of the helical winding pitch. As a result, the tension in the portion on the outer side with respect to the tube  3  is balanced out by the compressive force in the portion on the inner side, which reduces a force of the electric wire  4  pressing the tube and increases flexibility of the optical-electric composite cable  100 . Note that, illustrations of the sheath  6 , the shield layer  52  and the tape  51  are omitted in  FIG. 4 . 
     In addition, the electric wires  4  slide with respect to the tube  3  in a cable longitudinal direction when the optical-electric composite cable  100  is bent by an external force acting thereon. The sliding between the tube  3  and the electric wires  4  reduces the force applied to the tube  3  from the electric wires  4  at the time of bending and also suppresses deformation of the tube  3 , which allows lateral pressure toward the optical fiber  1  to be reduced. In other words, in the optical-electric composite cable  100 , a load applied to the tube  3  by an external force from the outer periphery side of the sheath  6  is reduce by the sliding of the electric wires  4  with respect to the tube  3 . 
     In addition, in the first embodiment, the plural electric wires  4  are formed so that the outer diameter D 41  of the power line  41  and the outer diameter D 42  of the signal line  42  are the same in dimension, as shown in  FIG. 3 . Although the cross sectional area of the plural core wires  410  of the power line  41  is greater than that of the plural core wires  420  of the signal line  42 , the insulation  411  of the power line  41  is formed thinner than the insulation  421  of the signal line  42  and the outer diameter of the power line  41  is thus equivalent to that of the signal line  42 . 
     In the first embodiment, although the outer diameter D 41  of the power line  41  and the outer diameter D 42  of the signal line  42  are the same in dimension as described above, D 41  and D 42  may be different from each other. In this case, it is desirable that the following inequality (2) be satisfied:
 
 D   min ≧0.8 ×D   max   (2)
 
where D max  is an outer diameter of the thickest of the plural electric wires  4  and D min  is an outer diameter of the thinnest of the plural electric wires  4 .
 
     By determining the outer diameter of the plural electric wires  4  as described above, it is possible to suppress, e.g., constant pressure on the tube  3  from a specific electric wire  4  having a large outer diameter or creation of a large gap between an electric wire  4  having a small outer diameter and an outer peripheral surface of the tube  3  or an inner peripheral surface of the binding member  5 . 
     The plural electric wires  4  come into contact with each other, and a load applied to the tube  3  by an external force from the outer periphery side of the sheath  6  is thus reduced. In other words, when the optical-electric composite cable  100  receives an external force, the sheath  6 , the shield layer  52  and the tape  51  are deformed and some of the plural electric wires  4  receive a pressing force applied from the outer peripheral surface of the binding member  5  toward the inside. The electric wire  4  which received the pressing force comes into contact with the tube  3 , is deformed into an ellipse shape by receiving a reactive force of the tube  3 , and comes into contact with an adjacent electric wire  4 . A portion of the pressing force from the binding member  5  is absorbed by this contact between the electric wires  4  and the load applied to the tube  3  is reduced. In other words, deformation of the tube  3  is suppressed. 
     In order to obtain this effect, the number of the plural electric wires  4  housed in the second housing portion  5   a  is desirably not less than three and not more than twenty. This is because, in case of one or two electric wires  4 , the load applied to the tube  3  cannot be reduced by the contact between the electric wires  4  and, in case of more than twenty electric wires  4 , an effect of absorbing the pressing force from the binding member  5  by the contact between the electric wires  4  becomes poor due to a decrease in surface pressure between contact surfaces of the electric wires  4 . 
     In addition, it is desirable that the following inequality (3) be satisfied:
 
( D   i5   −D   o3 )/2×0.8 ≦D   max ≦( D   i5   −D   o3 )/2  (3)
 
where D o3  is an outer diameter of the tube  3 , D i5  is an inner diameter of the binding member  5  and D max  is the maximum value of the outer diameters of the plural electric wires  4 , as shown in  FIG. 3 .
 
     That is, the maximum value of the outer diameters of the plural electric wires  4  should be not less than 80% of a width of the second housing portion  5   a  (a distance between the outer peripheral surface of the tube  3  and the inner peripheral surface of the binding member  5  in a radial direction about the central axis of the tube  3 ). As a result, it is possible to surely obtain the effect that the load applied to the tube  3  is reduced by the contact between the electric wires  4 . 
     Meanwhile, it is desirable that a thickness t of the tube  3 , which is derived by calculating (D o3 −D i3 )/2, satisfy the following formula (4):
 
 t≧D   o3 ×0.20  (4)
 
where D i3  is an inner diameter of the tube  3  and D o3  is the outer diameter thereof.
 
     In other words, the thickness t of the tube  3  should be not less than one-fifth of the outer diameter D o3 . Strength of the tube  3  is ensured by forming the tube  3  as described above, which suppresses deformation thereof due to an external force and allows lateral pressure acting on the optical fiber  1  in the first housing portion  3   a  to be reduced. 
     Note that, the inner diameter D i3  and the outer diameter D o3  of the tube  3  are dimensions in a state that the tube  3  is not deformed and the inner and outer peripheral surfaces of the tube  3  in a cross section orthogonal to the central axis thereof each have a perfect circular shape, and D i3  and D o3  are equal to values derived by dividing circumferential lengths of the inner and outer peripheral surfaces on the cross section by π (circular constant). 
     Meanwhile, as shown in  FIG. 3 , when the outer diameter of the optical fiber  1  is defined as D 1 , the total value of the outer diameters of the four optical fibers  1  (D 1 ×4) is desirably smaller than the inner diameter (D i3 ) of the tube  3 . This is because a gap is formed between the optical fiber  1  and the inner peripheral surface of the tube  3  or between the optical fibers  1  even when the four optical fibers  1  are linearly aligned inside the first housing portion  3   a , and the pressing force acting on the tube  3  can be prevented from directly acting as lateral pressure on the optical fiber  1  even when the tube  3  is deformed by the external force in a recessed manner. 
     Meanwhile, a ratio of void space in the first housing portion  3   a  of the tube  3  is desirably not less than 35%. The “void space” here refers to a portion inside the first housing portion  3   a  where the four optical fibers  1  and the fiber bundle  2  are not present. That is, the ratio R 3  of void space in the first housing portion  3   a  is obtained by the following formula (5):
 
 R   3 =( C   1   −V   1   −V   2 )/ C   1   (5)
 
where C 1  is the cubic capacity of the first housing portion  3   a , V 1  is the volume of the optical fibers  1  in the first housing portion  3   a  and V 2  is the volume of the fiber bundle  2  in the first housing portion  3   a . Also, the ratio R 3  of void space is desirably not less than 35%.
 
     In more detail, a ratio of the volume of the four optical fibers  1  in the first housing portion  3   a  (occupancy of the optical fibers  1  (=V 1 /C 1 )) should be not less than 2% and not more than 25%. Meanwhile, a ratio of the volume of the fiber bundle  2  in the first housing portion  3   a  (occupancy of the fiber bundle  2  (=V 2 /C 1 )) should be not less than 2% and not more than 50%. In this case, the ratio R 3  of void space is not more than 96% (when the occupancy of the optical fibers  1  and that of the fiber bundle  2  are both 2%). In addition, when the fiber bundle  2  is not housed in the first housing portion  3   a , the upper limit of the ratio R 3  of void space is 98%. 
     Even when the tube  3  is deformed by the external force, lateral pressure applied to the optical fiber  1  by the deformation is suppressed when the ratio of void space in the first housing portion  3   a  is determined as described above. In other words, even when the tube  3  is crushed and deformed by the external force, the deformation is absorbed by narrowing the void space in the first housing portion  3   a  and the pressing force acting on the tube  3  is prevented from directly acting as lateral pressure on the optical fiber  1 . 
     Effects of the First Embodiment 
     In the first embodiment, it is possible to reduce optical loss caused by microbending of the optical fiber while suppressing a decrease in flexibility. 
     Second Embodiment 
     Next, the second embodiment of the invention will be described in reference to  FIG. 6 .  FIG. 6  is a cross sectional view showing an optical-electric composite cable  100 A in the second embodiment. In  FIG. 6 , constituent elements in common with those explained for the optical-electric composite cable  100  in the first embodiment are denoted by the same reference numerals and the explanation thereof will be omitted. 
     The optical-electric composite cable  100 A in the second embodiment has the same structure as the optical-electric composite cable  100  in the first embodiment except the structure of the binding member  5 . In other words, the sheath  6  is provided on the outer periphery of the tape  51  with a gap  6   a A in between without a shield layer in the optical-electric composite cable  100 A of the second embodiment, while the shield layer  52  is provided on the outer periphery of the tape  51  in the optical-electric composite cable  100  of the first embodiment. 
     The gap  6   a A is desirably not less than 50 μm and not more than 3000 μm in the same manner as the first embodiment. 
     The tape  51  may be a conductive tape in which a conductive metal film is formed on a resin tape. 
     In the second embodiment, providing the gap  6   a A allows optical loss due to microbending of the optical fiber to be reduced while suppressing a decrease in flexibility in the same manner as the first embodiment. 
     In addition, since the shield layer is not provided, it is possible to downsize the optical-electric composite cable  100  in a radial direction. Furthermore, when the tape  51  is a conductive tape, it is possible to improve shielding properties while downsizing the optical-electric composite cable  100  in a radial direction. 
     Although the embodiments of the invention have been described, the invention according to claims is not to be limited to the above-mentioned embodiments. Further, please note that all combinations of the features described in the embodiments are not necessary to solve the problem of the invention. 
     In addition, the invention can be appropriately modified and implemented without departing from the gist thereof.