IT201600084968A1 - FIBER OPTIC CABLE AND USE OF SUCH A CABLE TO TRANSMIT THE LIGHT EMITTED BY A SMARTPHONE MADE BY A LIGHT SOURCE - Google Patents

Description

DESCRIPTION

attached to a patent application for INDUSTRIAL INVENTION entitled: "Fiber optic cable and use of such a fiber optic cable to transmit the light emitted by a smartphone acting as an external light source"

DESCRIPTION

The invention relates to an optical fiber cable, for transmitting from one of its input ends to one of its output ends the light emitted by an external light source arranged at the input end of the optical fiber cable according to the preamble of claim 1 .

The invention also relates to the use of such a fiber optic cable to transmit the light emitted by a smartphone acting as an external light source. With the English term "smartphone", which has also entered common use in Italy, we mean an advanced mobile phone, which in addition to the typical telephony functions of a mobile phone offers both the typical functions of a handheld computer, such as ability to connect to WEB sites or install on them the so-called "apps", ie specific programs to manage a specific functionality, and typically multimedia features, such as playing music, taking photos, shooting video and the like. Such a smartphone has a special component on the back that emits the light necessary for the smartphone to operate in flash and / or torch mode.

A fiber optic cable of the type indicated initially allows you to have at its exit end a light that has been generated elsewhere and precisely the light that was emitted by the light source and then entered, at the input end. of the optical fiber cable, into the optical fibers contained therein and was then transmitted by these optical fibers to the output end of the optical fiber cable. In other words, thanks to the optical fiber cable, it is possible to transfer the light emitted by the light source, in order to be able to use it at the output end of the optical fiber cable.

It is known that the single optical fiber tends, due to the characteristics of the material of which it is composed, to arrange itself along a possibly straight line or, if it is very long, along a slightly curved line, since the optical fiber does not admit plastic deformations and this makes it difficult to arrange the optical fiber cables along tortuous paths. To overcome this, fiber optic cables are arranged within external elements such as road excavations, when the fiber optic cable must extend along paths up to hundreds of meters long, or within raceways or guide tubes, when the fiber cable optics must extend along paths of the order of tens of meters.

However, when the optical fiber cable must extend only for particularly short paths, i.e. having lengths between 20 cm and a couple of meters, the use of external guide elements within which the optical fiber cable is inserted so that it follows the development of these external guide elements involves only disadvantages, as it is very difficult to predict a priori the right development of these external guide elements and furthermore it is not possible to subsequently vary and adapt the development of these external guide tubes to changed local needs .

In this context, the task underlying the present invention consists in developing in such a way an optical fiber cable of the case mentioned initially, that both its course in space and the position of its output end can be optimally determined without the aid of elements external to the cable which force it to extend along a predetermined obligatory path.

According to the invention, this task is solved if an optical fiber cable having the characteristics indicated in the preamble of claim 1 additionally also has the characteristics indicated in the distinctive part of claim 1. Now it is possible to position the end freely and according to the requirements. of the optical fiber cable, ie the output end of the optical fibers, since the optical fiber cable intrinsically possesses, thanks to the presence of the at least one metal wire, the ability to maintain any development in space. By directly manipulating the optical fiber cable, that is, bending and directing it as needed, it is possible to set the desired course of the optical fiber cable in space and it is able to maintain the curved and directed configuration that is set by the user. This is due to the plastic deformation of at least one metal wire, which forces the entire fiber optic cable to remain in the position set by the user, counteracting the tendency to return to the initial configuration that is exerted by the optical fibers.

The at least one metal wire is suitably a steel wire, as claimed in claim 2, since steel is the metal that best resists the repeated bending to which the wire is subjected.

Claim 3 claims a first embodiment of the optical fiber cable, according to which the at least one metal wire is incorporated in the outer sheath of the optical fiber cable. The incorporation of at least one metal wire in the outer sheath allows for a physical separation between the metal wire and the optical fibers, so that there is no direct contact between them, which could affect the efficiency of the optical fibers.

As claimed in claim 4, in the case of this first embodiment the metal wires can be arranged in a uniformly distributed manner along the perimeter of the optical fiber cable, which allows to distribute the action exerted by the at least one metal wire and ensures that the outer sheath is locally stressed in a less violent manner.

Claim 5 claims a second embodiment of the optical fiber cable according to which at least one metal wire acts as the core around which the optical fibers are arranged. It is also covered with an insulating layer, in particular with an insulating layer of PVC. Such a positioning of the at least one metal wire, approximately in the center of the optical fiber cable, allows the creation of an optical fiber cable with a symmetrical structure, which responds in a more uniform and neutral way to the bends to which it is subjected. The insulating layer that covers at least one metal wire has the purpose of isolating the optical fibers from the metal wire, preventing the metal wire from affecting the efficiency of the optical fibers with any interference. The composite layer in aluminum and polyester that is claimed in claim 6 serves on the one hand, the internal one (polyester), for coupling with the underlying insulating layer that covers the at least one metal wire and on the other side, the external one. (aluminum), to improve the efficiency of the optical fibers, as aluminum is highly reflective and this contributes to reducing the phenomena of light absorption during the transmission of light inside the optical fiber cable.

Conveniently, as claimed in claim 7, the optical fibers are PMMA (polymethylmethacrylate) fibers, ie the purest ones used for example in communication networks for packet data transmission. They guarantee excellent performance when transmitting light inside the optical fiber cable. Furthermore, again as claimed in claim 7, the outer sheath of the optical fiber cable, which must be made of a thermoplastic material, is suitably made of PVC (polyvinyl chloride), in particular UV-resistant PVC. This outer sheath must be made of a thermoplastic material, as it is fused around the optical fibers, in order to stabilize the optical fiber cable.

If, as claimed in claim 8, the optical fiber cable is equipped, at its light-emitting end, with an optical component capable of varying at least one characteristic of the light emanating from this end, for example a lens or a transparent element colored, you can vary the lighting you want to achieve. As mentioned, a further task of the present invention consists in making it possible to use an optical fiber cable according to the invention in the particular case in which the light to be transmitted is the light emitted by a smartphone.

This task is solved if, as claimed in claim 9, the smartphone is equipped with further connection means suitable for interacting with the connection means of the optical fiber cable. Such use allows the light emitted by the specific component of the smartphone to be used optimally even at a certain distance from the smartphone, keeping the light intensity of the light it emits as unaltered as possible even at a certain distance from the smartphone. More specifically, the claimed use allows the light emitted by the appropriate smartphone component to be transferred to the output end of the fiber optic cable with a minimum reduction in light intensity. In fact, the light that is emitted by this special component of the smartphone immediately enters the input ends of the optical fibers, from which it is then transmitted to their output ends, which coincide with the output end of the optical fiber cable. In this way, a light emission substantially equivalent to that emitted by the specific component of the smartphone is made available at this output end of the optical fiber cable. It is therefore possible to illuminate something that is not in the immediate vicinity of the smartphone, for example an object such as a book or a work surface or a work area that is also difficult to access, by directing and bending the fiber optic cable and positioning it appropriately with respect to what you want to illuminate the output end of the fiber optic cable. Note that this can be done without having to move the smartphone as well, which can instead remain in a comfortable starting position. Furthermore, since it is not necessary to hold the smartphone in order to illuminate, both hands are available during the lighting phase.

Thanks to the claimed use, it is therefore possible to optimally use the light it emits even away from the smartphone.

Further advantages and characteristics of the invention will become more evident from the following description of an example of realization of the optical fiber cable according to the invention and of its use, which are illustrated purely by way of example and indicative, but certainly not limitative, on the basis of the attached drawings. In the drawings they show:

fig. 1 schematically in side view an optical fiber cable according to a first and a second embodiment thereof;

fig. 2 schematically a cross section according to the section line A-A of the optical fiber cable of fig. 1 in the case of a first embodiment thereof;

fig. 3 schematically a cross section according to the section line A-A of the optical fiber cable of fig. 1 in the case of a second embodiment thereof; fig. 3a schematically and with reference to the second embodiment of the optical fiber cable of fig. 3, a detailed and enlarged representation of the at least one metal wire and the part of the optical fiber cable that surrounds this at least one metal wire;

fig. 4 schematically a detailed and enlarged representation of the right end of the optical fiber cable of fig. 1, i.e. the outlet end

fig. 5 schematically in perspective view of the back of a smartphone, being in particular recognizable the specific component of the smartphone that emits the light necessary for operation in flash and / or torch mode of the smartphone;

fig. 6 schematically in perspective view the smartphone of fig. 5 connected to the optical fiber cable according to the invention;

fig. 7 schematically, in the case of a first embodiment example of the first and second connection means, a detailed and enlarged representation of the smartphone portion containing the appropriate smartphone component and the annular hole to which the cable is connected fiber optic;

fig.7a schematically, in the case of the example of realization of fig. 7 of the connection means, a detailed and enlarged representation of the left end of the optical fiber cable of fig. 1, i.e. the entry end;

fig. 8 schematically a detailed and enlarged representation similar to fig. 7, in the case of a second embodiment of the first and second connecting means;

Fig. 8a schematically shows a detailed and enlarged representation similar to Fig. 7a, in the case of a second embodiment of the first and second connecting means;

fig. 9 schematically, in the case of a third example of embodiment of the first and second connection means, a sectional representation along the entry end of the optical fiber cable, along the annular hole connected to said entry end and along the specific component of the smartphone.

The figures show an optical fiber cable 5 to transmit the light emitted by an external light source located at the input end of the optical fiber cable 5 from one of its input ends to one of its output ends. The optical fiber cable 5 comprises an outer sheath, which delimits it externally, and a plurality of optical fibers 6, which are arranged inside the outer sheath and extend along the optical fiber cable 5 to the output end of fiber optic cable 5. The optical fiber cable 5 6 also comprises connection means 7a; 7b; 7c for connecting, in a detachable manner, the optical fiber cable 5 to the external light source, which 7a; 7b; 7c are arranged at the entry end of the fiber optic cable 5. When the optical fiber cable 5 is connected to the external light source, the light that comes out of the external light source enters a mandatory path, made up of the optical fibers 6 of the optical fiber cable 5, and can only escape to the outside. at the end of this mandatory path, i.e. only at the output end of the optical fiber cable 5, as shown for example in Figure 6, in which a smartphone 2 acts as an external light source.

According to the invention, the optical fiber cable 5 comprises inside at least one metal wire 9, see for example figs. 2 and 3, which is preferably made of steel.

According to a first embodiment of the optical fiber cable 5, see fig. 2, Γ at least one metal wire 9 is incorporated in the outer sheath of the optical fiber cable 5 and is not in direct contact with the optical fibers 6. Furthermore, if there are several metal wires 9, as shown for example in fig. 2, these metal wires 9 are suitably arranged in a uniformly distributed manner along the perimeter of the optical fiber cable 5.

According to a second embodiment of the optical fiber cable 5, on the other hand, see figs. 3 and 3a, the at least one metal wire 9 acts as a core around which the optical fibers 6 are arranged and is covered with an insulating layer 10, which can be made in particular of PVC (polyvinyl chloride) and which is in turn coated from a composite layer 11 in aluminum / polyester, as shown for example in fig. 3 a. As can also be seen from the combined view of the two figs. 3 and 3a, this composite layer 11 is arranged between the insulating layer 10 and the optical fibers 6 and presents internally towards the insulating layer 10 the polyester and externally towards the optical fibers 6 retarded aluminum.

The insulating layer 10 serves to protect the metal wire 9 from humidity and prevent its eventual oxidation, while the composite layer 11 serves, thanks to the presence of aluminum, to reflect the light as much as possible and therefore to improve the propagation of light. inside the optical fiber cable 5, i.e. inside the optical fibers 6. The optical fibers 6 can be wound in a helix around the composite layer 11, so that the optical fiber cable 5 is stronger, but in figs . 3 and 3a this characteristic has not been represented in order not to weigh down the representation.

With reference to both embodiments of the optical fiber cable 5, the optical fibers 6 are suitably optical fibers in PMMA (polymethylmethacrylate), while the outer sheath of the optical fiber cable 5 is in a thermoplastic material resistant to UV rays, in particular in PVC (polyvinyl chloride), and is fused around the optical fibers 6.

In the figures 12 is also represented an optical component capable of varying at least one characteristic of the light emanating from the optical fiber cable 5. This optical component 12 is part of the optical fiber cable 5 and is provided at the output end of the optical fiber cable 5. Such an optical component 12 can be for example a lens or a transparent and colored optical component, and it 12 can be applied, as needed and for example by coupling as shown in fig. 10, on the closing terminal 13 of the output end of the optical fiber cable 5

As has been said, in order to be able to transmit the light emitted by an external light source, a connection is provided, which can be unlocked if necessary, between the optical fiber cable 5 and the external light source and for this purpose the connection means 7a are provided; 7b; 7c of the optical fiber cable 5. The shape of these connecting means 7a; 7b; 7c depends on the shape of the external light source. The external light source in turn has connection means, and more precisely, respective further connection means 8a; 8b; 8c suitable for interacting with the connection means 7a; 7b; 7c to connect the input end of the cable together. 5 fiber optic and the external light source.

The operation of the optical fiber cable 5 is clear from fig. 6. In it the optical fiber cable 5 has been connected with its input end to an external light source, in this specific case the external light source is a smartphone 2, while the output end of the fiber cable 5 optical fibers has been positioned where it is necessary, directing and bending the optical fiber cable 5 even several times. Upon this positioning, the at least one metal element 9 comprised within the optical fiber cable 5 has been deformed in a manner corresponding to the development shown and it maintains itself and the entire optical fiber cable 5 without external help. such configuration. In other words, the optical fiber cable 5 no longer changes its configuration until the user intervenes again, for example, to stretch it in the configuration of fig. 1. If it is desired to vary the light beam exiting from the exit end of the optical fiber cable 5, it is possible to apply the optical component 12, which will be a lens, to the exit end, if it is desired to widen or narrow the light beam. light, or a colored transparent component, if a colored light beam is desired.

In figs. 6 - 9 shows the use of an optical fiber cable 5 according to the invention to transmit the light generated by an external light source consisting of a smartphone 2, in particular generated by a special component 4 of the smartphone 2 which 4 emits the light necessary for the smartphone 2 to operate in flash and / or torch mode. The smartphone 2 has an annular hole 3, which is arranged around said appropriate component 4 and in which 3 or adjacent to which 3 are arranged further connection means 8a; 8b; 8c suitable for interacting with the connection means 7a; 7b; 7c to connect together the input end of the optical fiber cable 5 and the annular hole 3 of the smartphone 2. The figures show three possible examples of embodiment for the connection means 7a; 7b; 7c and for the further connection means. connection 8a; 8b; 8c.

A first example of embodiment for such connection means is shown in figs. 7 and 7a, and according to this example the connecting means 7a consist of an externally threaded terminal element and the further connecting means 8a consist of an internal thread of the annular hole 3. Upon connection between the inlet end of the optical fiber cable 5 and the annular hole 3, the terminal element 7a is screwed into the internal thread 8a of the annular hole 3 and then to unlock this connection as needed, i.e. when it is no longer necessary to use the light coming out of the cable 5 a optical fibers, the terminal element 7a is unscrewed out of the internal thread 8a.

A second example of embodiment for the aforementioned connection means is shown in figs. 8 and 8a, and according to this example the connection means 7b consist of a magnet arranged on a closing terminal 13 of the entry end of the optical fiber cable 5 and the further connection means 8b consist of a ferromagnetic element arranged near the annular hole 3. Upon connection between the entry end of the optical fiber cable 5 and the annular hole 3, the magnet 7b is magnetically joined to the ferromagnetic element 8b and the closing terminal 13 is inserted into the annular hole 3. With these known closing terminals 13 the ends of the optical fiber cable 5 are stabilized. To unlock this connection as needed, that is, when it is no longer necessary to use the light coming out of the optical fiber cable 5, the magnet 7b is detached, pulling it with the hand, from the ferromagnetic element 8b.

A third example of embodiment for the aforementioned connection means is shown in fig. 9 and according to this example, the connection means 7c consist of a ring made of elastically yielding material and the further connection means 8c consist of an annular groove inside the annular hole 3. The ring 7c is located on the closing terminal 13 of the the entry end of the optical fiber cable 5. Upon connection between the entry end of the fiber optic cable 5 and the annular hole 3, the ring 7c is inserted into the internal annular groove 8c. To unlock this connection as needed, that is, when it is no longer necessary to use the light coming out of the optical fiber cable 5, the ring 7c is extracted, by pulling the entry end of the optical fiber cable 5, from the internal annular groove 8c.

All known systems of connection between an oblong element and a surface are obviously possible and conceivable, but according to the invention the above mentioned three embodiments are preferable and are distinguished by their simplicity and reliability. The use of the optical fiber cable 5 to transmit the light generated by a smartphone 2, in particular by a special component 4 of the smartphone 2 is as follows.

As soon as the user needs the light emitted by the smartphone 2 to be used to illuminate something specific that is distant from the smartphone 2 and is not well illuminated when the smartphone 2 works in torch mode, he connects to the smartphone 2, in particular to the annular hole 3, the entry end of the optical fiber cable 5. Upon doing this, depending on the present solution, either the terminal element 7a will be screwed into the internal thread 8a or the magnet 7b will be attached to the ferromagnetic element 8b or the ring 7c will be inserted into the internal annular groove 8c. The light emitted by the smartphone 2 thus propagates inside the optical fibers 6 of the optical fiber cable 5 and then comes out from the output end of the optical fiber cable 5 which becomes a luminous end. To illuminate what must be illuminated, the user will only have to direct and bring this luminous end closer to what must be illuminated. If at the time of this positioning of the luminous end of the optical fiber cable 5, the latter 5 should have been bent, even several times, and therefore have a curvilinear trend, see fig. 6, it 5 will maintain this curvilinear trend, as it is kept in position by at least one metal wire 9 that it 5 contains.

If you want to vary the light beam, you can apply the optical component 12, which will be a lens, to the exit end of the fiber optic cable 5 from which the light beam comes out, if you want to widen or narrow the light beam. , or a colored transparent component, if a colored light beam is desired.

At the end of the lighting, to detach the optical fiber cable 5 from the smartphone 2 1, proceed in the reverse way to what has been described, i.e., depending on the solution present, or the terminal element 7a will be unscrewed out of the internal thread 8a either the magnet 7b will be detached from the ferromagnetic element 8b or the ring 7c will be extracted out of the internal annular groove 8c.

Claims (9)

CLAIMS 1. Fiber optic cable (5), for transmitting the light emitted by an external light source arranged at the entry end of the optical fiber cable (5) from one of its input ends to one of its output ends, comprising: an outer sheath, which (5) delimits it externally; a plurality of optical fibers (6), which are arranged inside the outer sheath and extend along the optical fiber cable (5) to the output end of the optical fiber cable (5) and connection means (7a; 7b; 7c) for connecting, in a detachable manner, the optical fiber cable (5) to the external light source, which (7a; 7b; 7c) are arranged at the input end of the optical fiber cable (5), characterized in that it (5) comprises at least one metal wire (9) inside it. 2. Optical fiber cable (5) according to claim 1, characterized by the fact that the at least one metal wire (9) is made of steel. Optical fiber cable (5) according to claim 1 or 2, characterized in that the at least one metal wire (9) is incorporated in the outer sheath of the optical fiber cable (5) and is not in direct contact with the optical fibers (6). Optical fiber cable (5) according to claim 3, characterized in that the metal wires (9) are arranged in a uniformly distributed manner along the perimeter of the optical fiber cable (5). Optical fiber cable (5) according to claim 1 or 2, characterized in that the at least one metal wire (9) acts as a core around which the optical fibers (6) are arranged and is covered with an insulating layer (10), in particular by an insulating layer (10) in PVC. Optical fiber cable (5) according to claim 5, characterized in that it -i 3⁄4 o or insulating layer (10) is in turn covered by a composite layer (11) in aluminum / polyester, said composite layer (11) being arranged between the insulating layer (10) and the optical fibers (6) and presenting internally towards the insulating layer (10) the polyester and externally towards the optical fibers (6) aluminum. Optical fiber cable (5) according to one of the preceding claims, characterized in that the optical fibers (6) are PMMA fibers and that the outer sheath of the optical fiber cable (5) is made of a radiation-resistant thermoplastic material UV, especially in PVC, and is fused around the optical fibers (6). Optical fiber cable (5) according to one of the preceding claims, characterized in that the optical fiber cable (5) is equipped at its output end with an optical component (12) adapted to vary at least one characteristic of the light protruding from this free end of the optical fiber cable (5). Use of an optical fiber cable (5) according to one of the preceding claims, to transmit the light generated by an external light source consisting of a smartphone (2), in particular generated by a suitable component (4) of the smartphone ( 2) which (4) emits the light necessary for the operation of the smartphone (2) in flash and / or torch mode, the smartphone (2) having an annular hole (3), which is arranged around said special component (4 ) and in which (3) or adjacent to which (3) further connection means (8a; 8b; 8c) are arranged, suitable for interacting with the connection means (7a; 7b; 7c) to connect together the end of fiber optic cable entry (5) and the annular hole (3).