![[US Patent & Trademark Office, Patent Full Text and Image Database]](/netaicon/PTO/patfthdr.gif)
![[Home]](/netaicon/PTO/home.gif)
![[Boolean Search]](/netaicon/PTO/boolean.gif)
![[Manual Search]](/netaicon/PTO/manual.gif)
![[Number Search]](/netaicon/PTO/number.gif)
![[Help]](/netaicon/PTO/help.gif)
![[Bottom]](/netaicon/PTO/bottom.gif)
![[View Shopping Cart]](/netaicon/PTO/cart.gif)
![[Add to Shopping Cart]](/netaicon/PTO/order.gif)
![[Image]](/netaicon/PTO/image.gif)
| United States Patent |
5,381,505
|
|
Fischietto
, et al.
|
January 10, 1995
|
Optical fibers with a light absorbing coating
Abstract
Optical fibers having one or more polymeric coatings have been found to be
sensitive to extraneous light arising either as incident light from
outside the optical fiber or as light escaping the fiber at bends and
being reflected back into the fiber by a coating acting as a secondary
cladding. In either case the extraneous light intensity may be reduced by
placing at least one light absorbing component in a coating. Where the
light absorbing component is placed in a coating between the primary
cladding of the optical fiber and the secondary cladding both sources of
extraneous light may be reduced or eliminated. Particulate amorphous
carbon is an effective light absorber because of the broad range of
optical wavelengths absorbed and because of its efficiency of absorption
(high extinction coefficient) over this range.
| Inventors:
|
Fischietto; Frederick J. (Folsom, CA);
Jones; Ralph E. (Sacramento, CA);
Wilcox; Steven W. (El Dorado Hills, CA);
Zetter; Mark S. (El Dorado Hills, CA)
|
| Assignee:
|
UOP (Des Plaines, IL)
|
| Appl. No.:
|
174094 |
| Filed:
|
December 28, 1993 |
| Current U.S. Class: |
385/128; 385/123 |
| Intern'l Class: |
G02B 006/22 |
| Field of Search: |
385/128,123-127,141,100,144
359/360
65/3.12,3.13,DIG. 16
362/32
126/652,908
428/615,620,650
|
References Cited [Referenced By]
U.S. Patent Documents
| 4334523 | Jun., 1982 | Spanoudis | 359/360.
|
| 4372648 | Feb., 1983 | Black | 385/127.
|
| 4637686 | Jan., 1987 | Iwamoto et al. | 385/128.
|
| 4678273 | Jul., 1987 | Vilhelmsson | 385/128.
|
| 5000541 | Mar., 1991 | DiMarcello et al. | 385/128.
|
| 5062687 | Nov., 1991 | Sapsford | 385/128.
|
| 5093880 | Mar., 1992 | Matsuda et al. | 385/128.
|
Other References
"Optical Fiber Communications", B. K. Tariyal and A. H. Cherin,
Encyclopedia of Physical Science and Technology, vol. 9, pp. 605-629
(1987). (no month).
"Optical Fibers, Drawing and Coating", L. L. Blyler, Jr. and F. V.
DiMarcello, ibid., pp. 647-657, (1987). (no month).
|
Primary Examiner: Lee; John D.
Assistant Examiner: Heartney; Phan Thi
Attorney, Agent or Firm: McBride; Thomas K., Snyder; Eugene I.
Parent Case Text
CROSS REFERENCE TO RELATED APPLICATIONS
This application is a continuation-in-part of our copending application,
Ser. No. 08/045,515, filed Aug. 9, 1993, still pending all of which is
hereby incorporated by reference.
Claims
What is claimed is:
1. In an optical fiber transmitting radiation along the core of said fiber,
at least a portion of said transmitted radiation being in the wavelength
range between about 200 and about 30,000 nanometers, the improvement
comprising providing said optical fiber with a first coating of organic
polymers containing a particulate amorphous carbon in an amount effective
to absorb at least 99% of the radiation within said wavelength range
entering said first coating.
2. The improved optical fiber of claim 1 where said first coating of
organic polymers is interposed between a primary cladding and a second
coating acting as a secondary cladding.
3. The improved optical fiber of claim 1 where the transmitted radiation is
of a wavelength between about 200 and about 2500 nanometers.
4. The improved optical fiber of claim 1 where said first coating of
organic poloymers acts as a secondary cladding.
5. An optical fiber transmitting radiation, at least a portion of which is
within the wavelength range between about 200 and about 30,000 nanometers,
said optical fiber comprising concentric layers of:
a) a glassy core of refractive index n;
b) a glassy cladding of refractive index less than n;
c) a polyimide coating; and
d) a silicone coating containing a particulate amorphous carbon in an
amount which absorbs at least 99% of the radiation within said wavelength
range entering said silicone coating.
6. The optical fiber of claim 5 where the radiation transmitted is of a
wavelength between about 200 and about 2500 nanometers.
7. An optical fiber transmitting radiation, at least a portion of which is
within the wavelength range between about 200 and about 30,000 nanometers,
comprising concentric layers of:
a) a core of refractive index n;
b) a primary cladding of refractive index less than n;
c) a secondary cladding of refractive index less than n;
d) a coating of organic polymers containing a particulate amorphous carbon
in an amount which absorbs at least 99% of the radiation within said
wavelength range entering said coating, where said coating is either i)
the secondary cladding of c) or ii) interposed between the primary
cladding of b) and the secondary cladding of c).
8. The optical fiber of claim 7 where the transmitted radiation is of a
wavelength between about 200 and about 2500 nanometers.
Description
BACKGROUND OF THE INVENTION
Wave guides have become familiar means to transmit high radio frequency
signals, especially in the microwave region. More recent developments have
made wave guides for the transmission of light rather commonplace. An
optical fiber is a wave guide in which light is propagated by total
internal reflection at the fiber boundaries. For the purpose of this
application, "light" will refer to electromagnetic radiation in the
ultraviolet, visible, and infrared ranges of the electromagnetic spectrum,
which are approximately 200-400 nm, 400-800 nm, and 800-300,000 nm,
respectively, extending through the far infrared range. The greatest use
of optical fibers has been in communication and data transmission systems
where light waves of a narrow wavelength are used as carriers via pulse or
frequency modulation to transmit information. A less common but
increasingly important application of optical fibers is for the
transmission of analog information from a sensor to a remotely located
detector which measures the intensity of the transmitted light over a
range of wavelengths within the spectrum of light. For the purpose of this
application the spectral range of greatest interest is that spanning the
ultraviolet (ca. 200-400 nm), visible (ca. 400-800 nm) and near infrared
(ca. 800-2500 nm).
The measurement of, for example, digital information differs significantly
from that of analog information and imposes different requirements. Where
digital information is transmitted along an optical fiber one is
interested only in whether or not a signal is present, or more accurately
whether light of a particular frequency is present at an intensity above
some threshold value. Where analog information is transmitted along
optical fibers one is interested in the absolute intensity of the signal
at each wavelength of some extended portion of the light spectrum. Thus it
becomes clear that where accurate transmission of analog information along
an optical fiber is required it is necessary that both the wavelength and
intensity of the transmitted light be preserved, that is, one can tolerate
neither wavelength shifts nor intensity variation along the transmission
path.
The principles of optical fibers are too well known to require extended
discussion here. See, for example, "Optical Fiber Communications", B. K.
Tariyal and A. H. Cherin, Encyclopedia of Physical Science and Technology,
Vol. 9, pp 605-629 (1987); "Optical Fibers, Drawing and Coating", L. L.
Blyler, Jr. and F. V. DiMarcello, ibid., pp 647-57. In brief, optical
fibers have a core of plastic, glass, silica or other glassy transparent
material with an outer, concentric layer called cladding which has a
refractive index lower than the core. Where light injected into the core
strikes the core-cladding interface at an angle of incidence greater than
the critical angle there is total reflection, and since the angle of
incidence equals the angle of reflection it follows that light will zigzag
or spiral along the length of the core. Although in theory there should be
no light loss, in practice attenuation occurs along the optical fiber
because of the absorption by impurities within the core and because of
scattering arising mainly from fiber imperfections such as non-uniform
core diameter, bends in the fiber, and discontinuities at the
core-cladding interface.
Optical fibers per se are delicate and fragile, and generally need to be
protected by being sheathed with several concentric layers. In a variant
of interest here the core of the optical fiber is coated during the
drawing process with a thin layer of a tough polymer, such as a polyimide,
to protect the delicate surface from scratching and marring, and to
prevent microfracture. This is followed by another concentric layer of an
elastic polymer, such as silicones, thermoplastic rubber compounds,
urethanes or acrylates. Yet other coatings may be applied as protection
from physical and chemical damage. It also should be noted that in another
variant the cladding itself may be an elastic polymer. Of special interest
is the case where the optical fiber comprises concentric layers of a
glassy core of refractive index n, a glassy cladding of refractive index
less than n, a polyimide coating, and a silicone coating. It needs to be
emphasized that even though such an optical fiber is of special interest
to us, our invention is not limited to such an optical fiber but is
instead applicable to optical fibers generally.
We recently observed spurious signals in light transmitted along optical
fibers under two quite different circumstances. In one case the intensity
of light transmission varied with the intensity of ambient light external
to the optical fiber. Thus, the light intensity measured at different
wavelengths at the exit of an optical fiber varied with the intensity of
external light. This implied that there was a significant amount of
extraneous light from a source external to the fiber entering the core
through the cladding along the length of the optical fiber, contrary to
expectations. By "extraneous light" is meant light inserted into the core
of an optical fiber through the cladding, in contradistinction to light
injected directly into the core.
The second circumstance of spurious light transmission was noticed in an
optical fiber having bends along its length and was manifested as
selective attenuation at certain wavelengths. Further investigation showed
that the wavelengths whose intensity were reduced corresponded to spectral
absorption bands of a coating for the fiber. Evidently light was not
totally reflected at the core-cladding interface at bends in the fiber but
was reflected at the surface of other coatings acting as a secondary
cladding. Thus light traversed the core-(primary)cladding interface,
through one or more coatings external to the primary cladding where
selective absorption occurred, was reflected at the interface with the
secondary cladding back through the coatings it had already traversed
where absorption occurred for a second time, and finally entered the core
once more. In summary, light escaped the core, travelled through one or
more layers of coatings, there to be selectively absorbed, and was
reflected back into the core. Thus, light reentering the core
corresponded, at least roughly, to the "absorption spectrum" of the
traversed coatings and led to selective signal attenuation.
Once the nature of these problems was determined both were susceptible to a
common solution. If any coating contained one or more components which
efficiently absorbed the light entering the coating the problem could be
expected to be effectively solved for the case of incident light. If the
coating containing the light-absorbing component was placed between the
primary cladding and the secondary cladding both problems would be solved.
In fact, that turned out to be correct in the foregoing cases.
SUMMARY OF THE INVENTION
The purpose of this invention is to reduce or eliminate extraneous light
entering the core of an optical fiber. An embodiment comprises the
addition to a coating of at least one component absorbing light within the
range of wavelengths traveling along the core of the optical fiber. In a
more specific embodiment the component is charcoal in any of its forms. In
a more specific embodiment charcoal is present in an amount from about 0.1
up to about 10 weight percent of the coating. In yet another embodiment
the light absorbing component is added in an amount effective to absorb at
least 90% of the extraneous light at least at those wavelengths of
radiation injected into the core. In still another embodiment the optical
fiber is coated with an elastic polymer containing at least one light
absorbing component in an amount effective to absorb at least 90% of the
offending extraneous light. Other embodiments will be apparent from the
ensuing description.
DESCRIPTION OF THE INVENTION
This invention relates to optical fibers transmitting light, especially
radiation in the ultraviolet-visible-near infrared-infrared portion of the
light spectrum. For the purpose of this application, the light spectrum of
greatest interest is between about 200 and about 30,000 nm, and more
particularly from about 200 up to about 2500 nm. In the more usual case,
the optical fiber of our invention will be transmitting light of only a
limited wavelength range within the foregoing spectrum, and in fact the
more relevant parameter is the range of wavelengths whose intensity is
measured at the exit of the optical fiber, irrespective of the range of
wavelengths travelling within the fiber. The wavelength range .DELTA. will
in this application represent the wavelength range measured at the exit of
the optical fiber and usually, although not necessarily, also will
correspond to the wavelength range of the light being transmitted along
the optical fiber. It should be clear that only light of wavelengths
within .DELTA. are of importance in our invention. We previously have
defined "extraneous" light as that entering the core of an optical fiber
through the primary cladding. By "offending" light is meant extraneous
light within the wavelength range .DELTA. as that term is defined above.
It also should be explicitly recognized that material constraints place
limitations on spectral range which only reflect practical limitations.
Thus, most quartz fibers transmit light only up to about 2500 nm. Optical
fibers of zirconium fluoride can carry light of wavelength up to ca. 4000
nm. Chalcogenide fibers may extend that range to about 14,000 nanometers.
Thus, the limitations in materials available as optical fibers place
constraints on the spectral range of light carried by the fiber.
The optical fibers of our invention have at least one and usually several
coatings arranged concentrically around the cladded core. In at least some
cases one or more of the coatings also act as a secondary cladding,
reflecting light which escapes from the core through the primary cladding
back into the core. The coatings generally are organic polymers, some of
which may be elastic polymers. As previously stated, we have observed that
under some conditions there is extraneous light, which includes both 1)
the case where the extraneous light is ambient light entering from outside
the fiber and 2) the case where extraneous light is light which escapes
from the core via scattering and via loss of total internal reflection at
bends in the fiber and is reflected from a coating acting as a secondary
cladding. What is necessary is to prevent the extraneous light which has
entered any coating external to the primary cladding from entering, or
reentering, the core of the optical fiber.
The extraneous light which has entered a coating is prevented from getting
into the core of the optical fiber by having present in the coating a
light absorbing component. It is only necessary that this component absorb
light within the wavelength range .DELTA. since only that range of
wavelengths is being measured, or transmitted and measured. The light
absorbing component is present in an amount such that it absorbs at least
90% of the offending radiation, although it is preferable that it absorbs
at least 95%, and yet more preferable that it absorbs at least 99%, or
substantially all, of the offending radiation. One light absorbing
component which is particularly desirable is particulate amorphous carbon,
in all of its various forms, because it is effective to absorb radiation
over a very broad range of the spectrum of interest. By "particulate
amorphous carbon" is meant charcoal in all of its various forms and
however it may be referred to, such as decolorizing carbon, lamp black,
carbon black, activated carbon, activated charcoal, and so forth. It needs
to be understood that the success of our invention does not depend on the
nature or source of the particulate amorphous carbon used, but rather on
the fact that we use particulate amorphous carbon dispersed throughout the
polymeric coating. When particulate amorphous carbon is used it may be
employed in a concentration as little as about 0.1 weight percent up to as
high as about 10 weight percent of the coating. However, it should be
recognized that some polymer properties may be adversely affected (for
example, strength loss) with increasing concentrations of carbon black.
Consequently, it is more preferable that particulate amorphous carbon
concentrations do not exceed 5 weight percent, and even more preferable
that concentrations do not exceed about 2 weight percent. It also should
be clear that many other light absorbing components may be used. In
particular, other dyes may be used which are effective light absorbers
over more or less narrow ranges of the light spectrum. This variant may be
particularly useful when problems arise in only a very narrow and limited
range of the light spectrum, for in those cases the light absorbing
component may be carefully chosen to correspond to the problem areas
within the spectrum.
The identity of the coating is not of particular importance and it is known
that a rather broad range of materials are presently used. Examples of
suitable elastic polymers as coatings include silicones, acrylates,
urethanes, and rubbers, whether thermally cured or ultraviolet cured.
Examples of hard polymeric coatings include polyimides, polyacrylates, and
so forth.
As stated above the most generally effective placement of the coating
containing the light absorbing component(s) is between the primary and the
secondary claddings, for with such placement extraneous radiation from
both an external source as well as from failure of total internal
reflection can be absorbed. Where only radiation from an external source
is a problem the coating containing the light absorbing component(s) may
be located anywhere external to the primary cladding.
The foregoing description was couched in terms of discrete fibers. However,
in many uses fibers are bundled to afford an ensemble with each fiber core
carrying its own discrete spectrum of radiation. In such cases having on
each fiber a coating which contains the light absorbing components of our
invention also can be expected to be useful, especially in preventing
"crosstalk" between adjacent fibers. It should be clear that our invention
encompasses this variation as well.
The following examples illustrate our invention but are not intended to
limit it in any way.
EXAMPLE 1
Extraneous light via secondary cladding. An optical fiber was drawn from a
commercially available preform, coated with a thermally cured polyimide
(from DuPont) and sheathed in a thermally cured silicone. The fiber was
used to transmit light in the 1000-2300 nm range, and intensity
measurements were made on various coils of fiber of different bend radius
vs. unbent fiber as a reference. Significant attenuation was noticed at
wavelengths corresponding to absorption peaks of the polyimide. Absorption
varied with the bend radius, further supporting the view that light leaks
from the core of the bent fiber, i.e., it escapes from the core because of
failure of total internal reflection. The leaked light internally reflects
off the silicone sheath acting as a secondary cladding after being
absorbed by the polyimide, and is absorbed again by the polyimide before
reentering the core of the fiber.
EXAMPLE 2
Extraneous light via ambient light. The basic optical fiber was the same as
described above with a polyimide coating and was 500 microns in diameter.
Spectra of chloroform were obtained at various wavelengths in the
1000-2100 nm range using as the fiber on the source side of the analyzer,
i.e., fiber transmitting light to the sample, one having a thermally cured
silicone sheath, an ethylene-tetrafluoroethylene copolymer (Tefzel from
DuPont) jacket, a Kevlar.TM. braid, and an outer Tefzel jacket, with the
jacketed fiber wrapped in aluminum foil. The detector side of the analyzer
was connected to 6 meters of different fibers, one being a bare fiber
(only polyimide coated) and the other also having a silicone sheath
containing 1 weight percent carbon black. The latter were coiled, covered
with aluminum foil from their connection points to the coil, and placed in
an aluminum foil lined box. Scans of chloroform in a 50 mm cuvette were
obtained, both with the coils illuminated by a 100 W bulb held 7 inches
from the coil and without illumination. Table 1 gives the difference (in
absorbance units, AU) in light transmission at 4 points. Since chloroform
is virtually opaque at these wavelengths under the foregoing path length,
these are quite sensitive measurements for stray light.
TABLE 1
______________________________________
Effect of Ambient Light
AU Difference
Fiber 1151 nm 1408 nm 1679 nm 1860 nm
______________________________________
Bare 0.0441 0.0947 0.1891 0.2478
Silicone + 1% C
0.0004 0.0011 0.0014 0.0008
______________________________________
The foregoing data show both that light from an external source enters the
core through the coatings, and that the addition of carbon to a silicone
coating effectively absorbs the extraneous radiation over the measured
wave length region.
* * * * *
![[Top]](/netaicon/PTO/top.gif)