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| United States Patent |
5,639,968 |
| Bobb , et al. |
June 17, 1997 |
Optical fiber strain-to-failure sensor
Abstract
A sensor and method are disclosed for determining if a region, defined by two
end points, in a structure has exceeded a predetermined amount of strain. The
sensor has an optical waveguide which has two ends for receiving and emitting
light and which is fixable at two locations thereon to respective ones of the
end points to define a sensing region therebetween. The sensing region has a
first portion with a first length and a first cross-sectional area, and a second
portion with a second length and a second cross-sectional area which is smaller
than the first cross-sectional area. The lengths and cross-sectional areas are
sized so that the optical waveguide has a strain failure point equal to the
predetermined amount of strain. The lengths and cross-sectional areas are
approximately sized according to the formula R=.alpha.+1/ (.alpha./.beta.+1),
wherein R=the ratio of the amount of strain in the second portion which will
cause the optical waveguide to fail to the predetermined amount of strain in the
structure, .alpha.=the ratio of the length of the first portion to the length of
the second portion, and .beta.=the ratio of the cross-sectional area of the
first portion to the cross-sectional area of the second portion.
| Inventors: |
Bobb; Lloyd C. (Horsham, PA);
Krumboltz; Howard D. (Chalfont, PA) |
| Assignee: |
The United States of America as represented
by the Secretary of the Navy (Washington, DC) |
| Appl. No.: |
546974 |
| Filed: |
October 23, 1995 |
| Current U.S. Class: |
73/800; 73/760 |
| Intern'l Class: |
G02B 006/02 |
| Field of Search: |
73/800,760 385/28
|
References Cited [Referenced
By]
U.S. Patent Documents
| 4475812 |
Oct., 1984 |
Buczek et al. |
73/800. |
| 4636638 |
Jan., 1987 |
Huang et al. |
250/231. |
| 4761073 |
Aug., 1988 |
Meltz et al. |
356/32. |
| 4836030 |
Jun., 1989 |
Martin |
73/800. |
| 5222165 |
Jun., 1993 |
Bohlinger |
73/800. |
| 5461926 |
Oct., 1995 |
Bobb et al. |
73/800. |
| 5461927 |
Oct., 1995 |
Bobb et al. |
73/800. |
| Foreign Patent Documents |
| 1485009 |
Jun., 1989 |
SU |
73/800. |
Other References
W.G. Mullen and W.L. Dolch "Periscope-Type Strain Gauge
Measures Creep in mersed Specimens" Materials Research & Standards,
Apr. 1966. |
Primary Examiner: Chilcot;
Richard
Assistant Examiner: Noori; Max H.
Attorney, Agent or
Firm: Verona; Susan E., Billi; Ron
Goverment Interests
STATEMENT OF GOVERNMENT INTEREST
The invention described herein
may be manufactured and used by and for the Government of the United States of
America for governmental purposes without the payment of any royalties thereon
or therefor.
Claims
What is claimed is:
1. A sensor for determining if a region,
defined by two end points, in a structure has exceeded a predetermined amount of
strain along the line through the two end points, comprising:
an optical
waveguide having two ends for receiving and emitting light, fixable at two
locations along the length thereof to respective ones of the end points to
define a sensing region therebetween, the locations on said optical waveguide
being fixed to the two end points on the structure so that said optical
waveguide will be pulled in tension as the strain in the region increases the
distance between the two end points, the sensing region having a first portion
with a first length and a first cross-sectional area, and a second portion with
a second length and a second cross-sectional area which is smaller than the
first cross-sectional area, said lengths and cross-sectional areas being sized
so that said sensing region of said optical waveguide has a strain failure point
equal to the predetermined amount of strain.
2. The sensor according to
claim 1, wherein said first portion comprises two segments and said second
portion is between said two segments of said first portion.
3. The
sensor according to claim 2, wherein said two segments of said first portion are
of equal length.
4. The sensor according to claim 1, wherein said
lengths and cross-sectional areas are approximately sized according to the
formula R=.alpha.+1/(.alpha./.beta.+1), wherein R=the ratio of the amount of
strain in the second portion which will cause said optical waveguide to fail to
the predetermined amount of strain in the structure, .alpha.=the ratio of the
length of the first portion to the length of the second portion, and .beta.=the
ratio of the cross-sectional area of the first portion to the cross-sectional
area of the second portion.
5. A method of determining if a region,
defined by two end points, in a structure has exceeded a predetermined amount of
strain, comprising the steps of:
providing an optical waveguide capable
of transmitting light therethrough and having two ends for receiving and
emitting light therethrough;
selecting two locations on the optical
waveguide whereupon the waveguide will be fixed to respective ones of the two
end points on the structure, which two locations define a sensing region of the
optical waveguide therebetween;
providing the sensing region of the
optical waveguide with a first portion having a first length and a first
cross-sectional area, and a second portion having a second length and a second
cross-sectional area which is smaller than that of the first portion, the
lengths and cross-sectional areas being sized so that when the optical waveguide
is fixed to the structure at the two end points thereon the strain in the
optical waveguide will reach the known strain failure point of the second
portion of the optical waveguide when the structure reaches the predetermined
strain; and
fixing the locations on the optical waveguide to the two end
points on the structure so that the optical waveguide will be pulled in tension
as the strain in the region increases the distance between the two end points.
6. The method according to claim 5, further including the step of
observing whether or not the optical waveguide has failed, as an indication as
to whether the region in the structure has exceeded the predetermined amount of
strain.
7. The method of claim 6, wherein said step of observing whether
or not the optical waveguide has failed includes the step of launching light
into one end of the waveguide and observing that it does not emerge from the
other end thereof.
8. The method according to claim 5, wherein the
lengths and cross-sectional areas are approximately sized according to the
formula R=.alpha.+1/(.alpha./.beta.+1), wherein R=the ratio of the known strain
failure point of the second portion of the optical waveguide to the
predetermined amount of strain in the structure, .alpha.=the ratio of the length
of the first portion to the length of the second portion, and .beta.=the ratio
of the cross-sectional area of the first portion to the cross-sectional area of
the second portion.
9. The method of claim 5, wherein said step of
fixing the locations on the optical waveguide to the two end points on the
structure further includes the step of pretensioning the optical waveguide so
that it is taut when fixed to the structure.
10. The method of claim 5,
wherein said step of fixing the locations on the optical waveguide to the two
end points on the structure further includes the step of applying a UV-cured
epoxy between locations and their respective end points.
11. The method
of claim 5, wherein said step of providing the sensing region of the optical
waveguide with a first portion having a first length and a first cross-sectional
area, and a second portion having a second length and a second cross-sectional
area which is smaller than that of the first portion includes the step of
reducing the cross-sectional area of the provided optical waveguide in the area
thereof which is the second portion.
12. The method of claim 11, wherein
said step of reducing the cross-sectional area of the provided optical waveguide
in the area thereof which is the second portion includes the step of etching
away the outer surface of the optical waveguide until the desired
cross-sectional area of the second portion is achieved.
13. The method
of claim 12, wherein said step of etching includes chemical etching.
14.
The method of claim 12, wherein said step of etching includes plasma etching.
Description
BACKGROUND OF THE INVENTION
The present invention relates
generally to a strain sensor and more particularly to an optical fiber
strain-to-failure sensor which can measure small amounts of strain.
Oftentimes it is desirable to determine whether a structure has exceeded
some maximum strain value during a given time frame, as a means of providing a
warning of failure of the structure. For example, it may be desirable to know if
some component in an aircraft has exceeded some predetermined strain value
during a flight.
Optical fiber strain sensors exist which rely on
failure of the optical fiber at the location of strain to indicate the presence
of the strain. In such a sensor, the fiber is attached to the structure so that
when the structure experiences strain the fiber experiences the same amount of
strain. When the structure has reached an amount of strain that is the same as
the fiber's maximum strain capacity, the fiber fails. The failure of the fiber
is detected when light is launched into one end of the fiber and not detected at
the other end. Such sensors have the advantage that they are lightweight and do
not take up much space. Furthermore, they can be embedded in structures like
laminated composites. One problem with sensors of this type is that the amount
of strain which will cause the fiber in such a sensor to fail is variable,
making it difficult to predetermine the maximum strain to an accurate degree.
Additionally, the amount of strain required to break the fiber is too large to
be of interest in many applications. Most optical fibers will not fail until
they have reached a strain level in the range of 20,000 to 30,000 microstrain,
yet structures may fail at strain levels as low as 2000 to 3000 microstrain.
SUMMARY OF THE INVENTION
It is therefore an object of the
present invention to provide an optical fiber strain sensor for detecting that a
region in a structure has exceeded a predetermined small amount of strain.
It is another object of the present invention to provide a strain sensor
for detecting a small amount of strain, which sensor is lightweight and capable
of being embedded within a structure.
It is still another object of the
present invention to provide a method of determining if a region in a structure
has exceeded a predetermined amount of strain.
These and other objects
are accomplished by a sensor and method for determining if a region, defined by
two end points, in a structure has exceeded a predetermined amount of strain.
The sensor has an optical waveguide which has two ends for receiving and
emitting light and which is fixable at two locations thereon to respective ones
of the end points to define a sensing region therebetween. The sensing region
has a first portion with a first length and a first cross-sectional area, and a
second portion with a second length and a second cross-sectional area which is
smaller than the first cross-sectional area. The lengths and cross-sectional
areas are sized so that the optical waveguide has a strain-to-failure point
equal to the predetermined amount of strain. The lengths and cross-sectional
areas are approximately sized according to the formula
R=.alpha.+1/(.alpha./.beta.+1), wherein R=the ratio of the amount of strain in
the second portion which will cause the optical waveguide to fail to the
predetermined amount of strain in the structure, .alpha.=the ratio of the length
of the first portion to the length of the second portion, and .beta.=the ratio
of the cross-sectional area of the first portion to the cross-sectional area of
the second portion.
The method includes first providing an optical
waveguide capable of transmitting light therethrough and having two ends for
receiving and emitting light therethrough, and having a known strain-to-failure
point. Two locations on the optical waveguide are selected whereupon the
waveguide will be fixed to respective ones of the two end points on the
structure. These two locations define a sensing region of the optical waveguide
therebetween. The sensing region of the optical waveguide is provided with a
first portion having a first length and a first cross-sectional area, and a
second portion having a second length and a second cross-sectional area which is
smaller than that of the first portion, the lengths and cross-sectional areas
being sized so that when the optical waveguide is fixed to the structure at the
two end points thereon the strain in the optical waveguide will reach the known
strain-to-failure point of the optical waveguide when the structure reaches the
predetermined strain. The locations on the optical waveguide are fixed to the
two end points on the structure so that the optical waveguide will be pulled in
tension as the strain in the region increases the distance between the two end
points. One then observes whether or not the optical waveguide has failed, as an
indication as to whether the region in the structure has exceeded the
predetermined amount of strain.
Other objects, advantages, and novel
features of the invention will become apparent from the following detailed
description of the invention when considered in conjunction with the
accompanying drawing.
BRIEF DESCRIPTION OF THE DRAWINGS
The
FIGURE is a diagrammatic view of an optical fiber strain-to-failure sensor
according to the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring now to the drawing, one sees an optical fiber
strain-to-failure sensor 10 according to the invention positioned to detect when
the strain in a structure 12 in a region thereon defined by two end points X and
X' has exceeded a predetermined amount. Strain sensor 10 has an optical
waveguide 14, such as a multimode optical fiber capable of transmitting light
therethrough, which is fixed to end points X and X' at two locations Z and Z',
respectively, on the outer surface thereof. The distance between locations Z and
Z' defines a sensing region 16 of sensor 10. Optical waveguide 14 extends beyond
locations Z and Z' and has two ends 18 and 18' which can receive and emit light
therethrough. Strain in structure 12 causes strain in waveguide 14, which fails
when the strain in the structure reaches the predetermined maximum value
.epsilon..sub.s. Failure of waveguide 14 is determined by launching light into
one end 18 of the waveguide and observing that it does not emerge from the other
end 18'.
Waveguide 14 fails when structure 12 reaches the predetermined
maximum value .epsilon..sub.s because sensing region 16 has two portions,
distinguished by particular lengths and cross-sectional areas. A first portion
20 has a first length L.sub.1 and a first cross-sectional area A.sub.1, and a
second portion 22 has a second length L.sub.2 and a second cross-sectional area
A.sub.2 which is smaller than the cross-sectional area A.sub.1 of first portion
20. Portions 20 and 22 may be broken into discontinuous segments, separated by
segments of the other portion. For instance, as shown in the FIGURE, first
portion 20 may be broken into two segments of equal length L.sub.1 /2, with
second portion 22 being between the two segments of the first portion.
L.sub.1, L.sub.2, A.sub.1, and A.sub.2 are approximately sized according
to the formula R=.alpha.+1/(.alpha./.beta.+1), wherein:
.alpha.=L.sub.1
/L.sub.2 ;
.alpha.=A.sub.1 /A.sub.2 ; and
R=.epsilon..sub.2
/.epsilon..sub.s, wherein:
.epsilon..sub.s =the predetermined amount of
strain in the structure; and
.epsilon..sub.2 =the amount of strain in
the second portion which will cause the optical waveguide to fail.
The
value of strain that will cause the optical waveguide to fail, .epsilon..sub.2,
can be determined experimentally, and is the same at any point along the length
of the waveguide, regardless of the cross-sectional area at that point.
To size the lengths and cross-sectional areas, first the desired maximum
strain in the structure, .epsilon..sub.s, which is to be detected must be
determined. Then the amount of strain which will cause waveguide 14 to break (in
second portion 22), .epsilon..sub.2, must be determined. The ratio of these two
values, R, is plugged into the above equation to determine the other values as
indicated. For example, if it is determined that waveguide 14 will fail in
second portion 22 when the strain therein is ten times the predetermined amount
of maximum desirable strain in the structure, then L.sub.1 could be ten times
L.sub.2, and A.sub.1 could be one hundred times A.sub.2. In this situation, when
structure 12 experiences strain, second portion 22 experiences ten times that
amount of strain, and when the structure reaches the predetermined amount of
maximum desirable strain, second portion 22 will fail.
For convenience,
the cross-sectional area A.sub.1 of first portion 20 should typically be the
same as that of a standard optical waveguide. In other words, whatever optical
waveguide is used in sensor 10, the cross-sectional area thereof is used as the
cross-sectional area A.sub.1 of first portion 20. Second portion 22 may then be
formed by reducing the cross-sectional area of waveguide 14 where second portion
22 is to be. This reduction may be accomplished by chemical etching, plasma
etching, or ion milling. The cross-sectional area can also be reduced by heating
waveguide 14 along a length thereof which is smaller than the eventual length of
second portion 22 while applying tension thereto. The minimum size of A.sub.2 is
limited by the ability of the waveguide to transmit light therethrough. As long
as light can still pass through second portion 22, A.sub.2 is not too small. Of
course, if it is desirable that A.sub.1 be less than the cross-sectional area of
the waveguide provided, it can be reduced by etching or ion milling as well.
Waveguide 14 is attached to structure 12 at respective points and
locations by any adhesive 24 and 24' which will adhere to both the waveguide and
the structure, and which will not change much dimensionally when cured. An
example of an appropriate adhesive is UV-cured epoxy. Sensing region 16 of
waveguide 14 should preferably be pretensioned and attached to structure 12 so
that any strain experienced by the structure is also experienced by the sensing
region. Alternatively, sensing region 16 can have a known amount of slack
therein, increasing the amount of strain structure 12 can experience before
breaking waveguide 14. The equation should be adjusted accordingly.
Some
of the many features and advantages of the present invention should now be
readily apparent. For instance, an optical fiber strain-to-failure sensor has
been provided for detecting that a region in a structure has exceeded a
predetermined small amount of strain. The sensor is lightweight and capable of
being embedded within a structure. Furthermore, a method of determining if a
region in a structure has exceeded a predetermined small amount of strain has
been provided.
Other embodiments and modifications of the present
invention may readily come to those of ordinary skill in the art having the
benefit of the teachings of the foregoing description. Therefore, it is to be
understood that the present invention is not to be limited to the teachings
presented and that such further embodiments and modifications are intended to be
included in the scope of the appended claims.
* * * * *
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