![[US Patent & Trademark Office, Patent Full Text and Image Database]](United States Patent 5,240,643_files/patfthdr.gif)
![[Home]](United States Patent 5,240,643_files/home.gif)
![[Boolean Search]](United States Patent 5,240,643_files/boolean.gif)
![[Manual Search]](United States Patent 5,240,643_files/manual.gif)
![[Number Search]](United States Patent 5,240,643_files/number.gif)
![[Help]](United States Patent 5,240,643_files/help.gif)
![[HIT_LIST]](United States Patent 5,240,643_files/hitlist.gif)
![[Bottom]](United States Patent 5,240,643_files/bottom.gif)
![[View Shopping Cart]](United States Patent 5,240,643_files/cart.gif)
![[Add to Shopping Cart]](United States Patent 5,240,643_files/order.gif)
![[Image]](United States Patent 5,240,643_files/image.gif)
| United States Patent |
5,240,643 |
| Buckley , et al. |
August 31, 1993 |
Strain sensing composites
Abstract
This invention comprises the use of diacetylene-containing polymers, e.g.,
olyamides containing reactive diacetylene groups that change their absorption in
the visible spectrum with the application of strain as a strain sensing device
in various organic matrix composites such as an epoxy laminated composite. The
built in sensors in accordance with this invention will not affect the
mechanical performance of the composite and will indicate strain without the
need for extensive electronic equipment to measure the light pulse amplitude or
phase before and after strain.
| Inventors: |
Buckley; Leonard J. (Doylestown, PA);
Neumeister; Gary C. (Blue Bell, PA) |
| Assignee: |
The United States of America as represented
by the Secretary of the Navy (Washington, DC) |
| Appl. No.: |
852618 |
| Filed: |
March 11, 1992 |
| Current U.S. Class: |
252/408.1; 385/12; 385/13;
385/141 |
| Intern'l Class: |
G01L 001/24 |
| Field of Search: |
385/13,12,141 252/408.1
|
References Cited [Referenced
By]
U.S. Patent Documents
| 4515429 |
May., 1985 |
Smith et al. |
385/4. |
| 4788151 |
Nov., 1988 |
Preziosi et al. |
252/408. |
| 4789637 |
Dec., 1988 |
Preziosi et al. |
252/408. |
| 4849500 |
Jul., 1989 |
Rubner |
385/12. |
| 4875759 |
Oct., 1989 |
Ogawa |
385/141. |
| 4916211 |
Apr., 1990 |
Rubner |
528/480. |
| 5018829 |
May., 1991 |
Ogawa |
385/141. |
| 5085801 |
Feb., 1992 |
Thierry et al. |
252/408. |
| 5094527 |
May., 1992 |
Martin |
356/32. |
Primary
Examiner: Stoll; Robert L.
Assistant Examiner: Fee; Valerie
Attorney, Agent or Firm: Tura; James V., Bechtel; James B., Verona;
Susan E.
Goverment Interests
STATEMENT OF GOVERNMENT INTEREST
The invention described herein
may be manufactured and used by or for the Government of the United States of
America for governmental purposes without the payment of any royalties thereon
or therefor.
Claims
The invention claimed:
1. A strain-sensing device comprising an
effective amount of a strain-sensing polymer coated or cladded on a fiber optic
embedded in an organic matrix composite to detect strain; said strain-sensing
polymer consisting essentially of a diacetylene-containing polymer capable of
changing absorption in the visible spectrum while under strain.
2. The
strain-sensing composite of claim 1 wherein the diacetylene-containing polymer
is a copolymer of diacetylene.
3. The strain-sensing composite of claim
1 wherein the diacetylene-containing polymer is a diacetylene-containing
polyamide.
4. The strain-sensing composite of claim 1 wherein the
strain-sensing polymer is a polyamide-diacetylene polymer cladded on optical
fibers embedded in an epoxy matrix.
5. A method of detecting strain in
an organic matrix composite which comprises incorporating in said composite a
strain detecting amount of a strain-sensing polymer; said strain-sensing polymer
consisting essentially of diacetylene-containing polymers capable of changing
absorption in the visible spectrum while under strain.
6. The method of
claim 5 wherein the diacetylene-containing polymer is cladded on optical fibers.
7. The method of claim 5 wherein the diacetylene-containing polymer is a
copolymer of diacetylene.
8. The method of claim 5 wherein the
diacetylene-containing polymer is a polyamide-diacetylene.
9. The method
of claim 5 wherein the strain on the organic matrix composite is detected with a
strain gauge.
Description
BACKGROUND OF THE INVENTION
This invention relates to a strain
sensing device and more specifically to optically-active polymer clad fiber
optics embedded in an organic matrix or organic matrix composite such as an
epoxy composite. The strain sensing polymer-containing device consist
essentially of diacetylene-containing polymers such as the diacetylene
polyamides in combination with fiber optics capable of changing absorption in
the visible spectrum while under strain. It is beneficial to have means for
nondestructively evaluating strain resulting from the deformation of composites,
e.g., fiber/epoxy laminates, in various structures and particularly in aerospace
structures. Early warnings of excessive strain that might cause failure in
flexible structures have many advantages.
There is now a growing
interest in the area of sensor technology regarding the use of optical fibers as
sensors to detect strain, pressure, temperature, etc.; see the Journal of
Quantum Electronics, Volume QE-18, 1986. One means of measuring strain in
composites using embedded optical fibers is disclosed by Claus et al., SPIE
International Symposium, Volume 566, 1985. Here the work demonstrated the
feasibility of an optical fiber interferometric strain measurement wherein the
optical fibers were embedded in a composite laminate before the laminate was
fabricated. The strain measurements were conducted to demonstrate that the
system was functional and that there was reasonable correlation between the
strain measured by the system and theoretical predictions. Further, the
increased demand for strong flexible and light weight materials for the
fabrication of various aircraft parts has driven the development of polymer
based composites. These composites are useful as components of large structures,
particularly aerospace structures. Thus, a nondestructive evaluation method is
needed to determine the component's integrity not only during the manufacturing
process but ultimately in the end use of the components. Moreover, because of
the tremendous size of aerospace components, the nondestructive evaluation
technique must be capable of characterizing a large surface area of the
component.
In this regard, the prior art has considered embedding
optical and acoustical wave guides as sensors for such large scale components.
The acoustic wave guides have cross-sectional dimensions which are larger but
still comparable with graphite fibers in an epoxy composite. Here the fibers may
be embedded in the composite during the manufacturing process without changing
the structure of the composite. These sensors provide there own mechanism for
signal transfer and due to the potential dielectric nature of acoustic and
optical wave link, the dielectric composition of the composite can be
maintained. However, it should be noted that the diacetylene coated fiber
sensors in accordance with this invention exhibit additional advantages over the
acoustic sensors, particularly for large scale testing in that, for example,
optical fiber attenuation for unit length is far less than that of acoustic
rods.
In a graphite epoxy composite, e.g., the fiber bundle orientation
from layer to layer alternates in order to give the material strength in several
inplane directions. The spaces between the fibers in the bundles and between the
bundles and between the layers in the composite are completly filled with the
epoxy resin. The strain transfer from the material to the fiber depends also
upon the mechanical properties of the fiber jacket. Although there has been much
work done to identify jacketing materials having elastic constants to enhance
the fiber pressure sensitivity, there has been little work done to determine the
trade off between such enhancement and the effect of the jacket on the
mechanical properties of the composite. The prior art also has embedded both
bare optical fibers in a single pass straight length and polymer coated fibers
in back and forth serpentine patterns between adjacent parallel, perpendicular
and oriented composites; see the Journal of Nondestructive Evaluation 41,106
(1983) by R. O. Claus et al. Here the experiments used optical time domain
reflectometry (OTDR) which required extensive electronic equipment to launch an
optical pulse and to detect the pulse in the fiber. The amplitude of a pulse
before and after the deformation are compared and then related to the strain.
Other studies relied on the phase change as in relationship to the strain
through a Mach-Zehnder Interferometric Measurement; see Journal of Composite
Technology and Research 10,1 (1988).
SUMMARY OF THE INVENTION
In
accordance with this invention, polymers derived from diacetylene, i.e.,
diacetylene-containing polymers such as the diacetylene-amides, that change
their absorption in the visible spectrum upon the application of strain are used
in combination with optical fibers as a strain-sensing device in an organic
matrix composite such as graphite/epoxy composites. The embedded polymeric
sensor will not affect the mechanical performance of the composite and will show
strain without the need for extensive electronic equipment for the measurement
of light pulse amplitude or phase before and after strain. The incorporation of
the diacetylene-containing polymers as a cladding or coating on optical fibers
is essential to the operation of an in-situ sensor. The equipment needed for the
measurement consist essentially of a visible light source and a
spectroradiometer. This can be coupled to any fiber of fiber optic network
located in a specific critical area of the composite. The advantage of this
invention consist essentially of using the change in the absorption or
transmission behavior with strain as the signal in comparison to a change in
phase or amplitude which is more difficult to monitor. This approach does not
require the use of a laser or extensive electronic equipment for the detection
and interpretation of the signal.
Accordingly, it is an object of this
invention to provide a strain-sensing composite comprising
diacetylene-containing polymers capable of changing absorption in the visible
spectrum while under strain. It is a further object of this invention to provide
diacetylene-containing polymers coated or cladded onto optical fibers imbedded
in an organic matrix composite.
These and other objects will become
apparent from a further and more detailed description of the invention as
follows:
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows fibers
of a diacetylene-containing polymer as a cladding on optical fibers in a
laminate as an in-situ sensor.
FIG. 2 shows the percent of transmittance
versus the wavelength of a diacetylene-containing polymer as a cladding on the
fiber optic embedded in a composite before and after 1.0% strain.
FIG. 3
shows the percent of transmittance versus the wavelength of a
diacetylene-containing polymer as a cladding on the fiber optic embedded in a
composite before and after 0.8% strain.
DETAILED DESCRIPTION OF THE
PREFERRED EMDODIMENT
More specifically, this invention comprises the use
of diacetylene-containing polymers, e.g. polyamides containing reactive
diacetylene groups that change their absorption in the visible spectrum with the
application of strain as a strain sensing article in various organic matrix
composites such as an epoxy laminated composite. The built in sensors in
accordance with this invention will not affect the mechanical performance of the
composite and will indicate strain without the need for extensive electronic
equipment to measure the light pulse amplitude or phase before and after strain.
The diacetylene-containing polymers are incorporated in the organic matrix as a
cladding on optical fibers in a laminated composite in an amount sufficient to
operate as an in-situ sensor.
The term fiber includes a single optical
fiber with the diacetylene-containing polymer in place as the cladding. The
various organic matrices that may be used for embedding optical fibers
containing the diacetylene-containing polymers include well known matrices of
organic composites or laminates, such as the epoxies, polyamides, polyimides,
polyamide-imides, polyurethanes, bismaleimides, polyphenylene sulfides,
polyetheretherketones, and various combinations of polymers. These polymers are
known to be useful in the preparation of composites and/or laminates in the
fabrication of structural parts, and particularly the fabrication of structural
parts in aircraft and alike.
For purposes of this invention,
diacetylene-containing polymers include various segmented copolymers containing
a reactive diacetylene unit in one of the segments. One type of diacetylene
segmented copolymers are prepared by using urethane chemistry as taught by
Miller et al.; see Macromolecules, 18, 1985, the disclosures of which is hereby
incorporated by reference. Here, the first step of a two-step solution
polymerization technique uses urethane chemistry, e.g., a hydroxyl or carboxyl
terminated prepolymer is end-capped with isocyanate groups. The second step is a
step-wise reaction of the isocyanate groups with a diol or a diacid which in
this case must contain a diacetylene functionality within the molecule. This
chain extension step increases the molecular weight of the polymer as the
urethane or amide linages join the molecules together. The preferred
diisocyanates include 4,4'-methylene bis (phenylisocyanate) (MDI) and
hexamethylene diisocyanate (HDI). The preferred diacetylene diols include
2,4-hexadiyne 1,6 diol; 5,7-dodecadiyne 1,12 diol and
10,12-docosadiyne-1,22-diol, etc.
These polyurethane-diacetylene
elastomers are soluble in organic solvents, such as toluene and tetrahydrofuran,
etc. Upon exposure to UV radiation or thermal energy, the elastomers are
converted into polydiacetylene network polymers as evidenced by the dramatic
color change which occurs as the conjugated backbone of the polydiacetylene is
formed. These polyurethane-diacetylene elastomers are not the only segmented
copolymers that would be expected to exhibit these novel properties. This
becomes evident after examining the structure and properties of different
prepolymers and diacetylene monomers which can be utilzied in the synthesis of
the segmented copolymers.
Particularly preferred diacetylene-containing
polymers include the polyamide-containing diacetylene groups as part of the
repeating polymeric structure. It is known that the reactive diacetylene group
can be readily incorporated into many different polymeric structures making it
possible to synthesize a variety of fiber and film-forming polymers with tunable
mechanical and optical properties. This chemistry provides a means of
introducing well defined nonrandom cross links into a polymer without disruption
of the packing and order of the polymeric chain. Moreover, since the resulting
cross links are actually conjugated polydiacetylene chains, the material
developed all of the novel optical properties characteristic of the
polydiacetylenes such as nonlinear optical behavior, etc. In the case of
polyamides, it is possible to systematically vary the nature of the polymer
chain from flexible to semiflexible to rigid by controlling the length of the
spacer groups separating the diacetylene functionality from the amide linkage
and the type of diamide, i.e., aromatic or aliphatic, used to synthesize the
polymer.
The diacetylene-containing polyamides are prepared by
condensation wherein a diacid chloride is reacted with hexanediamine to form an
aliphatic polyamide-diacetylene (PADA6,22) and with 1,4 phenylenediamine to form
a partially aromatic polyamide-diacetylene. The reactive diacetylene groups
contained along the backbone of the polyamides may be activated by UV radiation
or by ionizing radiation to give a network structure in which the newly fromed
crosslinks are actually conjugated polydiacetylene chains. Knowledge of the
extent of diacetylene conversion to polydiacetylene chains is important to
understand how this chemistry influences the final properties of these
materials.
In the polyamide-diacetylene polymers, the sidegroups are
actually segments of a polymer chain containing two amide hydrogen bonds per
segment. This results in a sidegroup organization that is much less flexible or
"entropically active" than the urethane substituted polydiacetylenes synthesized
from diacetylene monomers. The amide hydrogen bonds serve as anchors that hold
the sidegroups in place thereby preventing complete disordering at elevated
temperatures and insuring reversible behavior. Once a significant portion of the
hydrogen bonds have been broken as would occur with extensive disordering, the
reversibility of the thermochromic transition becomes highly compromised. In
this light, the higher temperature capabilities of the aromatic-based polyamide
can be seen as a direct consequency of the decreased sidegroup mobility brought
about by the incorporation of a rigid phenyl ring in the sidegroup. A detailed
discussion regarding the polyamide-containing diacetylene polymers is available
by Rubner et al., Macromolecules, 22, 2130, 1989.
It is obvious that
there are other variations and modifications which can be made without departing
from the spirit and scope of the invention as particularly set forth in the
appendant claims.
* * * * *
![[Top]](United States Patent 5,240,643_files/top.gif)