DTS0115 Fiber Optic Distributed Strain And Temperature Sensors (DSTS) BOTDA Module Ci 1100
User Manual: Ci 1100
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Fiber Optic Distributed Strain and
Temperature Sensors (DSTS)
BOTDA Module
For more information about
our strain and temperature
sensor system and related
products, please visit
www.ozoptics.com
Photo: 3U chassis and
laptop computer shown.
Features
Product Description
• Uses standard telecom single mode fibers for
strain and / or temperature measurement
• Real-time measurement of strain and temperature
• High spatial resolution, strain, and temperature
resolution and accuracy
• DLL available for system integrator
OZ Optics’ Foresight™ series of fiber optic Distributed Strain and
Temperature Sensors (DSTS) BOTDA modules are sophisticated sensor
systems using stimulated Brillouin scattering in optical fibers to measure
changes in both strain and temperature along the length of an optical fiber. By
deploying a sensing cable that includes standard telecom single mode fiber,
users can detect when and where the strain or the temperature of the object
has changed and correct potential problems before failure occurs.
Performance at a glance
A unique feature of our Foresight™ DSTS system is its ability to measure
temperature and strain, simultaneously and independently, allowing regions
of temperature induced strain to be identified.
• As low as 0.1 m spatial resolution
• Max. 100 km sensing range with max. 160 km fiber
length
DTS0115
OZ Optics reserves the right to change any specifications without prior notice.
3 January 2018
1
Oil and Gas applications
Oil and Gas Well Monitoring
Oil and Gas Pipeline Monitoring
• Pipeline leakage monitoring
• Up to 100 km sensing range per channel
• High spatial resolution supports localized measurement
with long sensing range
• Short acquisition / response time
• Well integrity management
• Temperature, strain and pressure monitoring with proper
sensing cable and installation
• Not sensitive to hydrogen which may change the
attenuation of the fiber
Refinery Efficiency Sensing
• Improve the efficiency of the refinery per distributed
temperature profile
• Reduce downtime while ensuring safety levels
• Uses low cost telecom single mode fiber cable
Civil Engineering applications
Dam Monitoring
• Dam internal temperature monitoring
• Crack / sediment / deformation / seepage monitoring
• Up to 100 km sensing range per channel
Structural Health Monitoring (SHM)
•
•
•
•
Sediment monitoring
Strain and crack monitoring
Up to 100 km sensing range per channel
High spatial resolution supports localized measurement
with long range object
2
Civil Engineering applications continued
Geohazard Monitoring
• Landslide, subsidence and deformation of levee /
ground / highway monitoring
• Can monitor trends in ground movement
• Up to 100 km sensing range per channel
Highway Safety Monitoring
• Internal temperature / strain monitoring with proper
sensing cable and installation
• Highway subsidence monitoring
• Distributed temperature / strain data along the fiber
length up to 100 km
Utility and Cable applications
Overhead Power Line Monitoring
• Lightning strikes, icing and broken wires can be detected
• Up to 100 km sensing range per channel
• No additional components required along power line
route
• Easy deployment
Submarine Cable Monitoring
• Ongoing quality / status monitoring throughout the life
of the cable
• No additional components required along the route
Quality Inspection of Fiber Optic Cable
• More sensitive to strain than OTDR
• High level quality control based on high level technology
• Can monitor the quality of power cable / OPGW with
optical fiber unit
3
Security, Cryostat, and Fire applications
Cryostat Temperature Sensing
Border Security Monitoring
• Fast, dynamic measurement
• High precision of event location
• Can be used in conjunction with video surveillance
system
•
•
•
•
Able to measure temperatures as low as 25 K
May use low cost telecom single mode fiber
Up to 100 km sensing range per channel
High spatial resolution with good temperature resolution
/ precision
Building Fire Detection
• Fast, dynamic, and accurate temperature measurement
• Up to 100 km sensing range per channel
• May use low cost telecom single mode fiber cable
4
Specifications
Description
Parameter
Spatial Resolution
Dynamic Range
2 to 25
1
160 km
Sensing Range
100 km
Spatial Accuracy
as low as 5 cm
as low as 5 cm
Performance
Strain Range
-270°C to +2100°C (depending on cable material)
-3% (compression) to +4% (elongation) (depending on cable material)
Temperature Resolution
Temperature Accuracy (2σ)
Strain Resolution
0.005°C2
± 0.1°C (Whole sensing range for BOTDA)
0.1 µε2
Strain Accuracy (2σ)
Acquisition Time (full scan)
Averaging
± 2 µε (Whole sensing range for BOTDA)
as low as 1 second
1 to 60,000 scans
Fault Point
Detection
Acquisition Time
Sensing Range (round trip)
100 km
Simultaneous
Measurement
of Strain and
Temperature
(using patented
cable design)
Temperature Resolution
0.005°C2
Temperature Accuracy (2σ)
Strain Resolution
Strain Accuracy (2σ)
Sensing Range
Measured Variables
Communication & Connections
Output Signals
1 second per thousand scans
± 0.1°C (Whole sensing range for BOTDA)
0.1 µε2
± 2 µε (Whole sensing range for BOTDA)
50 km
Strain and/or temperature, Brillouin spectrum
Ethernet port, USB
Software alarms via TCP/IP, SPST, SSR relays (optional)
Data Storage
Internal hard disc (128GB or more)
Data Format
Database, text files, MS Excel, bitmap plot
General
Optical Connections
Laser Wavelength
0°C to 40°C, <85% RH, Non-condensing
115 or 230 VAC; 50–60Hz; max 300W
Dimensions
(L x W x H)
3U Chassis
Weight
3U Chassis
Measurement Modes
Features
Data Analysis
Alarm & Warnings
Remote Operation
Watch Dog
FC/APC3
1550 nm band
Operating Temperature
Power Supply
4
25 dB
Fiber Loop, BOTDA+BOTDR combo unit is optional
Temperature Range
3
0.1 m to 50 m
30 dB
Sensor Configuration
Spatial Step
2
0.5 m to 50 m
30 dB
Number of Channels
Maximum Fiber Length
1
1 m to 50 m
390 x 344 x 133 mm (Not including computer)4
<12 kg (Not including computer)
Manual, remote or automatic unattended measurement
Measurement analysis, Multiple trace comparison with respect to selectable baseline,
Measurement trends, Graphical zoom
Automatic alarm triggering, configurable alarm settings (gradient, threshold, etc.)
Remote control, configuration and maintenance via TCP/IP
Long term operation 24/7 guaranteed by automatic recovery and continuous self diagnostics
2 channels or 4 channels are provided within the sensor unit. Additional channels can be added by using an external optical switch.
This value is estimated/calculated from the uncertainty of laser beat frequency, 5 kHz, and temperature and strain coefficients of fibers.
Adaptors and patch cords are available for mating with other types of optical connectors.
Dimensions do not include carrying handle. Air vents on sides of unit must not be obstructed.
5
Related Products
Fiber Optic Sensor Probes, Components, Termination Kits, and Training
OZ Optics offers a full spectrum of fiber optic sensor probes, components, termination kits and training. OZ Optics' standard fiber optic products
have been used worldwide in high performance sensor and telecommunications applications since 1985. OZ Optics also offers specialty fiber
optic sensor probes and custom cabling for high temperature applications and other hostile and corrosive environments. System integrators with
experience in structural and pipeline monitoring will find that OZ Optics offers a complete suite of enabling products and services for installing
and maintaining fiber optic systems. If you are planning a pipeline or structural monitoring project, please contact OZ Optics to learn more about
our fiber optic solutions.
For more information about our strain and temperature sensor system and related products, please visit www.ozoptics.com.
Ordering Information
Part Number Description:
DSTS-CT CO I-SR-MSR-AS-BOTDA-X-CH
CT = Chassis Type of DSTS
opto-electronics box
3U = 3U chassis
CO = Computer Type
L = Laptop (requires 3U chassis)
R1U = 1U computer
X = Customer supplier computer
I=
Internal Interface between DAQ and
computer
T = Thunderbolt (requires 3U chassis)
S = Standard
SR = Spatial Resolution (m)1
0.1/10
0.1/50
0.5/10
For a field ready unit, replace the chassis type, computer type,
0.5/50
1/10
and computer interface with a single letter “F.” Field ready units
1/50
include a built-in computer, monitor, keyboard and mouse.
CH =
Number of channels
2CH = 2 built-in channels
4CH = 4 built-in channels
X=
Connector Type
3A = FC/APC
AS =
Acquisition Speed3
N = Normal
H = High Speed
MSR = Maximum Sensing Range (km)1,2
60
1/60
5/60
100
1/100
5/100
Notes:
1. Each DSTS can be configured for short haul operation, long haul operation or both. The configuration must be specified at the time of
purchase. The spatial resolution indicates the best resolution at the maximum sensing range. If the DSTS is configured for both short-haul
and long-haul measurements then two numbers will be listed indicating the resolutions and maximum sensing range for each operating
mode. For example, suppose the DSTS unit needs to achieve 0.1 meter resolution over a 1 km range for short-haul applications, and
50 meter resolution over a 100 km range for long-haul applications. The part number will specify the spatial resolution (SR) as 0.1/50, and
maximum sensing range (MSR) as 1/100.
2. Maximum sensing range is 60 km or 100 km for long haul operation. Alternately, if the 0.1 m spatial resolution is chosen, a maximum sensing
range of 1 km is displayed for that resolution (for short haul operation). Maximum sensing range is described as 60, 1/60, 5/60, 100, 1/100,
or 5/100.
3. The acquisition speed is described as normal or high speed. N and H are used respectively. The high-speed version is typically at least a
factor of two faster than the normal-speed version during the acquisition of data.
3U model with laptop computer
The 3U version of the DSTS comes with removable
carrying handles. The user can easily replace the
handles with tabs (sold separately) that will allow the
unit to be installed in a standard 19-inch rack.
Field-ready model
A field-ready model is optional for our customers.
Please contact OZ Optics for detailed information.
6
Optional Accessories
Bar Code
Part Number
Description
DSTS-TRAVEL-CASE-1U/3U
Optional aluminum carrying case for DSTS. Includes wheels and handle. Designed for
checking on airplane. Approximate dimensions: 23.75 (H) x 22.5 (W) x 15 (D). {60.3 cm x
57.2 cm x 38.1 cm}.
48979
CI-1100-A2
Handheld Video Microscope kit for Fiber Optic Connector Inspection. The kit includes a
3.5” TFT LCD display with video probe. An ac power adapter with battery charger and a
rechargeable battery pack. It also includes one SC/FC PC female connector, one LC/PC
female connector, one Universal 2.5 mm FC/PC male connector and one Universal 1.25 mm
FC/PC male connector.
48980
CI-1100-A2-PT2-FS/APC/F
Tip for SC and FC APC type female (in receptacle) connector for CI-1100-A2 handheld
microscope.
36939
HUXCLEANER-2.5
Receptacle fiber cleaner for FC, SC and ST type.
5336
Fiber-Connector-Cleaner-SA
Disposable Cletop reel type A optical fiber connector cleaner.
8122
SMJ-3A3A-1300/1550-9/125-3-1
1 meter long, 3 mm OD jacketed, 1300/1550 nm 9/125 µ Corning SMF 28e fiber patchcord,
terminated with angled FC/APC connectors on both ends.
48298
40536
1 meter long, 3 mm OD PVC cabled, 9/125 um 1300/1550 nm SM fiber patch cord,
SMJ-3AEA-1300/1550-9/125-3-1 terminated with an angled FC/APC connector on one end and an angled E2000 connector
on the other end.
PMPC-03
Flanged sleeve thru connector for polarization maintaining FC/PC connectors. Keyway width
is 2.03/2.07 mm wide for 2.00 mm wide (Type R) key connectors.
19711
AA-200-11-9/125-3A3A
Universal connector with a male angle FC/APC connector at the input and a female angle
FC/APC receptacle at the output end for SM 9/125 applications.
58975
DSTS-3U-19IN-RACK-MOUNT-KIT
Brackets with handles & hardware to convert 3U DSTS to 19" rack mountable version.
11
Software Interface
For users who want to develop their own application software for monitoring strain and / or temperature, OZ Optics provides a Dynamic Link
Library (DLL) of routines for controlling the DSTS. Contact OZ Optics for additional information.
Optical Connections
The biggest problem that customers encounter is when they fail to properly clean the optical connectors before mating them to a sensor system.
As a result of this, fiber end-faces can be damaged, which degrades performance. This may result in a costly repair. For this reason, a buffer
patch cord or adaptor should ALWAYS be used between the DSTS and the sensing fiber. Connections should always be made to this patch cord
or adaptor, while the patch cord remains attached to the DSTS at all times. The patch cord should only be removed from the DSTS if it becomes
damaged and needs to be replaced. Following this procedure helps to ensure trouble-free operation of the sensor.
In addition, connectors and receptacles must always be properly cleaned prior to mating. Damage to the end-face of the fiber in the
receptacle on the front panel of the DSTS is not covered by the warranty. Buffer patch cords or adaptors (with spares) are provided with
each DSTS. Extra patch cords or adaptors can be purchased separately. Patch cords are available from OZ Optics to mate with any type of
connector. Contact OZ Optics with your specific requirements.
Questionnaire
1. What is your application? Please describe briefly.
6. What is the maximum strain to be measured?
2. Are you looking for a BOTDA module (requires both ends
of fiber to be connected to DSTS) or a BOTDR module
(requires only one end of fiber to be connected to DSTS) or
a COMBO unit with both BOTDA and BOTDR functions?
7. What is the desired sensing range or fiber length in this
application?
3. What are your resolution and precision requirements for
temperature measurements?
Resolution: _____________________________________
Precision: ______________________________________
4. What are the highest and lowest temperatures you expect?
8. What spatial resolution do you desire?
9. Do you want to measure temperature, strain or both?
10. What is the desired data acquisition time?
11. Do you need fiber calibration / system design / project
engineering service?
12. Where will the unit be housed?
13. Any additional information?
5. What are your resolution and precision requirements for
strain measurements?
Resolution: _____________________________________
Precision: ______________________________________
7
Applications of Fiber Optic Distributed Strain and Temperature Sensors
Executive Summary
Fiber optic distributed strain and temperature sensors measure strain and temperature over very long distances and are an excellent tool for
monitoring the health of large structures. These sensors leverage the huge economies of scale in optical telecommunications to provide highresolution long-range monitoring at a cost per kilometer that cannot be matched with any other technology. Today's distributed strain and
temperature sensors offer clear cost and technical advantages in applications such as pipeline monitoring, bridge monitoring, dam monitoring,
power line monitoring, and border security / perimeter monitoring. Brillouin sensors are also excellent for the detection of corrosion in large
structures.
Working Principle
Although a detailed understanding of Brillouin sensors is not required when using OZ Optics sensor systems in typical structural health
monitoring applications, a description of the basic measurement will be useful to users who want a better understanding of the specification
tradeoffs when selecting a sensor system solution.
The most common type of Brillouin strain and temperature sensor uses a phenomenon known as stimulated Brillouin scattering. The
measurement is illustrated in the figure below:
Brillouin Sensor – Principle of Operation
Brillouin Sensor – Principle of Operation
Brillouin Scattering
Unstrained
Strained
Optical Fiber
pump
G
probe
B
s
Bs= B0 + CT ( T - T0 ) + Cε ( ε - ε0 )
Figure 1. Brillouin spectral peaks from strained and unstrained fibers.
The typical DSTS BOTDA sensor configuration requires two lasers that are directed in opposite directions through the same loop of fiber (one
laser operating continuously, the other pulsed). When the frequency difference between the two lasers is equal to the "Brillouin frequency" of the
fiber, there is a strong interaction between the 2 laser beams inside the optical fibers and the enhanced acoustic waves (phonons) generated in
the fiber. This interaction causes a strong amplification to the Brillouin signal which can be detected and localized using an OTDR-type sampling
apparatus. To make a strain or temperature measurement along the fiber, it is necessary to map out the Brillouin spectrum by scanning the
frequency difference (or "beat" frequency) of the two laser sources and fitting the peak of the Brillouin spectrum to get the temperature and strain
information.
As the equation at the bottom of Figure 1 shows, the Brillouin frequency at each point in the fiber is linearly related to the temperature and the
strain applied to the fiber. In some optical fibers such as dispersion-shifted fiber, there are actually two peaks in the Brillouin spectrum and it is
possible to extract both temperature and strain information from a single fiber. If one uses the sensor system with our patent pending sensing
fiber, then one can simultaneously measure strain and temperature, while utilizing the same fiber for telecommunications.
A Comparison of Fiber Optic Sensor Technologies for Structural Monitoring
Brillouin fiber optic sensors excel at long distance and large area coverage; in fact, Brillouin sensors should be considered for any strain or
temperature application with total lengths in excess of 10 meters. Another common fiber optic sensor technology appropriate for localized
measurements is known as fiber Bragg grating sensors. However, for structural health monitoring, when the potential damage or leakage
locations are unknown, it is difficult to pre-determine the places to put fiber Bragg grating sensors or other types of point sensors. Fiber Bragg
grating sensors are an excellent localized sensor when the specific area(s) of interest are known. Distributed Brillouin sensors can be used for
much broader coverage and can locate fault points not known prior to sensor installation.
There are two types of Brillouin fiber optic sensors. Brillouin Optical Time Domain Reflectometers (BOTDR) resolve the strain or temperature
based Brillouin scattering of a single pulse. Brillouin Optical Time Domain Analysis (BOTDA) uses a more complicated phenomenon known as
Stimulated Brillouin Scatter (SBS).
For Stokes scattering (including Brillouin scattering and Raman scattering) only a small fraction of light (approximately 1 in 103 photons) is
scattered at optical frequencies different from, and usually lower than, the frequency of the incident photons. Based on BOTDR technology, since
the intensity of a backscattered Brillouin signal is at least 1/103 less than that of the incident light, the Brillouin scattering signal is very weak.
Considering the attenuation of the optical fiber, for example, 0.22 dB/km, the measurement range cannot be very long and the SNR is generally
worse than that found with BOTDA technology. The primary advantage of BOTDR technology is that only one end of the fiber needs to be
accessible.
8
The BOTDA technique is significantly more powerful as it uses enhanced Brillouin scattering through two counter-propagating beams. Due to
the strong signal strength the strain and temperature measurements are more accurate and the measuring range is longer than that of BOTDR
technology. In addition, our patented sensing method allows one to determine simultaneous strain and temperature information.
The BOTDA method requires more optical components and a 2-way optical path so the total system cost is typically higher (the sensor fiber must
be looped or mirrored). However, most field units deployed today are BOTDA systems because the additional measurement accuracy more than
justifies the moderate increase in system cost.
OZ Optics' Foresight™ series of DSTS has BOTDA, BOTDR and BOTDA/BOTDR combo units. Our customers can enjoy more choices based
on their special requirements. Table 1 provides a comparison of common fiber optic strain and temperature sensor techniques, along with typical
performance limits for each type:
Bragg Grating*
BOTDR
BOTDA
Strain Accuracy
± 1 µstrain
± 16 µstrain
± 2 µstrain
Spatial Resolution
0.1 m
1m
0.1 m
Length Range
Point sensor
70 km
100 km
Acquisition Time
<1 second
3–20 minutes
As low as 1 second
Configuration
Many fibers
Single fiber
Loop or single fibers
Temperature Accuracy
± 0.4°C
± 0.8°C
± 0.1°C
Strain and Temperature
Multiple fibers
Multiple fibers
Single or multiple fibers
Distributed
No
Yes
Yes
*quasi-distributed with multiple fibers
Table 1. Typical Performances of Distributed / Quasi Distributed Fiber Optic Sensors
The simultaneous measurement of strain and temperature is possible by using our patented method. Standard singlemode fiber is used in large
quantities for high speed optical telecommunications networks and is inexpensive. It is important to make a decision on the fiber type and cable
structure early in any structural monitoring project. Although test equipment can be changed or upgraded in the future, it is essential to install
the correct fiber type if the simultaneous measurement of strain and temperature is required.
Major Applications of Fiber Optic Distributed Strain and Temperature Sensors
Fiber optic distributed strain and temperature sensors have been applied in numerous applications. As mentioned previously, Brillouin-based
systems are generally unmatched in applications that require high-resolution monitoring of large structures (long, or large surface areas). Unlike
competing sensor technologies, Brillouin systems directly leverage the economies of scale from the millions of kilometers of fiber optic
telecommunications fiber installed worldwide. As Table 2 shows below, the most common applications for distributed strain and temperature
sensors involves very large linear or spatial dimensions.
Strain
Temperature
References available upon request
by OZ Optics collaborators
Pipeline Leakage Monitoring
■
■
■
Power Lines Monitoring
■
■
■
Process Control
■
■
■
Structural Health Monitoring (concrete & composite structures)
■
Bridge Monitoring
■
■
■
Fire Detection
■
■
■
Crack Detection
■
Security Fences
■
Application
■
■
Table 2. Applications of Brillouin Fiber Optic Sensors
OZ Optics is committed to delivering solutions in each of the markets listed above. If your critical monitoring application is not listed in the table,
please contact us with your requirements. To get more detailed information related to your application or request a reference article, please
contact OZ Optics.
The fiber optic strand provides excellent flexibility and placement over large areas and great distances. For example: a mining conveyor belt
may be tens of kilometres long in order to remove excess debris. The material is of little value and detecting a seizing bearing along the length
would be difficult via conventional fire detection means. As a bearing starts to seize, it will overheat prior to causing a fire. The DSTS and
sensing fiber is easily installed and will readily detect this change in heat at a bearing. While the direct cost of the damage caused by the fire
is minimal, the loss of revenue from shutdown of the mining operations while the conveyer belt is repaired will be extensive.
9
Sample Performance Table
Distributed Brillouin measurements are quantified by four variables: precision of measurement, variation of strain and temperature to be
measured, spatial resolution, and length of fiber being measured. These four interact to determine the time the measurement will take.
Conversely, if time is restricted, the other qualities of measurement can be determined.
The ForeSight™ Brillouin based DSTS BOTDA module design enables focus on the variable of most concern. For instance, concrete fracture
detection may require tight spatial resolution and high precision. The result will be a known measurement time and the maximum fiber length
that can be utilized.
The measurement time can vary from 1 second to 10 minutes based up the requirements dictated by the application. The sample table below
reflects some common requirements: better than ± 0.5°C and ± 10 µε precision. All table measurements were completed in less than 1 minute
and 40 seconds.
The table is not a restriction of what can be achieved. Variations in the four areas of concern can be accommodated. For instance, the
measurement of temperature/strain for 50 km sensing fiber, 2 m spatial resolution, with an accuracy of 0.2°C/4 µε is attainable, but will increase
measuring time to 3 minutes and 45 seconds. Another comparison of the interaction of fiber length, spatial resolution, accuracy of
temperature/strain, and measurement time: 100 km sensing fiber, 6 m spatial resolution can be 0.4°C/8 µε when measuring time is 4 minutes
and 38 seconds, however the same 100 km can have a precision of 0.1°C/2 µε when spatial resolution is increased to 50 m with a measuring
time of 3 minutes and 48 seconds.
Spatial Resolution
10 cm
50 cm
1m
2m
3m
4m
5m
10 m
20 m
50 m
1 km 0.3°C/6 µε 0.2°C/4 µε
Fiber Length
2 km
0.3°C/6 µε 0.1°C/2 µε
4 km
0.4°C/8 µε 0.3°C/6 µε
10 km
0.3°C/6 µε
20 km
0.4°C/8 µε
0.06°C/1.2 µε
30 km
0.2°C/4 µε
40 km
0.3°C/6 µε
0.1°C/2 µε 0.2°C/4 µε
50 km
0.2°C/4 µε 0.3°C/6 µε 0.2°C/4 µε 0.1°C/2 µε
60 km
0.2°C/4 µε
70 km
0.3°C/6 µε
80 km
0.2°C/4 µε
90 km
0.4°C/8 µε
100 km
0.4°C/8 µε 0.2°C/4 µε
Table 3. Typical BOTDA module measurement precision table (Acquisition time ≤ 100 seconds)
Fast Measurement Mode
The DSTS BOTDA can be used in a fire detection and control system. The distributed fiber optics technology provides for excellent flexibility to
detect fires. The fiber optic strand does not pose a spark risk or explosion risk, and if properly designed, it may be placed in an area subject to
ionizing radiation. The spatial resolution is dependent on the fiber length. With a 20 km fiber length, a spatial resolution of 1 m is provided. Shorter
lengths can be monitored with better spatial resolution, compared to longer fibers. Similarly, longer lengths can be monitored at the expense of
resolution. Refer to Table 3 for more details.
Temperature measurement performance while in Fast Measurement Mode will vary from a nominal Brillouin measurement in that the goals of
the measurement are based upon fast detection of a change in temperature. The overall goal of the Fast Measurement Mode is to accurately
detect a change in temperature associated with a pending fire or outright temperature changes in a nominal amount of time. Therefore the
performance of the DSTS BOTDA will meet or be better than the following table:
Start
Temperature
Required Measuring
Temperature By System
Oven Setting
Temperature
Specified
Measurement Time
Measurement
Accuracy
24°C
30°C
30°C
9 sec
28 - 32°C
24°C
40°C
40°C
11 sec
38 - 42°C
24°C
50°C
50°C
13 sec
48 - 52°C
24°C
60°C
60°C
14 sec
58 - 62°C
24°C
70°C
70°C
16 sec
68 - 72°C
24°C
80°C
80°C
18 sec
78 - 82°C
Table 4. Typical Accuracy for Fire Detection Applications (Fast Measurement Mode)
The following conditions apply for the reference table to be accurate:
• Total fiber length: 60 km
• Baseline must be obtained at 24°C before temperature measurements.
• Spatial resolution: 6 m
• Measurement time does not include sensing cable response time.
• All sensing fiber must be same type of fiber without strain effect.
10
Calculating the Cost Savings for Brillouin Fiber Optic Sensors
As stated previously, Brillouin fiber sensors offer high-resolution with long distance coverage at a cost per kilometer unmatched by any other
measurement technique. This creates the opportunity to generate a rapid return on investment for Brillouin sensor-based monitoring systems
used in critical monitoring applications. The figure below shows a simple cost savings example:
Fiber Optic Monitoring
OZ Optics Ltd. Cost Savings Calculator
System Parameters
Pipeline Length
50 km
Cost of Failure
$750,000 cost of leak
Downtime Cost
$20,000 per hour
Comparison
Probability of Failure
Monitoring
No Monitoring
Comments
% / year
0.25%
1%
Reduced risk of failure
Downtime
hours/year
4.8
24
Automated preventive maintenance
Maintenance Cost
dollars/year
$25,000
$50,000
Automation of routine maintenance
Total Annual Savings
$414,625
Total Annual Savings
Table 5. Cost Savings example
Several pipeline shutdown accidents demonstrate the need for continuous online monitoring. While the calculation in Table 5 is for a mid-sized
regional distribution pipeline, the economics for major pipelines are even more compelling. The shutdown cost per day can easily exceed
$10 million. With long-haul Brillouin monitoring system costs of only $1 - $2 per meter, the prevention of a single shutdown greatly exceeds the
installation and operating costs of a monitoring system. Other large structures such as power lines, dams, and bridges also have very high costs
associated with catastrophic failure and shutdowns.
The most important factors in a typical cost savings estimate are the reduction in maintenance/inspection cost (due to automated monitoring),
the reduction in downtime, and the reduction in the potential for catastrophic failure. In many instances, the downtime and failure costs are much
higher than that shown in the example.
For more information about our strain and temperature sensor system and related products, please visit www.ozoptics.com.
Background Articles
Pipeline Buckling Detection:
L. Zou, X. Bao, F. Ravet, and L. Chen, “Distributed Brillouin fiber sensor for detecting pipeline buckling in an energy pipe under internal pressure,"
Applied Optics 45, 3372-3377 (2006).
Pipeline Corrosion Detection:
L. Zou, G. Ferrier, S. Afshar, Q. Yu, L. Chen, and X. Bao, “Distributed Brillouin scattering sensor for discrimination of wall-thinning defects in steel pipe
under internal pressure,” Applied Optics 43, 1583-1588 (2004).
Power Line Monitoring:
L. Zou, X. Bao, Y. Wan and L. Chen, “Coherent probe-pump-based Brillouin sensor for centimeter-crack detection,” Optics Letters 30, 370-372 (2005).
Crack Detection:
L. Zou and Maria Q. Feng, “Detection of micrometer crack by Brillouin-scattering-based distributed strain and temperature sensor,” 19th International
Conference on Optical Fiber Sensors, Perth (Australia, 14-18 April 2008).
Accuracy of BOTDA Technology:
L. Zou, X. Bao, S. Yang, L. Chen, and F. Ravet, “Effect of Brillouin slow light on distributed Brillouin fiber sensors,” Optics Letters 31, 2698-2700 (2006)
Simultaneous Measurement of Strain and Temperature:
L. Zou, X. Bao, S. Afshar V., and L. Chen, “Dependence of the Brillouin frequency shift on strain and temperature in a photonic crystal fiber,” Optics
Letters 29, 1485-1487 (2004)
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Source Exif Data:
File Type : PDF File Type Extension : pdf MIME Type : application/pdf PDF Version : 1.3 Linearized : Yes XMP Toolkit : Adobe XMP Core 5.2-c001 63.139439, 2010/09/27-13:37:26 Creator Tool : PScript5.dll Version 5.2.2 Modify Date : 2018:01:04 17:14:02-05:00 Create Date : 2017:08:31 12:57:28-04:00 Metadata Date : 2018:01:04 17:14:02-05:00 Format : application/pdf Title : DTS0115 - Fiber Optic Distributed Strain and Temperature Sensors (DSTS) BOTDA Module Creator : Copyright ©2018 OZ Optics Ltd. All rights reserved. Description : OZ Optics’ Foresight™ series of fiber optic Distributed Strain and Temperature Sensors (DSTS) BOTDA modules are sophisticated sensor systems using stimulated Brillouin scattering in optical fibers to measure changes in both strain and temperature along the length of an optical fiber. By deploying a sensing cable that includes standard telecom single mode fiber, users can detect when and where the strain or the temperature of the object has changed and correct potential problems before failure occurs. A unique feature of our Foresight™ DSTS system is its ability to measure temperature and strain, simultaneously and independently, allowing regions of temperature induced strain to be identified. Producer : Acrobat Distiller 10.1.16 (Windows) Keywords : Document ID : uuid:eeef8712-9e68-4fe0-9c52-4a1e92524030 Instance ID : uuid:4de33927-852b-4b61-bca4-c296683273a5 Startup Profile : Print Page Layout : SinglePage Page Count : 11 Author : Copyright ©2018 OZ Optics Ltd. All rights reserved. Subject : OZ Optics’ Foresight™ series of fiber optic Distributed Strain and Temperature Sensors (DSTS) BOTDA modules are sophisticated sensor systems using stimulated Brillouin scattering in optical fibers to measure changes in both strain and temperature along the length of an optical fiber. By deploying a sensing cable that includes standard telecom single mode fiber, users can detect when and where the strain or the temperature of the object has changed and correct potential problems before failure occurs. A unique feature of our Foresight™ DSTS system is its ability to measure temperature and strain, simultaneously and independently, allowing regions of temperature induced strain to be identified.EXIF Metadata provided by EXIF.tools