Name: DTSX200 gedistribueerde temperatuursensor
Brand: Yokogawa
SKU: distributed-temperature-sensing-dtsx200

What Is Distributed Temperature Sensing?

Distributed temperature sensing (DTS) measures temperature distribution over the length of an optical fiber cable using the fiber itself as the sensing element. Unlike traditional electrical temperature measurement (thermocouples & RTD), the length of the fiber optic cable is the temperature sensor. Distributed temperature sensing can provide thousands of accurate and precise temperature measurements over a long distance. Compared to traditional electrical temperature measurements, distributed temperature sensing represent a cost effective method for obtaining accurate and high resolution temperature measurement.

Introducing Fiber-Optic Temperature Sensor, DTSX

Temperature monitoring throughout large plants without blank areas is difficult due to technical and cost issues and it is hard to comply with corporate HSE policies. DTSX measures temperature distribution over the length of an optical fiber cable using the fiber itself as the sensing element and it is ideal for temperature monitoring over long distances and wide areas. DTSX has been increasingly used in variety of applications such as fire detection, leak detection and preventative maintenance.

What Are the Advantages of Using DTS ?

Cost
When an application requires hundreds or thousands of sensors to be measured, it becomes very expensive to wire each individual sensor back to a data acquisition station. It is much more cost effective and beneficial to acquire accurate and high resolution temperature measurement using fiber optic cable.

Long distance
It is difficult to measure temperature over a long distance using traditional electrical measurement sensors. Not only can DTS fiber optic cable be deployed over a long distance but it also provides a high resolution profile of the area as well as accurate and precise temperature measurement over that distance.

High electromagnetic noise environment
DTS is isolated from electromagnetic noise because of its optical characteristics. Unlike traditional electrical measurement sensors (thermocouple & RTD) there is no electrical component within the optical fiber, therefore, it is immune to electromagnetic noise.

What Is DTSX200 Distributed Temperature Sensor ?

The DTSX200 adapts flexibly to the installation environment as a standard model. Using data obtained from temperature distribution measurement, we contribute to monitoring of plant facilities, maintenance and management of the integrity of high-temperature furnaces, and prevention of failures.

About OpreX

OpreX is the comprehensive brand for Yokogawa’s industrial automation (IA) and control business and stands for excellence in the related technology and solutions. It consists of categories and families under each category. This product belongs to the OpreX Field Instruments family that is aligned under the OpreX Measurement category.

Measurement Principle

Operating Principle

Yokogawa DTSX200 measures temperature and distance over the length of an optical fiber using the Raman scatter principle. A pulse of light (laser pulse) launched into an optical fiber is scattered by fiber glass molecules as it propagates down the fiber and exchanges energy with lattice vibrations. As the light pulse scatters down the fiber optic cable, it produces stokes signal (longer wavelength) and anti-stokes (shorter wavelength) signal, of which both signals shifted from the launch of the light source. The intensity ratio of the two signals components depends on the temperature at the position where the Raman scatter is produced. This temperature can thus be determined by measuring the respective intensities of the stokes and anti-stokes signals. Furthermore, part of the scattered light, known as the backscatter, is guided back towards the light source. The position of the temperature reading can thus be determined by measuring the time taken for the backscatter to return to the source.

Raman Scattering

All light interacts with matter! For example, imagine standing in a pitch black garage with no external light source. Inside this garage is a bright red sports car. Needless to say, you cannot see the sports car or the color of the sports car itself. However, when you turn on the lights to the garage, you can immediately see the light source reflecting the bright red color off the car. The light that is bouncing off the red sports car is only bouncing off the "red" spectrum, therefore, your eyes see the sports car as, well, red.

Raman scattering

This phenomena is also true when you shoot a pulse of light (laser pulse) off of a molecule, in this case, the fiber glass molecule in the optical fiber cable. When the light source enters the optical fiber cable, most of the light bounces (backscatter) back unchanged (no change in wavelength). However, a small amount of that light shifted/changed. That shift/change from the light source is called Raman Scatter. Since Raman Scatter is thermally influenced by temperature, the intensity depends on temperature. Distributed temperature sensing is capturing the shift/change from the propagating light pulse and measuring the intensities between the two signal components (stokes and anti-stokes).

Types of Scattering Light

Yokogawa's distributed temperature sensors measure temperature distribution using Raman scattering light, which exhibits particularly good temperature sensitivity among the following types of scattering light.

Types of Scattering Light	Features	Field of Application
Rayleigh Scattering (Rayleigh)	Caused by fluctuations in the density inside the medium Same frequency components as those of incident light	Optical fiber loss distribution (OTDR：Optical Time Domain Reflectometer)
Raman Scattering (Raman)	Caused by the interaction with molecular vibration inside the medium The intensity of anti-Stokes rays is mainly dependent on temperature.	Temperature distribution (DTS：Distributed Temperature Sensor)
Brillouin Scattering (Brillouin)	Caused by the interaction with sound waves inside the medium The frequency is dependent on strain and temperature.	Strain distribution (DSS：Distributed Strain Sensor) Temperature distribution

Measurement Method

Single-Ended Measurement Method

This method launches optical pulses into only one end of the optical fiber for sensing. Easy to install, it is effective when the measuring target is long range.

Single-ended measurement method

Double-Ended Measurement Method

This method launches optical pulses into both ends of a looped optical fiber for sensing.
This method allows for continued measurement even if on place of the fiber optic cable is broken.

Double-ended measurement method

Comparison of Measurement Methods

Measurement Method	Advantages	Disadvantages
Single-Ended Measurement Method	Compared to the double-ended measurement, the fiber optic sensor cable can be easily installed. No optical switch is required. Even if the optical fiber is broken, it is possible to continue measurement at points before the broken section.	It is impossible to compensate for position-based optical fiber loss fluctuations. The temperature calibration is more complicated than the double-ended measurement.
Double-Ended Measurement Method	The optical fiber loss distribution along the optical fiber is automatically canceled out. Yokogawa's method reduces the influence such as darkening. If the optical fiber is broken, the measurement method is automatically switched to the single-ended measurement.	The installation of fiber optic sensor cable must be looped. An optical switch is required. The actual maximum distance range for temperatuer measurement is a half that for the single-ended measurement method.

Types of Temperature Sensors

Types of Temperature Sensors and Their Features

Type	Features
Fiber Optic Sensor	An optical fiber, used as the temperature sensor, is suitable for monitoring temperatures over a long distance and wide area. It allows you to identify specific locations on a per sampling-interval basis along the fiber optic sensor cable and to monitor the temperature at each location.
Thermo Camera	This instrument detects infrared radiant energy from objects to measure temperatures. Capable of measuring temperature distributions over a wide area in a non-contact manner, it is suitable for monitoring temperatures of industrial furnaces, solids of revolution, and so on.
Resistance Thermometer	This sensor uses the characteristic of the electrical resistance of metal that changes almost in proportion to temperature. Capable of accurate temperature measurement, it is suitable for industrial precision temperature measurement.
Thermocouple	When two different metals are connected to each other, the temperature difference between the metals develops electromotive force at the connection. This sensor uses this electromotive force. Capable of measuring temperature over a wide area at low cost, it is widely used as a temperature sensor for industrial use.
Radiation Thermometer	This thermometer measures temperatures by measuring the intensity of infrared rays from materials. As a non-contact thermometer capable of remote measurement, it is suitable for measuring ultra-high temperatures.

Comparison among Temperature Monitoring Methods

	Fiber Optic Sensor	Thermo Camera	Point Sensor (Thermocouple)
Description	Wide-area monitoring based on a fiber optic sensor	Surface temperature monitoring based on a thermo camera	Multipoint monitoring based on discrete sensors
Detection Method	Contact	Non-contact	Contact
Range of Temperatures Monitored	-200 to 300 °C (Based on a sensor cable)	Normal temperature to 2000 °C (Range switching required)	-200 to 1000 °C (Type K thermocouple)
Area	Coverage of a very wide area DTSX200: up to 6 km / ch DTSX3000: up to 50 km / ch DTSX1: up to 16 km / ch	Small viewing angle of 20°	Wide area
Advantages	Coverage of a very wide area and seamless monitoring	Capability of a limited tiny area monitoring	Capability of a limited tiny area monitoring
Disadvantages	Restricted to small areas	Non-seamless monitoring	Non-seamless monitoring Installation and maintenance of compensating lead wires

Performance

Representative parameters that indicate the performance of distributed temperature sensors include the spatial resolution and temperature resolution. In spite of the fact that in general, there is a trade-off relationship between these parameters, we have realized high performance based on signal processing technology.

Spatial Resolution

The spatial resolution is the minimum length that detects changes in temperature (it is also referred to as the response distance).
The spatial resolution is defined as the length when a temperature change of 10 to 90 percent of the optical fiber for sensing is detected.
The sampling resolution represents the data interval, the definition of which is different from that of the spatial resolution.

Spatial Resolution

Temperature Resolution

The temperature resolution is defined by the standard deviation (1 σ) of measured values along the fiber optic sensor in a uniform temperature environment (in a thermostat chamber).
The temperature resolution is the indicator of variations, which does not indicate temperature accuracy (the use of a reference thermometer in calibration makes it possible to make measurements with a higher temperature accuracy).
Raman backscattering light is a very faint signal. By repeating measurements to average measured values, the distributed temperature sensors achieve a higher temperature resolution.

Temperature Resolution
Examples of measurement results (DTSX200)

Types of cables

You can choose the most suitable type according to your intended use.

Normal Operating Temperature	Applications	Cable Type	Cable Details	Features
Normal Temperature	Conveyor Fire Detection Cable Temperature Monitoring Bus Duct Temperature Monitoring Cable Tunnel Fire Detection Warehouse Fire Detection Hot Spot Detection Cold Spot Detection etc.	Standard Type	Image Zoom	Nonmetal, lightweight, and easy to install EN 54-22 certified
		Robust Type	Image Zoom	Resistant to crush and tension and less likely to break EN 54-22 certified
		Flexible Type	Image Zoom	Thin and flexible and easy to install along the measurement targets
High / Low Temperature	Blast Furnace Monitoring Drying Furnace Monitoring LNG Leak Detection Well Monitoring etc.	Steel Tube Type	Image Zoom	Thin and flexible and easy to install along the measurement targets
High / Low Temperature		Steel Armored Type	Image Zoom	Resistant to crush and tension and less likely to break

Flexible System Construction That Adapts to a Wide Range of Applications

Temperature data is processed (zone and alarm settings and warnings are made) at a host system, allowing for flexible system construction according to the system size and your requirements.
If an optionally available PLC (FA-M3 or e-RT3) or recorder is incorporated, the system can produce a contact output when it gives a warning.

System Configuration Example : Image

【Example of a Host System】
SMATRDAC+ (recorder and data logging software), CI server and CENTUM (integrated production control system)

Product Introduction

DTSX200 Overview

The DTSX200 distributed temperature sensor is configured by a DTS module, an optical switch module, a base module, a power supply module, and so on.

DTSX200 Distributed Temperature Sensor

* DTS : Distributed Temperature Sensor

The distance to the target : 6 km Range

On the Partner Portal Member Site, you can check the details of the specifications.
GS 39J06B45-01 : DTSXM Distributed Temperature Sensor Middle Range System
GS 39J02B45-01 : DTSXM Distributed Temperature Sensor Middle Range System (Software)

Optical Switch Module

Optical Switch Module
Image Zoom

We provide three different types of optical switches.
They are module types, offering choices according to your intended use.

DTOS2 : 2 - channel optical switch module
DTOS4 : 4 - channel optical switch module
DTOS16 : 16 - channel optical switch module

Base Module

Base Module
Image Zoom

The base module for DTSX200 is used for mounting various function modules including the DTSX200 distributed temperature sensor, power supply modules, optical switch modules and CPU I/O modules

Power Supply Module

Power Supply Module
Image Zoom

One of the following power supply modules must be selected.(* Input voltage range by model name)

NFPW426 : 10 to 30 V DC
NFPW441 : 100 to 120 V AC
NFPW442 : 220 to 240 V AC
NFPW444 : 21.6 to 31.2 V DC

Accessory

DTRK10 Rack Mount Kit

DTRK10 Rack Mount Kit
Image Zoom

The rack mount kit can be used for laying optical fibers in a cabinet.

Software

DTSX3000 Control Visualization Software (DTAP3000)

DTSX200 Control Visualization Software (DTAP200)
Image Zoom

The DTSX200 needs to process temperature measurement data at multiple points from multiple channels.
The DTAP3000 is application software specifically designed to facilitate making settings of all DTSX products (DTSX3000 / 200 / 1) and indicating measurement data. With a variety of functions, such as setting and control of the main unit of the DTSX200 and optical switch, indication of measurement results, analysis of changes in temperature, and setting and indication of alarms, the software provides you with information that helps you monitor temperature.

DTSX200 data conversion software (DTAP200D)

DTSX200 data conversion software (DTAP200D)
Image Zoom

The DTAP200D is application software for converting data to the WITSML format, the standard format for the oil and gas markets. This software allows you to create data in the WITSML format directly from the DTSX200.

Specifications

Refer to the General Specifications for detailed specifications.

DTSX 200

Item			Specifications
Distributed temperature measurement	Distance	Measurement distance range	1 km, 2 km, 3 km, 4 km, 6 km
		Sampling resolution	10 cm, 20 cm, 50 cm, 1 m
		Spatial resolution	1 m (10 to 90 %)
	Temperature	Measurement temperature range	-200 to 300 °C (dependent on the optical fiber for sensing)
		Temperature resolution (1 σ, without optical switch)	Range
		Temperature resolution (1 σ, without optical switch)	Time 10 s 1 min 10 min	1 km 0.5 0.3 0.1	3 km 1.1 0.6 0.2	6 km 4.2 °C 2.1 0.7
Sensor optical fiber	Optical fiber		50 / 125 μm GI (No reflection at end of optical fiber)
Sensor optical fiber	Optical connector		E2000 / APC
Interface	Serial (RS-232C)		3 ports, non-isolated, RJ45 modular jacks Full duplex, asynchronous
			SERIAL 1: Function: Communication (Modbus) Baud rate: 1.2, 2.4, 4.8, 9.6, 19.2, 38.4 57.6, 115.2 kbps
			SERIAL 2: Function: Communication (Modbus) Baud rate: 1.2, 2.4, 4.8, 9.6, 19.2, 38.4 kbps
			SERIAL 3: Function: Maintenance (Private)
	Ethernet interface	LAN	1 port, 10BASE-T or 100BASE-TX, RJ45 modular jacks, automatic negotiation, automatic MDI, with Network power switch (ON/OFF)
	Display		LEDs: HRDY, RDY, LASER ON
Power supply	Consumption	Operating mode	10 W
Power supply	Consumption	Power save mode	2.1 W
Dimensions (W x H x D)			197.8 x 132.0 x 162.2 mm (6 slots width)
Weight			2.5 kg

Temperature calibration of the Sensor Optical Fiber for DTSX200 is required before temperature distribution measurement.

Optical Switch Module

Item		Specifications
Model		DTOS2	DTOS4	DTOS16
Insertion loss		0.6 dB (Typical) 1.4 dB (Max.)	1.0 dB (Typical) 3.0 dB (Max.)	0.8 dB (Typical) 1.4 dB (Max.)
Distributed temperature measurements	Measurement type	Single end, Double end
Sensor optical fibers	Optical fiber	50 / 125 μm GI, closed end, non refraction required
	Optical connector	E2000 / APC
	Optical channels	2 channels	4 channels	16 channels
Interface	Control	Controlled by DTSX200
Interface	Display	LEDs: HRDY, RDY, Alarm, Active channel
Power supply	Consumption	1 W	1 W	Operating 4.5 W Power save 1 W
Dimensions (W x H x D)		65.8 x 130.0 x 160.3 mm (2 slots width)	65.8 x 130.0 x 160.3 mm (2 slots width)	65.8 x 130.0 x 160.3 mm (2 slots width)
Weight		0.6 kg	0.64 kg	0.75 kg

Note: As a guideline, the module should be replaced periodically every 4.7, 6 and 9.5 years for continuous operation of 15-second, 20-second and 30-second measurements, respectively.

REGULATORY COMPLIANCE and CONFORMITY to STANDARDS

Item		Specifications
Safety Standards		CSA C22.2 No.61010-1-04 EN 61010-1:2010 EN 61010-2-030:2010 EN IEC 61010-2-201:2018 CU TR 004
EMC Standards	CE Marking	EN 55011:2016+A1:2017 Class A Group 1 EN 61000-6-2:2005 EN 61000-3-2:2014 EN 61000-3-3:2013
	RCM	EN 55011:2016+A1:2017 Class A Group 1
	KC Marking	Korea Electromagnetic Conformity Standard
	EAC Marking	CU TR 020
Laser safety	Class	IEC 60825-1:2007 Class1M IEC/EN 60825-1:2014 Class1
Laser safety	FDA (CDRH)	21CFR Part 1040.10
Standards for Hazardous Location Equipment	FM Nonincendive	Class I, Division 2, Groups A, B, C, D T4 FM 3600-2018 FM 3611-2018 FM 3810-2005
	ATEX Type "n"	II 3 G Ex nA ic [op is Gc] IIC T4 Gc X EN IEC 60079-0:2018 EN 60079-11:2012 EN 60079-15:2010 EN 60079-28:2015
	CSA Non-Incendive	Class I, Division 2, Groups A, B, C, D T4 C22.2 No. 0-10 CAN/CSA-C22.2 No. 0.4-04 C22.2 No. 213-M1987 TN-078
Restriction of Hazardous Substances	RoHS Directive	EN IEC 63000:2018

Note: Under EU legislation, the manufacturer and the authorised representative in EEA (European Economic Area) are indicated below:
Manufacturer: YOKOGAWA Electric Corporation (2-9-32 Nakacho, Musashino-shi, Tokyo 180-8750, Japan).
Authorised representative in EEA: Yokogawa Europe B.V. (Euroweg 2, 3825 HD Amersfoort, The Netherlands).

Industries/Applicantions

Vehicle Lithium-ion Battery

Smart Monitoring of Aging Process Shelves

Thermal runaway of lithium-ion batteries mounted on individual shelves is discovered at an early stage. This enables a quick initial response when an abnormality occurs to limit damage to a minimum.
(For details, refer to "Smart Monitoring of Aging Process Shelves -In-vehicle Lithium-ion Battery Applications- ".)

Prevention of Fires in Exhaust Air Ducts in Battery Assembly Process

Fires or dust explosions in exhaust air ducts for preventing the contamination of aluminum dust in the assembly process of lithium battery batteries are monitored. Abnormalities are not overlooked as ducts extending over long distances in blind areas such as roof space are comprehensively monitored. (For details, refer to “Prevention of Fires in Exhaust Air Ducts in Battery Assembly Process -In-Vehicle Lithium-ion Battery Applications- ".)

Monitoring of Soundness of Power Supply Bus Bar

The joints of the power supply bus bar are monitored.
Abnormalities are not overlooked as fiber optic cable is built into the bus duct and bus bars extending over long distances in blind areas such as roof space are comprehensively monitored.
(For details, refer to "Monitoring of Soundness of Power Supply Bus Bar -In-vehicle Lithium-ion Battery Applications-".)

Fiber Optic Cable Visualizes In-furnace Temperature Distribution

The DTSX fiber optic distributed temperature sensor can monitor temperature distribution every meter along the path of the fiber optic cable.
Thermocouples, etc. are used for heater control as up till now, and by adding DTSX to them, it will be possible to visualize the temperature distribution inside the entire drying furnace.
Resolving heater and other problems by utilizing the result, and passing products through the furnace after setting the in-furnace temperature to the ideal temperature profile result in improved productivity.

Fiber Optic Cable Visualizes In-furnace Temperature Distribution

When attempts are made to measure multiple points by thermocouples, etc., wiring is complicated, construction costs escalate and periodic maintenance of each individual sensor is required. This is unrealistic when applying it to multiple drying furnaces.
As the DTSX system requires only laying fiber optic cable inside the furnace, both initial and running costs can be reduced.
Moreover, a single DTSX can cover multiple drying furnaces, which improves cost effectiveness.
The DTSX has also been put to use in monitoring the temperature distribution in tunnel furnaces.
(For details, refer to "Fiber Optic Cable Visualizes In-furnace Temperature Distribution".)

Fire Detection

Early fire detection to critical process and environment is an important component to any safety system. A blazing fire has devastating consequences to important assets, products and most importantly, human lives. Furthermore, the cost of downtime due to fire leads to lost opportunities and costly repairs. Discrete sensor technology often fails due to the surrounding environment conditions such as dust, humidity, heat and corrosion. In addition, it is expensive to maintain a conventional sensor technology due to constant repair. Yokogawa's DTSX200 is designed to detect fire in critical assets under the most extreme conditions and offers unmatched reliability, performance and cost savings.

Yokogawa's DTSX200 is designed to deploy in the following fire detection applications:

Conveyor belts carrying important goods
Tank farms
Cable trays
Underground tunnels
Pipelines (underground, above ground)
Nuclear facilities
Mining, Refinery

Feature	Benefits
1m special resolution	Identify the exact location of the fire
Up to 0.1°C temperature resolution	Possible fire detection within the first 10 seconds of occurrence *
Fiber optic cable sensor	Unlike discrete sensor or IR camera, fiber optic cable eliminates "blind spots"
Coated fiber optic cable	Immune to dust, humidity, corrosion and dirt
Report and data analysis	Access historical data using HTTP, SFTP or web browser
Wide range of communication protocols	Connect to existing DCS, PLC, DAQ and wireless interface
6km optical fiber = 6,000 points!	Cost effective way of measuring temperature compared to traditional sensor technology

* Assuming appropriate scan rate and data refresh intervals are used

Oil & Gas

The development of unconventional resources, such as heavy oil, oil sands and shale gas has been progressing in line with the increase in global energy demand. DTSX200 can measure the temperature distribution along an optical fiber with a length of several kilometers are being applied to extraction of unconventional resources. DTSX200 maximizes oil/gas extraction by providing real time continuous temperature measurement through different injection dynamics. In addition to well optimization, DTSX200 provides critical data that help monitor and detect wellbore conditions for leaks, water penetration and gas breakthrough. DTSX200 also provides control capability (measurement of flow, pressure, temperature, valve position, etc.) on top of fiber optic temperature measurement. More importantly, compared to conventional wellbore monitoring technology, DTSX200 is more robust, cost effective and accurate.

Features	Benefits
Ultra low power consumption: 10W	Perfect for solar application in remote areas
Operating temperature range: -40 °C to 65 °C	Perfect for rugged environment without cooling or heating
Fiber optic cable sensor	Provides a complete and continuous profile of the downhole well
Control capability with NFCP050 module	Monitor and control external devices such as flow, pressure, valve position, temperature, etc.
Wide range of communication protocols	Connect to existing DCS, PLC, DAQ and wireless interface
6km optical fiber = 6,000 points!	Cost effective way of measuring temperature compared to traditional sensor technology