Glossaries

There are many specialized glossaries that cover the terms describing the unique details about temperature and moisture sensors and their uses and this page represents an attempt to index most of them in one place.

CONTACT TEMPERATURE SENSORS:

Thermistors: https://www.temperatures.com/blog/2018/04/04/thermistor-gloss…-and-terminology/.

Thermocouples:

RTDS: 

 

NONCONTACT TEMPERATURE SENSORS:

Many online articles about radiation thermometry and its uses (infrared thermometers, radiation pyrometers) exist including technology articles, PowerPoint slide presentations and .pdf downloads, but they seem to be vanishing as more and more “big businesses” take over these specialized sensors.But few are aimed at being useful glossaries or definition of terms.

There are some exceptions and some well-crafted pieces that have been online for a while and can be found in semi-hidden corners of the Web.

Thermal Radiation Thermometers: temperature_measurement_radiation_thermometers

Thermal Imaging:  (Glossary of Basic Thermography Terms) http://www.ne-spintech.com/Glossary%20of%20Basic%20Thermography%20Terms.pdf .

Clearly this is a work in progress, and it may be expanded in time. Priority will be according to the response it garners.

 

Industrial temperature measurement | Basics and practice

Free Download From ABB

(Extract From the Introduction)

With this Handbook for industrial temperature measurements we are attempting to provide the technician with solutions to his wide variety of responsibilities. At the same time, it provides for those new to the field, insight into the basics of the most important measurement principles and their application limits in a clear and descriptive manner.

The basic themes include material science and measurement technology, applications, signal processing and fieldbus communication.

A practice oriented selection of appropriate temperature sensor designs for the process field is presented as well as therequired communication capability of the meter locations.

The factory at Alzenau, Germany, a part of ABB, is the Global Center of Competencefor Temperature, with numerous local experts on hand in the most important industrialsectors, is responsible for activities worldwide in this sector.

125 years of temperature measurement technology equates to experience and competence. At the same time, it forms an important basis for continued innovation.

In close cooperation with our customers and users, our application engineers create conceptsto meet the measurement requirements.

Our Sector-Teams support the customer, planner and user in the preparation of professional solutions.

Free download available online at: https://library.e.abb.com/public/6bfb8fc893ac4d0da0a806ce8cd73996/03_TEMP_EN_E.pdf

Author Team:
Karl Ehinger, Dieter Flach, Lothar Gellrich, Eberhard Horlebein, Dr. Ralf Huck, Henning Ilgner, Thomas Kayser, Harald Müller, Helga Schädlich, Andreas Schüssler, Ulrich Staab,

ABB Automation Products GmbH

Many thanks to the publishing group at ControlEngineering-Europe for alerting us to this new online resource (http://www.controlengeurope.com/article/140944/Handbook-aims-to-simplify-industrial-temperature-measurement.aspx)

Mercury Thermometer Alternatives by NIST

Promoting alternatives

no mercuryOnline —  The USA’s National Institute for Science & Technology (NIST) is not only  the nation’s National Metrology Institute (NMI), it also serves additional roles, including cooperating with other government agencies to safeguard people from harm due to sensors or practices that could be hazardous.

About 20 years ago the use of mercury-filled sensors, such as barometers, hygrometers and liquid-in-glass thermometers were recognized as sources of long-term hazards to man and nearly all animals.

The Federal Drug Administration (FDA) and Environmental Protection Agency (EPA) began efforts to ban the use of mercury in such devices and NIST has been in the forefront of the effort, along with volunteer organizations like ASTM International.

NIST has published a series of webpages that describe the issues related to mercury filled thermometers and considered several alternatives, some of which, in this Editor’s opinion are long overdue.

The rest of this article is copied from the December 22, 2016 NIST webpage: https://www.nist.gov/pml/sensor-science/thermodynamic-metrology/mercury-thermometer-alternatives-promoting-alternatives that begins the NIST series of information pages to help users understand some of the alternatives to mercury-filled  Liquid-in-Glass thermometers.

In effect these new temperature sensor alternatives bring many testing and measuring practices into the modern world of both sensor and display technologies, providing durability, precision and traceability along with digital options, in many cases.

Mercury-filled thermometers have historically served numerous industries as reliable temperature standards. Increased regulation and the high cost of cleaning up mercury spills have encouraged the use of alternative types of thermometers.

To support the use of alternative thermometers, the NIST Temperature and Humidity Group provides guidance documents, training, and technical consultation to other government agencies and standards-developing organizations.

Replacement of mercury thermometers with suitable alternatives will reduce releases of mercury into the environment and will reduce costs incurred to clean up mercury spills.

Historically, healthcare and regulated testing laboratories have relied greatly on NIST-calibrated mercury-in-glass thermometers as stable reference standards of temperature.

The use of mercury thermometers has been virtually eliminated in routine hospital use, but a wide variety of regulations and test methods continue to specify mercury thermometers.

Mercury thermometers have several intrinsic advantages:

  • they are stable for long periods,
  • failure is usually visually apparent, and
  • they require little training or maintenance.

 

However, mercury is a powerful neurotoxin, and the cost of cleaning a mercury spill in industry is many thousands of dollars. Furthermore, many states restrict the sale of mercury thermometers.

In 2008, the NIST Temperature and Humidity Group worked with several organizations to reduce or eliminate the use of mercury thermometers.

Environmental Protection Agency (EPA):  the EPA hosted meetings in the Spring of 2008 to discuss strategies to eliminate the use of mercury thermometers in EPA regulations and laboratories. NIST provided technical guidance documents, presentations, and technical advice as experts in temperature measurements.

Clinical Laboratory and Standards Institute (CLSI):  NIST Temperature and Humidity Group staff have worked with CLSI staff to update standards calling for the use of mercury-in-glass SRM thermometers, enabling laboratories to use other thermometer types with NIST traceability.

Centers for Disease Control and Prevention (CDC):  Control of temperature is critical to proper storage of vaccines, in order to preserve safety and efficacy. At CDC’s invitation, the NIST Temperature and Humidity Group gave a presentation at the May, 2008 “Vaccine University” that CDC sponsors. Over 60 participants learned how traceable temperature measurement and control can be achieved with modern electronic thermometers.

These activities build on support provided in 2007 to the Food and Drug Administration (steam processing of food) and ASTM committee D2 on petroleum.

In an environment of increased regulatory and economic pressures to discontinue the use of mercury thermometers, NIST has provided timely and critically important technical advice to other federal agencies and thermometer users, ensuring that important industrial and health-care temperature measurements are performed efficiently and accurately.

Major accomplishments:

  • Guidance document published on how to identify alternatives to mercury liquid-in-glass thermometers.
  • Technical support provided to other government agencies and to developers of documentary standards.

 

Links to other NIST webpages:

 

Selected Publications & Related Links

 

Questions about Mercury Thermometer Alternatives?

New references for high temperature measurements

Summary of work reported for high temperature measurements from NPL

As a culmination of an eight-year research programme an international collaboration has developed robust reference fixed points, studied their sensitivity to impurities and external conditions and finally measured their melting transition temperature.

This talk describes how 100+ measurements made by nine different NMIs have been combined to assign low-uncertainty thermodynamic temperatures to the melting transition of Re-C, Pt-C and Co-C metal-carbon eutectics.

At the simplest level, these fixed-points will provide new temperature references for the calibration of pyrometers at temperatures above the freezing point of silver (1234.93 K) and will thus reduce the uncertainties associated with high temperature measurement compared to those achievable using the International Temperature Scale of 1990 (ITS-90).

The thermodynamic temperatures of these fixed-points have been determined through direct measurement of the radiance of a blackbody cavity surrounded by the fixed-point material from Planck’s law and hence the Boltzmann Constant.

The evolving mise en pratique for the definition of the kelvin encourages the realisation and dissemination of thermodynamic temperature.

This may be directly – and the work described in this talk shows that filter radiometry is sufficiently mature for this, or it may be by providing fixed-points with reference thermodynamic temperatures that have associated uncertainties – and this talk outlines such temperatures.

Recorded: 16 June 2015

Speaker: Emma Woolliams

Last Updated: 10 Sep 2015

Source: http://www.npl.co.uk/science-lectures/new-references-for-high-temperature-measurements

YouTube Video: https://www.youtube.com/watch?v=l4Ws6PiqQ9cs.YouTube video:

Further information

Related areas

TI Temperature Measurement Videos

TI, or Texas Instruments, is one of the world’s most prolific and largest makers of temperature sensors. They make all kinds but their sensors are mostly in the form of Integrated Circuit semiconductors.

TI also does an exceptional job in educating users how their devices work and how they can be interfaced and incorporated in measurement systems. Especially useful are the videos showing how some of their other integrated circuit modules can be used with external temperature sensors, like Thermocouples, RTDs and Thermistors.

Here’s an example of an interesting one:

Developed through TI’s expertise in MEMS technology, the TMP006 is the first of a new class of ultra-small, low power, and low cost passive infrared temperature sensors. It has 90% lower power consumption and is more than 95% smaller than existing solutions, making contactless temperature measurement possible in completely new markets and applications.

Check out their Video Channel on YouTube, especially the long list of videos already published about “Temperature Measurement”. It very straightforward; just go to: https://www.youtube.com/user/texasinstruments/search?query=%22temperature+measurement%22

Thermocouple 101

The Analog Devices’ 8 Video Series on Thermocouples

This informative, basic series of brief videos on YouTube and linked on the AD website seems to lack an index. Below there is an approximation to what we believe the staff at AD intended followed by a series of 8 pages, one for each video on YouTube.com

Index

  1. Thermocouple 101: What is a Thermocouple?
  2. Thermocouple 101: Measuring the Tiny Signal
  3. Thermocouple 101: Cold Junction Compensation
  4. Thermocouple 101: Setting the Common Mode Voltage
  5. Thermocouple 101: Open Thermocouple Detection
  6. Thermocouple 101: Filtering a Thermocouple
  7. Thermocouple 101: Thermocouple Nonlinearity
  8. Thermocouple 101: Compensating for Nonlinearity

What is a Thermocouple?

Read more Thermocouple 101

New ASTM Standard For Digital Thermometers

ASTM E2877, Guide for Digital Contact Thermometers

Digital Display with Temperature 27 Deg. C by palomaironique
Image Courtesy of OpenClipArt.org

W. Conshohocken PA, USA — A new ASTM International standard provides a variety of recommendations for the manufacture and selection of digital thermometers. ASTM E2877, Guide for Digital Contact Thermometers, was developed by Subcommittee E20.09 on Digital Contact Thermometers, part of ASTM International Committee E20 on Temperature Measurement.

Included in ASTM E2877 is a set of accuracy classes for digital thermometers. These classes pertain to the temperature interval from -200 °C through 500 °C, an interval important for many thermometry applications.

In order to qualify for a specific accuracy class, a thermometer must measure correctly to within a specified value over this interval or the subinterval in which the thermometer is capable of making measurements.

Digital thermometers that are used for measuring temperature in many laboratories and industrial applications are being increasingly seen as environmentally safe alternatives to mercury-in-glass thermometers, particularly since the U.S. Environmental Protection Agency’s efforts to phase out mercury thermometers are under way.

According to Christopher W. Meyer, a physicist at the National Institute of Standards and Technology, and an E20 member, the petroleum industry and others have used mercury thermometers for decades.

“These industries wish to convert to digital thermometers but until now there has been no ASTM standard for them,” says Meyer. “Also, there has been no set of defined accuracy classes that could help specify the type of thermometer needed for a given application. ASTM E2877 is necessary for instructing these industries in the basics of digital thermometers and for providing a standard that can be used in operation protocols.”

The new standard describes three types of sensors used in digital thermometers: platinum resistance sensors (PRTs or RTDs), thermistors and thermocouples (TCs).

“ASTM E2877 describes the various types of contact digital thermometers that are on the market and discusses the relative characteristics of each,” says Meyer. “It also defines a set of accuracy classes for digital thermometers that may be used to help specify the type of digital thermometer needed for an application. It will allow industries that have previously specified mercury thermometers in their protocols to use digital thermometers.”

All interested parties are invited to join in the standards developing activities of E20.09.

To purchase ASTM standards, visit www.astm.org and search by the standard designation, or contact ASTM Customer Relations (phone: 877-909-ASTM; sales@astm.org). ASTM International welcomes participation in the development of its standards. For more information on becoming an ASTM member, visit www.astm.org/JOIN.

For more news in this sector, visit www.astm.org/sn-consumer or follow ASTM on Twitter @ASTMProductsRec.

ASTM Committee E20 Next Meeting: May 20-21, 2013, May Committee Week, Indianapolis, Ind.

Technical Contact: Christopher W. Meyer, National Institute of Standards and Technology, Gaithersburg, Md., Phone: 301-975-4825; cmeyer@nist.gov

ASTM Staff Contact: Christine DeJong, Phone: 610-832-9736; cdejong@astm.org

ASTM International, formerly known as the American Society for Testing and Materials (ASTM), is a globally recognized leader in the development and delivery of international voluntary consensus standards. Today, some 12,000 ASTM standards are used around the world to improve product quality, enhance safety, facilitate market access and trade, and build consumer confidence.

ASTM’s leadership in international standards development is driven by the contributions of its members: more than 30,000 of the world’s top technical experts and business professionals representing 150 countries. Working in an open and transparent process and using ASTM’s advanced electronic infrastructure, ASTM members deliver the test methods, specifications, guides, and practices that support industries and governments worldwide.
Learn more about ASTM International at www.astm.org/ABOUT/overview.html.

The Pros & Cons of RTDs & Thermocouples – By Jim Pinto

Jim Pinto One useful resource on RTD and Thermocouple sensors was found at Jim Pinto’s Writings section of his website, borrowed from the original article that he wrote for Instruments & Control Magazine in June 2000, at: www.jimpinto.com/writings/tempsensors.html.

In the article Jim takes particular care to describe the likely errors that can occur with less-than-perfect cold junction correction in some electronic thermocouple instruments (i.e. signal conditioners, displays, controllers and transmitters)

He prefaces his remarks by saying:

Resistance temperature detectors and thermocouples can be used for some of the same measurements, but each has strengths and weaknesses that must be carefully matched to the application at hand.

The original version of this article was published in the leading USA magazine – Instruments & Control Systems, June 2000

(Click here for a copy from the I&CS website: http://ics.pennnet.com/home/articles.cfm?ARTICLE_ID=76441&VERSION_NUM=1&Section=Articles).

Jim Pinto is an extraordinary person who has been very active in the ISA – the International Society for Automation, where he is Fellow of the Society. He founded Action Instruments and since about 1998 has shared his thoughts and experiences with the world through various media including, since about 2000, his website, www.JimPinto.com  and his YouTube Channel, online at: www.youtube.com/user/jimpinto?feature=watch.

His personal profile is available on TED.com at: www.ted.com/profiles/3154 (credit for Jim Pinto’s Picture belongs to that page) and on Linkedin at: www.linkedin.com/in/jimpinto1. where many images and video recordings of Jim may be viewed.

Measurement of Temperature Under Various Conditions – Lecture 13

The Fifth Lecture in the 11 Lecture Sub-series on Temperature Measurement.

Also online at youtu.be/PWXhWm3oQ68 and NPTEL at: nptel.iitm.ac.in/video.php?subjectId=112106138.

Lecturers for these videos are Prof. Shunmugam M. S., Department of Mechanical Engineering , IIT Madras.(email: shun@iitm.ac.in) and.Prof. S.P. Venkateshan, Department of Mechanical Engineering , IIT Madras (email: spv@iitm.ac.in).

Numbers after the lecture title indicate the length of the lecture in (hh:mm:ss) format. You can appreciate from the list and times shown, this is about a 50 hour course, equivalent to a substantial opportunity to learn the topics in significant depth.

Lectures in this course: 50

– Syllabus: PDF.

1 – Introduction to the Study of Mechanical Measurement (57:28)
2 – Errors in Measurement (55:15)
3 – Errors in Measurement(Contd..) (58:31)
4 – Propagation of Errors (57:02)
5 – Regression Analysis (56:47)
6 – Regression Analysis (Contd) (55:57)
7 – Design of Experiments (57:29)
8 – Design of Experiments(Contd) (56:52)
9 – Temperature Measurement (56:50)
10 – Overview of Thermometry (57:48)
11 – Thermoelectric Thermometry (57:35)
12 – Thermoelectric Thermometry(Contd) (56:33)
13 – Measurement of Temperature Under Various Conditions (56:35)
14 – Errors in Temperature Measurement (59:07)
15 – Measurement of Transient Temperature and Resistance Thermometry (59:21)
16 – Resistance Thermometry(Contd) (59:47)
17 – Resistance Thermometry(Contd)and pyrometry (59:07)
18 – pyrometry (Contd) (58:50)
19 – pyrometry(Contd) (58:47)
20 – Pressure Measurement(Contd) (59:03)
21 – Pressure Measurement(Contd) (01:00:41)
22 – Pressure Measurement(Contd) (59:41)
23 – Pressure Measurement(Contd) (01:00:08)
24 – Transient Response of Pressure Transducers (59:20)
25 – Transient Response of Pressure Transducers (59:45)
26 – Measurement of High Vacuum (59:33)
27 – Measurement of Fluid Velocity (59:05)
28 – Hot Wire Anemometry and Laser Doppler Velocimetry (59:09)
29 – Laser Doppler Velocimetry and Ultrasonic Methods (57:24)
30 – Measurement of Heat Flux (59:30)
31 – Measurement of Heat Flux(Contd) (59:59)
32 – Transient Method of Heat Flux Measurement (59:37)
33 – Measurement of Volume and Mass Flow Rate of Fluid (59:41)
34 – Flow Measuring Devices (58:17)
35 – Measurement of Stagnation and Bulk Mean Temperature (56:28)
36 – Measurement of Thermo-Physical Properties (01:00:29)
37 – Measurement of Thermal Conductivity (57:51)
38 – Measurement of Heat Capacity and Heating Value (01:00:11)
39 – Measurement of Viscosity (59:17)
40 – Measurement of Viscosity(Contd) (59:03)
41 – Integrating Sphere and Measurement of Emissivity (56:25)
42 – Measurements of Gas Composition (58:03)
43 – Measurements of Gas Composition(Contd) (59:29)
44 – Measurements of Gas Composition and Smoke (58:34)
45 – Measurement of Force (59:00)
46 – Force Measurement (01:00:39)
47 – Vibration and Acceleration Measurement (58:04)
48 – Laser Doppler Accelerometer,Speed,Torque (58:35)
49 – General Issues in Mechanical Measurement (59:52)
50 – Case Studies (01:01:42)

Thermoelectric Thermometry (Continued) – Lecture 12

The Fourth Lecture in the 11 Lecture Sub-series on Temperature Measurement.

Also online at youtu.be/_STPaaaDB8Y and NPTEL at: nptel.iitm.ac.in/video.php?subjectId=112106138.

Lecturers for these videos are Prof. Shunmugam M. S., Department of Mechanical Engineering , IIT Madras.(email: shun@iitm.ac.in) and.Prof. S.P. Venkateshan, Department of Mechanical Engineering , IIT Madras (email: spv@iitm.ac.in).

Numbers after the lecture title indicate the length of the lecture in (hh:mm:ss) format. You can appreciate from the list and times shown, this is about a 50 hour course, equivalent to a substantial opportunity to learn the topics in significant depth.

Lectures in this course: 50

– Syllabus: PDF.