[xls]infrared radiance calculator - · web viewfor contact and non-contact thermometry for...
TRANSCRIPT
evitherm technical WP data Notes & examplesContents (data or service)
associations association, club, institute, organisation, society, websitebasics
data qualification statements
documents book, paper, proceedings, technical note, technical reportequations
equipment suppliers, manufacturers & services
events
frequently asked questions (FAQs)
journals journals on thermal measurement, theory and practicelegal directives, health & safety (e.g. COSHH regulations), legislation
measurement good practice book, paper, website, written standardmeasurement devices - contact thermometrymeasurement methodsmeasurement services services offered by test & calibration labs and NMIsmeasurement services - contact thermometryprediction methods for thermal properties
projects and research
reference materials thermal property reference materialssoftwarestandards (transfer)
standards (written)
terminology and unitstrade organisationstraining training in measurement design, practice, principles
© evitherm 23 March 2004
general introductory information for industry people, not technical experts. UNDER DEVELOPMENT.
information on the issues (purity, heat treatment ...) affecting thermal property data values
key equations, e.g. Wiedemann-Franz for thermal conductivity, Stefan-Boltzmann for emissivityequipment (dilatometer, calorimeter etc.), equipment maintenance & repair, materialsconference, congress, exhibition, meeting, seminar, symposium, workshopWhat is the connection between thermal conductivity and thermal diffusivity?
calculating thermal property data, typically when measured data are not availableEC-funded projects (e.g. evitherm!), national measurement & other R&D programmes and projects
material artefacts used for measurement instrument calibration and testingdocuments with guidelines for ensuring consistent measurement practice
All of the information on this page is for the FREE siteNon-contact thermometry
Title Subject Author(s) Language principles facts issues applications terms equations links NotesBasics (general introductory information) ... the cells in this sheet will have text for the website. CURRENTLY UNDER DEVELOPMENT.
publication date
Industry sector
recommendations
All of the information on this page is for the FREE siteNon-contact thermometryDocuments (book, paper, proceedings, technical note, technical report)
Title Subject Author(s) Publisher ISBN Journal title Vol. No. Pages Date Phone Fax Email Website Country Language Notes
paper blackbody radiation M. Planck 2 237-245 1900 Germany German
book 192 1986 USA English
book Theory and Practice of Radiation Thermometry 1152 1988 USA English
book thermometry 444 2002 USA English
book Temperature, 2nd Edition temperature T. J. Quinn 495 1990 English
book Practical Temperature Measurement thermometry P. R. N. Childs 368 2001 English
book Temperature Measurement , 2nd Edition thermometry 518 2002 English
paper Review of temperature measurement thermometry AIP 71 8 2000 USA English
paper English
paper The 1990 NIST Scales of Thermal Radiometry 95 621 1990 English
www A brief introduction to emissivity Emissivity Ralph Rudolph English
Pamphlet The International Temperature Scale of 1990 thermometry HMSO 25 1991 English
Type of document
Contact name
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
Zur Theorie des Gesetzes der Energieverteilung im Normalspektrum
Verhandlungen der Deutschen Physikalischen Gesellschaft
The fundamental paper in the field of radiation thermometry
Applications of Radiation Thermometry (ASTM STP 895)
radiation thermometry
J. C. Richmond, D. P. Dewitt, eds.
American Society for Testing and
0-8031-0445-6
(610) 832–9585
www.astm.org/cgi-bin/SoftCart.radiation
thermometryD.P. DeWitt, G. D. Nutter, eds.
John Wiley & Sons, New York, NY
0-471-61018-6
www.wiley.com/WileyCDA/Traceable Temperatures: An Introduction to
Temperature Measurement and Calibration, 2nd Edition
J. V. Nicholas, D. R. White
John Wiley & Sons, New York, NY
0-471-49291-4
www.wiley.com/WileyCDA/Academic
Press, London
0-12-569681-7
Elsevier (Butterworth-Heinemann
075065080X
http://books.elsevier.com/uk/
United Kingdom
L. Michalski, K. Eckersdorf, J. Kucharski, J. McGhee
John Wiley & Sons, New York, NY
0-471-86779-9
www.wiley.com/WileyCDA/P. R. N. Childs,
J. R. Greenwood, C. A. Long
Review of Scientific Instruments
2959-2978
http://rsi.aip.org/
Uncertainty budgets for realisation of scales by radiation thermometry
radiation thermometry
J. Fischer, M. Battuello, M. Sadli, M. Ballico, Seung
CCT working document CCT/03-03
http://www.bipm.fr/cc/CCT/Temperature scales
for radiation thermometry
Klaus D. Mielenz, Robert D. Saunders, Albert C. Parr,
Res. Natl. Inst. Stand. Technol.
http://www.temperatureconsultant.ISBN 0 11
480059 6English version of the official French text
All of the information on this page is for the FREE siteNon-contact thermometryEquations
Title Subject Symbol Units Equation Terms Scope Caveat(s) Reference Author(s) Publisher ISBN Vol. No. Pages Website NotesFormat of reference
Journal title
All of the information on this page is for the FREE siteNon-contact thermometryEquipment suppliers, manufacturers & services
Supplier Product / service Contact name Phone Fax Email Website Country Notes
CEDIP Infrared Systems IR imaging systems France 19 bd Bidault 77183 France
FLIR Systems, Inc. IR cameras 18004646372 USA 16 MA 01862 USA
IMPAC Infrared GmbH Germany 32 Krifteler Str. 60326 Germany
Ircon, Inc. Radiation thermometers 847- 967-5151 847-647-0948 [email protected] USA 7300 Niles Illinois 60714 USA
IR technology [email protected] Germany 21 Erding 85435 Germany
Land Instruments International (01246) 417691 Dronfield S18 1DJ
InfraTec GmbH [email protected] Germany 61-63 Dresden 01217 Germany
Raytek GmbH [email protected] Germany 135 Berlin 13127 Germany
Germany 40 Wiesbaden 65205 Germany
Germany 88 München 80993 Germany
EUROTRON manufacturer Italy 409/413 20099 Italy
Chino Works America
Mikron Infrared Inc. USA
VEGA International, Inc. Blackbody sources USA
Thermo Gauge Instruments, Inc. Precision Blackbodies USA
Type of organisation
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
+33 1 60 37 01 00
+33 1 64 11 37 55
http://www.cedip-infrared.com
Croissy Beaubourg
http://www.flirthermography.com
Esquire Road
North Billerica
Instruments for non-contact measurement of temperatures from -100 °C to 4000 °C
+ 49 69 97373-0
+ 49 69 97373-167
http://www.impac-infrared.com
Frankfurt/Main
http://www.ircon.com
N. Natchez Avenue
GORATEC Technology GmbH & Co. KG
+49 8122 88 09 410
+49 8122 88 09 444
http://www.goratec.com/
Otto-Hahn-Str.
Products for infrared temperature measurement, infrared linescanning and
(01246) 410585
http://www.landinst.com/infr/index.html
United Kingdom
United Kingdom
Thermography devices and infrared detectors
+49 351 871-8620
+49 351 871-8727
http://www.infratec.de
Gostritzer Str.
IR, noncontact, industrial temperature measurement instruments
+49 30 478 00 80
+49 30 471 02 51
http://www.raytek.com
Blankenburger Str.
HEITRONICS Infrarot Messtechnik GmbH
IR radiation thermometers and related equipment
+49 61197393-0
+49 61197393-26
[email protected]://www.heitronics.com
Kreuzberger Ring
ebs Automatisierte Thermographie und Systemtechnik GmbH
Distributor of IR thermal imaging and measurement systems
+49 89 140 3446
+49 89 140 3190
http://www.ebs-thermography.com/about/info_e.html
http://www.ebs-thermography.com/
Postfach 50 05 66
Wildermuthstr.
IR radiation thermometers
+39-022488201
+39-022440286
http://www.eurotron.com/
Manufacturer of the IRTec line of industrial online & portable infrared thermometers that include 8 single waveband devices covering the -30 °C to 1600 °C range and ratio infrared (Two Colour) thermometers
EUROTRON Instruments SpA
Viale F.lli Casiraghi
Sesto S. Giovanni (MI)Radiation thermometers
and related equipmenthttp://www.chinoamerica.com/
CHINO Corporation is a manufacture of industrial temperature measurement and control equipment. Instruments include temperature sensors, recorders, infrared pyrometers, controllers and other
Infrared thermometers and blackbody sources
+1 201 405 0900
+1 201 405 0090
[email protected]://www.mikroninst.com
Dr. Sergey A. Ogarev
tel: + 212 629 0290
fax: +1 (212) 643-6918
[email protected] http://www.vegaint.com
Christopher A. Liller
Phone: 304-298-3769
Fax: 304-298-3769
e-mail: [email protected]
http://thermogauge.com
All of the information on this page is for the FREE siteNon-contact thermometryFrequently asked questions
Question Answer Website
food
combustion
Which surfaces behave like a grey body?
ALL
What is emissivity ? ALL
Why emissivity is important ? ALL
ALL
ALL
ALL
What is spectral range? Why is it important? ALL
ALL
How does infrared work? ALL
ALL
ALL
Industry Sector
What should the emissivity setting be when measuring furnace temperature?
The emissivity setting of the IR-thermometer should be 1.00. The furnace can be seen as a blackbody cavity, i.e. the effective emissivity approaches 1.00 due to multiple reflections of thermal radiation inside the furnace. The corrections and errors on the measured surface temperature are small with surrounding surface at similar temperature.
steel, combustion
Can I use a 8 - 14 μm IR-thermometer for surface temperature measurements in a furnace at elevated temperatures?
Normally not. Water vapor along the line of sight will absorb and emit thermal radiation in this spectral range. Use a IR-thermometer that measures at wavelengths outside gas absorption bands, e.g. a 3.9 μm IR-thermometer
Combustion, surface treatment
What is the best way to measure the temperature of food items with an IR-thermometer in a freezing room at -18˚C?
Use a 8 - 14 μm IR-thermometer with emissivity set to 1.00. Using an emissivity setting of 0.95 and the IR-thermometer temperature as a measure of the ambient reflected thermal radiation would lead to large errors despite a surface emissivity close to 0.95. Avoid large temperature changes of the IR-thermometer during measurements, e.g. store the IR-thermometer dry at 5 ˚C rather than in the sun.
Can I measure the gas temperature inside a combustor with good precision using an IR-thermometer?
The reading of IR-thermometers are not affected by the gas flow velocity as for contact sensors and the response time is fast. IR-thermometers looking at radiation from particles or the 4.3 μm hot-band of carbon dioxide can usually be used. Two-colour pyrometers based on emitted radiation from particles require high concentration of particle and long path length, i.e. the gas temperature measurement is influenced by the temperature of the opposite wall with too few particles in the field of view. The IR-thermometer based on radiation from a single band of carbon dioxide works well if the temperature profile along the field of view is flat and with a content of 1-12% carbon dioxide of the fluegas (low carbon dioxide concentration requires long path length) .
In practise none! The emissivity is independent of wavelength for a grey body. The emissivity of all real surfaces changes with wavelength, although some surfaces are close to a grey body. The ideal gray body concept is useful for simplified equations in heat transfer calculations.
all, heat transfer
What is the emissivity of painted metal surfaces and how does it depend on layer thickness?
The emissivity of most diffuse painted surfaces is approximately 0.95 in the spectral range 8 - 14 μm, regardless of the visual colour. The emissivity of painted surfaces usually approaches the emissivity of the paint for a sufficient layer thickness, i.e. usually 2 or 3 thin coats. The emissivity of painted surfaces usually increases with temperature due to broadening of the absorption bands of the chemical components in the paint. A metal surface painted with a thin layer (1 coat) might change emissivity from 0.95 at 500 ˚C to 0.4 at 50 ˚C.
How can I correct the emissivity setting of my IR-thermometer looking through a window?
Three effects must be comsidered: absorption, reflection or scattering of light/thermal radiation. The ideal window has only low reflection losses of light, i.e. the window material has a small refractive index. The best way to compensate for the effect of the window is to calibrate the IR-thermometer with the window in the same geometry and conditions as in the application, e.g. decrease the emissivity setting of the IR-thermometer until the same reading is obtained looking through the window as without the window. Be aware of things becoming fairly complex when the window is hot and absorbs in the spectral range of the IR thermometer.
How does a radiation thermometer work? Radiation thermometers measure the thermal energy emitted by a source and relate this to its temperature by means of the Planck law of radiation. They consist of optics (generally lenses) to collect and focus the emitted energy onto a detector. The signal from the detector can either be measured directly, or it can be converted to a temperature using a system of electronics. Filters are usually used to define the wavelength or wavelength band over which the emitted energy is measured. Many types of radiation thermometer are available for different applications. For measuring high temperatures a thermometer should be chosen that operates at a short wavelength, where the rate of change of emitted radiation with temperature is very high. However, for low temperature applications where the amount of emitted radiation is low, a broad-band device operating at longer wavelengths is required.
http://www.npl.co.uk/thermal/faq_index.html#radiation
All objects at temperatures above absolute zero emit thermal radiation. However, for any particular wavelength and temperature the amount of thermal radiation emitted depends on the emissivity of the object's surface. Emissivity is defined as the ratio of the energy radiated from a material's surface to that radiated from a blackbody (a perfect emitter) at the same temperature and wavelength and under the same viewing conditions. It is a dimensionless number between 0 (for a perfect reflector) and 1 (for a perfect emitter). The emissivity of a surface depends not only on the material but also on the nature of the surface. For example, a clean and polished metal surface will have a low emissivity, whereas a roughened and oxidised metal surface will have a high emissivity. The emissivity also depends on the temperature of the surface as well as wavelength and angle
http://www.npl.co.uk/thermal/faq_index.html#emissivity
Knowledge of surface emissivity is important both for accurate non-contact temperature measurement and for heat transfer calculations. Radiation thermometers detect the thermal radiation emitted by a surface. They are generally calibrated using blackbody reference sources that have an emissivity as close to 1 as makes no practical difference. When viewing 'real' more reflective surfaces, with a lower emissivity, less radiation will be received by the thermometer than from a blackbody at the same temperature and so the surface will appear colder than it is unless the thermometer reading is adjusted to take into account the material surface emissivity. Unfortunately, because the emissivity of a material surface depends on many chemical and physical properties it is often difficult to estimate. It must either be measured or modified in some way, for example by coating the surface with high emissivity black paint, to provide a known emissivity value. The NPL provides a service for measuring the emissivity of samples (for further information see the NPL website) which is used by customers when they need valid surface temperature measurements or heat transfer calculations. For further information visit: http://www.npl.co.uk/thermal/stuff/guide4.html and see the bibliography
http://www.npl.co.uk/thermal/faq_index.html#emissivity
I am using a radiation thermometer to measure the temperature of a sample, but I am getting different results compared to using a thermocouple immersed in the sample. Why?
There are a number of possible reasons for the difference, in addition to possible calibration errors. Firstly, the thermocouple might not be in good thermal contact with the surface of the sample, or there might be temperature gradients within the sample. If this is the case then the thermocouple and radiation thermometer will not be measuring the same temperature. Alternatively, if the emissivity of the sample is low, or not precisely known, the temperature measured by the radiation thermometer will not represent the true temperature of the sample, again leading to differences. Also, if the sample is small, it might not be fully filling the field-of-view of the radiation thermometer, and the radiation thermometer temperature will therefore be low compared to that of the thermocouple
http://www.npl.co.uk/thermal/faq_index.html#sample
What is the maximum distance I can make measurements from the target?
This is a function of the optics in your thermometer. Use the distance-to-size ratio and the diameter of your target to determine the maximum distance you can be from the target. Most IR thermometers have a maximum measuring distance of approximately 100 feet (30 metres), depending on atmospheric conditions.
http://www.coleparmer.com/techinfo/techinfo.asp?htmlfile=IRTherms_faq.
Can I use an anodised aluminium plate or a tungsten ribbon lamp, rather than a blackbody source, to calibrate my radiation thermometer?
A number of factors need to be taken into account when considering sources for calibrating radiation thermometers: Firstly, the calibration source needs to have a high and accurately known emissivity, to ensure that measured temperature will accurately reflect the true temperature of the surface. Secondly, the source needs to be large enough to fill the optical field-of-view of the radiation thermometer, since under-filling the field-of-view will result in measurement errors. Thirdly, the temperature of the source needs to be measured by some means, for example by using a contact sensor inserted close to the radiating surface. A blackbody source with an aperture of a suitable size meets these requirements and should therefore usually be used to calibrate radiation thermometers. The use of an anodised aluminium plate is not generally recommended for checking or calibrating radiation thermometers. Firstly, the emissivity of anodised aluminium is quite low and depends on the thickness of the anodised layer. Many radiation thermometers operate at wavelengths in the infrared, and in this region the emissivity can be anywhere between 0.4 and 0.9. The actual value must be known if measurement errors are to be avoided. Secondly, because the emissivity is low, the radiation measured by the thermometer will be a combination of radiation emitted by the plate and radiation reflected from the plate from other objects in the room. This will, again, lead to potentially significant errors in the reading. Thirdly, there must be some other means, such as a contact probe, for determining the temperature of the plate. If this probe is not in good thermal contact with the
http://www.npl.co.uk/thermal/faq_index.html#sample
The infrared spectral range is 0.7 to 1000 μm, the range for wavelength in which infrared radiation is transmitted. For cost reasons, IR thermometers generally operate under 20 μm. Mnay commercial IR thermometers have a spectral response in the region of 8-20 μm. This range is used because it is minimally affected by CO2 and H2O in the atmosphere. With longer, lower-energy wavelengths, the accuracy decreases with increased distances due to the affects of the atmosphere (humidity).
http://www.coleparmer.com/techinfo/techinfo.asp?htmlfile=IRTherms_faq.htm
How close do I have to be to an object to take its temperature?
Distance does not affect the measurement. However, infrared sensors measure the energy from a circular spot on the target, and the size of that spot is a function of the distance between the sensor and target. The farther away from the target the sensor is, the larger the spot. Consequently, distance is only limited by the size of the object you want to measure.
http://www.raytek-northamerica.com/cat.html?cat_id=1.1
IR thermometers capture the invisible infrared energy naturally emitted from all objects warmer than absolute zero (0 degrees Kelvin). Infrared radiation is part of the electromagnetic spectrum which includes radio waves, microwaves, visible light, ultraviolet, gamma, and X-rays. Any object emits energy somewhere within that range. Infrared falls between the visible light of the spectrum and radio waves. Infrared wavelengths are usually expressed in microns with the infrared spectrum extending from 0.7 microns to 1000 microns. In practice, the 0.7 to 14 micron band is used for IR temperature measurement.
http://www.raytek-northamerica.com/cat.html?cat_id=1.1
Some IR thermometers use lasers. Do they take temperature readings? Are they dangerous?
No on both questions. Lasers are used only for aiming or sighting. The lasers are low voltage units and are not dangerous. Note, however, that all lasers have government regulated labels on them stating power ratings and any necessary safety measures (usually "do not stare into beam").
http://www.raytek-northamerica.com/cat.html?cat_id=1.1
Why can't I see infrared? Human eyes are designed for visible light, but two species are known to detect IR: some rattlesnakes and beetles. Even though IR is not visible to the human eye, your skin can sense IR. When beside a campfire, you can feel the warmth of heat radiated from the fire.
http://www.metrisinst.com/infrared_tutorial.php#what_isI am using a radiation thermometer to
measure the temperature of a sample, but I am getting different results compared to using a thermocouple immersed in the sample. Why?
There are a number of possible reasons for the difference, in addition to possible calibration errors. Firstly, the thermocouple might not be in good thermal contact with the surface of the sample, or there might be temperature gradients within the sample. If this is the case then the thermocouple and radiation thermometer will not be measuring the same temperature. Alternatively, if the emissivity of the sample is low, or not precisely known, the temperature measured by the radiation thermometer will not represent the true temperature of the sample, again leading to differences. Also, if the sample is small, it might not be fully filling the field-of-view of the radiation thermometer, and the radiation thermometer temperature will therefore be low compared to that of the thermocouple
www.npl.co.uk/thermal/faq_index.html
Can I use an anodised aluminium plate or a tungsten ribbon lamp, rather than a blackbody source, to calibrate my radiation thermometer?
A number of factors need to be taken into account when considering sources for calibrating radiation thermometers:Firstly, the calibration source needs to have a high and accurately known emissivity, to ensure that measured temperature will accurately reflect the true temperature of the surface.Secondly, the source needs to be large enough to fill the optical field-of-view of the radiation thermometer, since under-filling the field-of-view will result in measurement errors.Thirdly, the temperature of the source needs to be measured by some means, for example by using a contact sensor inserted close to the radiating surface. A blackbody source with an aperture of a suitable size meets these requirements and should therefore usually be used to calibrate radiation thermometers.The use of an anodised aluminium plate is not generally recommended for checking or calibrating radiation thermometers. Firstly, the emissivity of anodised aluminium is quite low and depends on the thickness of the anodised layer. Many radiation thermometers operate at wavelengths in the infrared, and in this region the emissivity can be anywhere between 0.9 and 0.4. The actual value must be known if measurement errors are to be avoided. Secondly, because the emissivity is low, the radiation
www.npl.co.uk/thermal/faq_index.html
What is a blackbody source and what is it used for?
A blackbody source is an ideal, 'Planckian', radiator, i.e it emits thermal (visible and infrared) energy whose intensity at a given wavelength and temperature is given by the Planck Law of radiation. Blackbody sources, whose temperatures are known or can be measured, are therefore extremely useful standards for the calibration of radiation thermometers.An ideal blackbody source is a completely enclosed cavity held at a uniform temperature. The radiation field inside the cavity depends only on the temperature, and not on any physical property (size, shape, construction material). It completely absorbs and emits all radiation and has an emissivity of 1. For practical purposes, in order to view the radiation field inside the cavity, it is necessary to introduce a hole or aperture. Since this means a departure from the 'ideal' situation it is not possible to have a practical blackbody cavity with an emissivity of 1. However, by careful design cavities can be made with emissivities that closely approach 1.
For more information visit: www.npl.co.uk/thermal/services.html#mstm ) and www.npl.co.uk/thermal/stuff/guide3.html and see the bibliography
How does a radiation thermometer work?
Radiation thermometers measure the thermal energy emitted by a source and relate this to its temperature by means of the Planck law of radiation. They consist of optics (generally lenses) to collect and focus the emitted energy onto a detector. The signal from the detector can either be measured directly, or it can be converted to a temperature using a system of electronics. Filters are usually used to define the wavelength or wavelength band over which the emitted energy is measured.Many types of radiation thermometer are available for different applications. For measuring high temperatures a thermometer should be chosen that operates at a short wavelength, where the rate of change of emitted radiation with temperature is very high. However, for low temperature applications where the amount of emitted radiation is low, a broad-band device operating at longer wavelengths is required.
For more information visit: www.npl.co.uk/thermal/services.html#mstm) and: www.npl.co.uk/thermal/stuff/guide3.html and see the
All of the information on this page is for the FREE siteNon-contact thermometryJournals
Identifier Title Subject Language Publisher Phone Fax Email Website Notes
HTHP English Pion Limited
MST English
Bristol BS1 6BESENSORS SENSORS English Popular, monthly magazine
1 NH 03458 USAMetrologia Metrologia Metrology English BIPM
BIPM 92312 FranceElsevier
infrared physics English Elsevier
English AIP All
Contact name
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
High Temperatures - High Pressures
thermophysical properties research
+44 20 8459 0066
+44 20 8451 6454
[email protected]://www.pion.co.uk/hthp/
Covers the thermophysical properties of gases, liquids, and solids, at all temperatures and under all physical conditions. Authoritative reviews of advances in thermophysics research, new technology applications,
United Kingdom
Measurement Science and Technology
Measurement science and technology
IOPInstitute of Physics Publishing
+44 (0) 117 9297481
+44 (0) 117 9294318
Institute of Physics Publishing Dirac
HouseTemple Back
United Kingdom
All kinds of sensors
Advanstar Communications, Inc.
603-924-5400
603-924-5401
http://www.sensorsmag.com/
Phoenix Mill Lane
Peterborough
J. H. Williams, editor
+33 1 45 07 70 29
+33 1 45 07 70 32
http://www1.bipm.org/en/metrologia/
International journal dealing with the scientific aspects of metrology
Metrologia
Pavillon de Breteuil
Sèvres Cedex
International Journal of Thermal Sciences
http://www.elsevier.fr/html/detrevue.cfm?code=RG2
Infrared Physics & Technologies
http://www.elsevier.com/inca/publications/store/5/2/5/4/3/9/
covers the entire field of infrared physics and technology: theory, experiment, devices and instrumentation
Review of Scientific Instruments
scientific instruments, apparatus and techniques
http://rsi.aip.org/rsi/top.jsp
A montly journal devoted to scientific instruments, apparatus and techniques
All of the information on this page is for the PAY siteNon-contact thermometryLegal (directives, health & safety, legislation)
Identifier Subject Type Date Organisation Phone Fax Email Website Language Country NotesContact name
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
All of the information on this page is for the PAY siteNon-contact thermometryMeasurement good practice (book, paper, website, written standard)
Identifier Title Format Subject Author Date Publisher Phone Fax Email Website Language Notes
VDI/VDE 3511 Blatt 4 1995 VDI/VDE [email protected] Germany
VDI/VDE 3511 Blatt 4.1 2001 VDI/VDE [email protected] Germany
VDI/VDE 3511 Blatt 4.2 2002 VDI/VDE [email protected] Germany
CCT/03-03 paper CCT WG 5 2003 CCT English
book 1988 English
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
Temperature measurement in industry - Radiation thermometry
written standard
Radiation thermometry
http://www.vdi.de/vdi/vrp/richtliniendetai
German & English
Overview of radiation thermometry for application in industry
Temperature measurement in industry - Specification for radiation thermometers
written standard
Radiation thermometry
http://www.vdi.de/vdi/vrp/richtliniendetai
German & English
Specification of parameters charakterising radiation thermometrs
Temperature measurement in industry - Maintenance of the specification for radiation
written standard
Radiation thermometry
http://www.vdi.de/vdi/vrp/richtliniendetai
German & English
Error sources in temperature measurement and how to avoid themMaintenance and regular testing of radiationUncertainty budgets for
realisation of scales by radiation thermometry
Radiation thermometry
http://www.bipm.fr/cc/CCT/Allowed/22/
Discussion of uncertainties in radiation temperature measurement
Theory and Practice of Radiation Thermometry
Radiation thermometry
Edited by D.P. DeWitt and Gene D. Nutter
Wiley Interscience (John Wiley & Sons, Inc)
The veritable "Bible" of non-contact temperatures measurement. If it isn't written here either it's something new or there's a reference to it
All of the information on this page is for the FREE siteNon-contact thermometryMeasurement services - thermal
Type of service Contact name Phone Fax Email Website Country Notes
0.06°C
Calibration of radiation thermometers
0.05 °C
Calibration of blackbody sources
Calibration of tungsten ribbon lamps
Calibration of radiation thermometers Ed Davis 2 Sheffield S4 8BT
Ed Davis 2 Sheffield S4 8BT
Calibration of radiation thermometers Mike Brown Dronfield Sheffield S18 6DJ
Calibration of blackbody sources Mike Brown 3 °C Dronfield Sheffield S18 6DJ
Calibration of radiation thermometers Ekkehard Schreiber Germany 31 Stuttgart 70569 Germany
Calibration of tungsten ribbon lamps Ekkehard Schreiber Germany 31 Stuttgart 70569 Germany
Calibration of ear thermometers Germany 0.05 °C Siemens AG 2 Erlangen 91058 Germany
Calibration of radiation thermometers Germany Siemens AG 2 Erlangen 91058 Germany
Calibration of radiation thermometers Germany 2 Ilmenau 98693 Germany
Calibration of filament pyrometers Germany 2 Ilmenau 98693 Germany
Germany 800 3000 2-12 Abbestr. Berlin 10587 Germany
Germany -60 1000 2-12 Abbestr. Berlin 10587 Germany
France 292 75141 France
Calibration of radiation thermometers Gilbert Brigodiot France BP11 33165 France
Calibration of radiation thermometers Christian Ranson France 29 78197 France
Calibration of blackbody sources Christian Ranson France 29 78197 France
Italy 73 Torino 10135 Italy
Calibration of fixed-point cells Italy 0.05 °C 73 Torino 10135 Italy
Italy 0.2 °C 73 Torino 10135 Italy
Italy 73 Torino 10135 Italy
Calibration of infrared thermometers Italy 73 Torino 10135 Italy
Calibration of visual pyrometers Italy 73 Torino 10135 Italy
Calibration of tungsten ribbon lamps Italy 73 Torino 10135 Italy
Calibration of radiation thermometers [email protected] www.sici.it Italy 6 °C SICI srl 33 23807 Italy
Calibration of radiation thermometers Italy 5 °C 25 VA 21048 Italy
Calibration of infrared thermometers Sønnik Clausen Denmark P.O.49 399 Roskilde 4000 Denmark
Calibration of blackbody sources Sønnik Clausen Denmark P.O.49 399 Roskilde 4000 Denmark
Calibration of ear thermometers Sønnik Clausen Denmark ? P.O.49 399 Roskilde 4000 Denmark
Thua Weckstrom Finland ? 37 Helsinki OO181 Finland
Calibration of infrared thermometers Finland Raahe 92101 Finland
Calibration of radiation thermometers Jan Ivarrson Sweden SP Box 857 Boras 50115 Sweden
Calibration of blackbody sources Jan Ivarrson Sweden SP Box 857 Boras 50115 Sweden
Calibration of tungsten ribbon lamps Jan Ivarrson Sweden ? SP Box 857 Boras 50115 Sweden
Jan Ivarrson Sweden ? SP Box 857 Boras 50115 Sweden
Norway ? 99 Fetveien Kjeller 2007 Norway
Calibration of radiation thermometers Vicente Chimenti Spain ? 2 28760 Spain
Calibration of radiation thermometers D. Jose Luis Lucena Padraza Spain 29 Madrid 1 28042 Spain
Calibration of radiation thermometers Eduarda Filipe / Isabel Loio Portugal 2 Caparica 2829-513 Portugal
Calibration of radiation thermometers Hungary ? 37-39 1124 Hungary
Calibration of radiation thermometers NMI Delft 97 Delft 2628 VK
Calibration of blackbody sources NMI Delft 97 Delft 2628 VK
Calibration of radiation thermometers 5602 BH
Calibration of radiation thermometers Dr Janko Drnovsek Slovenia 25 Ljubljana Slovenia
Calibration of blackbody sources Dr Janko Drnovsek Slovenia 25 Ljubljana Slovenia
Material groups
Material type
Measurement method(s)
T min / °C
T max / °C
Sample geometry (mm)
Atmosphere
Uncertainty
Accreditation
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
Calibration of standard radiation thermometers
Jamie Clark (Customer Services Manager) or Helen McEvoy
+44 20 8943 6444 or +44 20 8943 6183
http://www.npl.co.uk/thermal/services.htmlUnited Kingdom
0.07 °C at 961.78 °C; 0.07
UKAS accredited calibrati
Calibration of standard radiation thermometers operating from 0.65 to 0.9 microns
National Physical Laboratory
Queens Road
Teddington
Middlesex
TW11 0LW
United Kingdom
Calibration of fixed-point cells for radiation thermometry
Jamie Clark (Customer Services Manager) or Helen McEvoy
+44 20 8943 6444 or +44 20 8943 6183
http://www.npl.co.uk/thermal/services.htmlUnited Kingdom
UKAS accredited calibrati
Calibration of Ag, Au and Cu fixed-point cells for radiation thermometry
National Physical Laboratory
Queens Road
Teddington
Middlesex
TW11 0LW
United Kingdom
Jamie Clark (Customer Services Manager) or Helen McEvoy
+44 20 8943 6444 or +44 20 8943 6183
http://www.npl.co.uk/thermal/services.htmlUnited Kingdom
0.2 °C from -40 °C to 200 °C;
UKAS accredited calibrati
Calibration of radiation thermometers from -40 °C to 3000 °C
National Physical Laboratory
Queens Road
Teddington
Middlesex
TW11 0LW
United Kingdom
Calibration of tympanic (ear) thermometers
Jamie Clark (Customer Services Manager) or Helen McEvoy
+44 20 8943 6444 or +44 20 8943 6183
http://www.npl.co.uk/thermal/services.htmlUnited Kingdom
UKAS accredited calibrati
Calibration of tympanic (ear) thermometers from 15 C to 45 °C
National Physical Laboratory
Queens Road
Teddington
Middlesex
TW11 0LW
United Kingdom
Jamie Clark (Customer Services Manager) or Helen McEvoy
+44 20 8943 6444 or +44 20 8943 6183
http://www.npl.co.uk/thermal/services.htmlUnited Kingdom
0.2 °C from -40 °C to 200 °C;
UKAS accredited calibrati
Calibration of blackbody sources from -40 °C to 3000 °C
National Physical Laboratory
Queens Road
Teddington
Middlesex
TW11 0LW
United Kingdom
Jamie Clark (Customer Services Manager) or Helen McEvoy
+44 20 8943 6444 or +44 20 8943 6183
http://www.npl.co.uk/thermal/services.htmlUnited Kingdom
2.0 °C to 1.0 °C from 700 °C
UKAS accredited calibrati
Calibration of evacuated and gas-filled tungsten ribbon lamps from 700 °C to 2300 °C
National Physical Laboratory
Queens Road
Teddington
Middlesex
TW11 0LW
United Kingdom
Calibration of optical (disappearing filament) pyrometers
Jamie Clark (Customer Services Manager) or Helen McEvoy
+44 20 8943 6444 or +44 20 8943 6183
http://www.npl.co.uk/thermal/services.htmlUnited Kingdom
10 °C to 3 °C from 800 °C
UKAS accredited calibrati
Calibration of optical (disappearing filament) pyrometers from 800 °C to 3000 °C
National Physical Laboratory
Queens Road
Teddington
Middlesex
TW11 0LW
United Kingdom
+44 114 244 2521
http://www.controlsdirect.comUnited Kingdom
6 °C from 500 °C to 1200
UKAS accredited calibrati
Calibration of radiation thermometers from 500 °C to 1600 °C
Roxspur Measurement and Control
Downgate Drive
South Yorkshire
United Kingdom
Calibration of (optical) disappearing filament pyrometers
+44 114 244 2521
http://www.controlsdirect.comUnited Kingdom
6 °C from 800 °C to 1100
UKAS accredited calibrati
Calibration of optical (disappearing filament) pyrometers from 800 °C to 2200 °C
Roxspur Measurement and Control
Downgate Drive
South Yorkshire
United Kingdom
+44 1246 417691
http://www.landinst.comUnited Kingdom
1 °C from -10 °C to 1100
UKAS accredited calibrati
Calibration of radiation thermometers from -10 °C to 2500 °C
Land Instruments International
United Kingdom
+44 1246 417691
http://www.landinst.comUnited Kingdom
UKAS accredited calibrati
Calibration of blackbody sources from 20 °C to 1600 °C
Land Instruments International
United Kingdom
+49 711 685 2112
http://www.ike.uni-stuttgart.de 0.8 °C from 800 °C to 1000
DKD accreditation number
Calibration of radiation thermometers from 800 °C to 2600 °C
Institut für Kernenergetik und Energiesyste
Universität Stuttgart
Pfaffenwaldring
+49 711 685 2112
http://www.ike.uni-stuttgart.de 0.8 °C from 800 °C to 1000
DKD accreditation number
Calibration of tungsten ribbon lamps from 800 °C to 2100 °C
Institut für Kernenergetik und Energiesyste
Universität Stuttgart
Pfaffenwaldring
Jens Stuk; e-mail: [email protected]
DKD accreditation number
Calibration of ear thermometers from 35 °C to 45 °C
I & S IS, Bau N
Günter-Scharowsky-StrasseJens Stuk; e-mail:
[email protected] °C from -20 °C to +50 °C;
DKD accreditation number
Calibration of radiation thermometers from -20 °C to 1600 °C
I & S IS, Bau N
Günter-Scharowsky-Strassecalibration-
0.2 °C from 30 °C to 50 °C; 0.4
DKD accreditation number
Calibration of radiation thermometers from 30 °C to 2000 °C
Landesamt für Mess- und Eichwesen
Eichdirektion Ilmenau
Unterpörlitzer Strasse
2.2 °C to 1.7 °C from 800 °C
DKD accreditation number
Calibration of filament pyrometers from 800 °C to 6000 °C
Landesamt für Mess- und Eichwesen
Eichdirektion Ilmenau
Unterpörlitzer Strasse
Calibration of radiation thermometers, tungsten-filament lamps, thermography devices, blackbody radiators with respect to temperature
Dr. Jörg HollandtDr. Jürgen Hartmann
+49 30 3481 369 +49 30 3481 451
+49 30 3481 510
[email protected]@ptb.de
http://www.ptb.de/de/publikationen/_mkm.html 0,28 K to 1,5 K
Physikalisch-Technische Bundesanstalt
Fachbereich 7.3
Calibration of radiation thermometers, thermography devices, blackbody radiators with respect to temperature
Dr. Jörg HollandtDr. Jürgen Hartmann
+49 30 3481 369 +49 30 3481 451
+49 30 3481 510
[email protected]@ptb.de
http://www.ptb.de/de/publikationen/_mkm.html 0,07 K to 0,18 K
Physikalisch-Technische Bundesanstalt
Fachbereich 7.3
http://www.cnam.fr/instituts/inm Institut National de Metrologie
BNM-INM/CNAM
rue Saint-Martin
Paris Cedex 03
+33 5 5657 3471
http://www.launchers.eads.net/home/ 4°C to 7.5 °C from 600 °C
Cofrac accreditation number
Calibration of radiation thermometers from 600 °C to 2300 °C
EADS Space Transportation SA
Avenue du Général Niox
St-Medard-en-Jalles Cedex +33 1 30
http://www.lne.fr 0.4 °C from -20 °C to 150 °C;
Cofrac accreditation number
Calibration of radiation thermometers from -20 °C to 1500 °C
LNE Trappes
avenue Roger Hennequin
Trappes Cedex
+33 1 30 69 1000
http://www.lne.fr 0.5 °C to 0.9 °C from -20 °C
Cofrac accrediation number
Calibration of blackbody sources from -20 °C to 1200 °C
LNE Trappes
avenue Roger Hennequin
Trappes Cedex
Calibration of standard radiation thermometers
http://www.imgc.to.cnr.it from 0.05 °C at 961.78
Calibration of standard radiation thermometers working from 650 nm to 1100 nm in the temperature range
Istituto di Metrologia "G. Colonnetti" -
Strada delle Cacce
http://www.imgc.to.cnr.it Calibration of Ag and Cu fixed-point cells for radiation thermometery
Istituto di Metrologia "G. Colonnetti" -
Strada delle Cacce
Calibration of precision infrared thermometers
http://www.imgc.to.cnr.it Fixed point calibration (from In to Cu) of precision infrared thermometers from 1.6um to 14 um
Istituto di Metrologia "G. Colonnetti" -
Strada delle Cacce
Calibration of monochromatic radiation thermometers
http://www.imgc.to.cnr.it 0.15 % of t (°C)
Calibration of photoelectric monochromatic thermometers from 800 °C to 2100 °C
Istituto di Metrologia "G. Colonnetti" -
Strada delle Cacce
http://www.imgc.to.cnr.it 0.4 °C from -25 °C to 90 °C
Calibration of band and two-color thermometers from -25 °C to 1400 °C
Istituto di Metrologia "G. Colonnetti" -
Strada delle Cacce
http://www.imgc.to.cnr.it 4 °C up to 1000 °C0.3 % of t (°C) above 1000 °C
Calibration of visual pyrometers from 800 °C to 2100 °C
Istituto di Metrologia "G. Colonnetti" -
Strada delle Cacce
http://www.imgc.to.cnr.it 0.1 % of t (°C) for vacuum lamps
Calibration of vacuum and tungsten ribbon lamps from 800 °C to 2100 °C
Istituto di Metrologia "G. Colonnetti" -
Strada delle Cacce
SIT- Calibration Laborat
Calibration of radiation thermometers from 600 °C to 1400 °C
via Campi Merate (LC)
SIT- Calibration Laborat
Calibration of radiation thermometers from 600 °C to 1400 °C
MC METROCONTROL s.r.l.
Via A. Moro
SOLBIATE ARNO
+45 4677 4523
http://www.risoe.dk 0.24°C to 10 °C
Calibration of infrared thermometers from -80 °C to 1600 °C
Risø National Laboratory
Frederiksborgvej
+45 4677 4523
http://www.risoe.dk 0.24 °C to 10 °C
Calibration of blackbody sources from -80 °C to 1600 °C
Risø National Laboratory
Frederiksborgvej
+45 4677 4523
http://www.risoe.dk Calibration of ear thermometers from 35 °C to 45 °C
Risø National Laboratory
Frederiksborgvej
Calibration of infrared thermometers and blackbody sources
+358 9 616 7464
+358 9 616 7467
http://www.mikes.fi Calibration of infrared thermometers and blackbody sources from -50 °C to 1500 °C
Centre for Metrology and Accreditation
PO Box 239
Lonnrotinkatu
+358 8 84911
+358 8 849 126
http://www.rautaruukki.fi 1.7 °C from -10 °C to +200
FINAS accreditation number
Calibration of infrared thermometers from -10 °C to 1500 °C
Rautaruukki Steel Technical Service
P.O. Box 93
+46 33 16 5442
+46 33 135502
http://www.sp.se 1 °C from -20 °C to 1000
SWEDAC accreditation ID
Calibration of radiation thermometers from -20 °C to 2600 °C
+46 33 16 5442
+46 33 135502
http://www.sp.se 1 °C from -20 °C to 1000
SWEDAC accreditation ID
Calibration of blackbody sources from -20 °C to 2600 °C
+46 33 16 5442
+46 33 135502
http://www.sp.se SWEDAC accreditation ID
Calibration of tungsten ribbon lamps from 700 °C to 2600 °C
Calibration of optical (disappearing filament) pyrometers
+46 33 16 5442
+46 33 135502
http://www.sp.se SWEDAC accreditation ID
Calibration of optical (disappearing filament) pyrometers from 700 °C to 2600 °CCalibration of blackbody sources and
radiation thermometers +47 64848484
+47 64848485
http://www.justervesenet.no Calibration of blackbody sources and radiation thermometers from 800 °C to 1700 °C
Justervesenet
+91 807 4714
+91 807 4807
http://www.cem.es Calibration of radiation thermometers from 50 °C to 950 °C
Centro Espanol de Metrologia
Calle de Alfar
Tres Cantos, Madrid
+91 313 8000
+91 313 8090
http://www.sgsgroup.com 4 °C from 50 °C to 400 °C
ENAC accreditation number
Calibration of radiation thermometers from 50 °C to 1100 °C
SGS Tecnos, S. A.
Laboratorio de Calibracion
C/Trespaderne
Ed. Barajas
+351 212 948184
+351 212 948188
http://www.ipq.pt 0.5 °C from 40 °C to 500 °C;
Calibration of radiation thermometers from 40 °C to 2500 °C
Instituto Portugues da Qualidade
Laboratorio de Metrologia
Rua Antonio Giao
+36 1 458 5800
+36 1 355 0598
http://www.omh.hu Calibration of radiation thermometers
National Office of Measures (OMH)
Nemetvolgyi ut
Budapest XII
Rob Zwaan and Adriaan van der Linden
+31 15 269 1587 or +31 15 269 1689
+31 15 269 1727
http://www.nmi.nlThe Netherlands
0.1 °C from -60 °C to +50 °C;
Calibration of radiation thermometers from -60 °C to 3000 °C
Schoemakerstraat
The Netherlands
Rob Zwaan and Adriaan van der Linden
+31 15 269 1587 or +31 15 269 1689
+31 15 269 1727
http://www.nmi.nlThe Netherlands
0.5 °C from -50 °C to +200
Calibration of blackbody sources from -50 °C to 3000 °C
Schoemakerstraat
The Netherlands
+31 40 2675300
+31 40 2675321
http://www.fluke.nlThe Netherlands
0.7 °C from -25 °C to +200
RvA Accreditation number
Calibation of radiation thermometers from -25 °C to +550 C
Fluke Nederland B.V. Standaard
Postbus 1337
Eindhoven
The Netherlands
+386 1 4768 223
+386 1 4264 633
http://www.lmk.fe.uni-lj.si 0.2 °C from 5 °C to 60 °C; 0.3
RvA Accreditation number
Calibration of radiation thermometers from 5 °C to 1500 °C
University of Ljubljana, Faculty of Electrical
Laboratory of Metrology and
Trzaska C.
+386 1 4768 223
+386 1 4264 633
http://www.lmk.fe.uni-lj.si 0.04 °C from -10 °C to +600
RvA Accreditation number
Calibration of blackbody sources from -10 °C to 1500 °C
University of Ljubljana, Faculty of Electrical
Laboratory of Metrology and
Trzaska C.
All of the information on this page is for the PAY siteNon-contact thermometryProjects and Research (EC-funded, national measurement & other R&D programmes and projects)
Organisation Subject Phone Fax Email Website Country Language Notes
EU Teddington Middlesex TW11 0LW
EU Helen McEvoy Teddington Middlesex TW11 0LW
Project Title orResearch Topic
Project identifier
Contact name
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
HIMERT (Novel High temperature Metal carbon Eutectic fixed-points for Radiation thermometry and Thermocouples)
EUROMET 550 / HIMERT
Project to investigate the potential of high temperature metal-carbon
Graham Machin
+44 20 8943 6742
+44 20 8943 6755
Funded by the European Community under the 'Competitive and Sustainable Growth' Programme, Contract number G6RD-CT-2001-
Graham Machin
National Physical Laboratory
Queens Road
United Kingdom
The examination of base parameters for ITS-90 scale realisation in radiation thermometry
EUROMET 658
Radiation thermometry
Tel: +44 20 8943 6183
Fax: +44 20 8943 6755
[email protected] Helen McEvoy
National Physical Laboratory
Queens Road
United Kingdom
All of the information on this page is for the PAY siteNon-contact thermometrySoftware
Identifier Title Format Supplier Contact name Phone Fax Email Website Country Language Free/Pay Notes
IRC Web IRIA Center English free
Product description
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
Infrared Radiance Calculator
Javascript function calculating various quantities
http://www.iriacenter.org/iriaweb.nsf/Planck.js?
All of the information on this page is for the PAY siteNon-contact thermometryStandards (written)
Identifier Subject Title Date Material type Publisher Phone Fax Email Website Language Notes
VDI/VDE 3511 Blatt 4 1995 VDI/VDE Germany
VDI/VDE 3511 Blatt 4.1 2001 VDI/VDE Germany
VDI/VDE 3511 Blatt 4.2 2002 VDI/VDE Germany
ASTM E 344-02 2002 ASTM USA
ASTM E1256-95(2001) 2001 ASTM USA
ASTM E1965-98(2003) 2003 ASTM USA
BS 1794:1952 BSI
BS 1041:Part 5 (1988) 1988 BSI
JIS C 1612
E 1934-99 ASTM
E 1933-99 ASTM
E 1862-97 ASTM
E 1543-00 ASTM
E 1311-99 ASTM
E 1213-97 2002 ASTM
E 639 2002 ASTM
E 307 2002 ASTM
C1153-97(2003)e1 2003 ASTM
BS 1041-5:1989 BSI English UK
JIS C 1612-1988 1994 JIS Japan
Device type
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
Radiation thermometry
Temperature measurement in industry - Radiation thermometry
http://www.vdi.de/vdi/vrp/richtliniendetails/index.php?ID=2756532
GermanEnglish
Overview of radiation thermometry for application in industry
Radiation thermometry
Temperature measurement in industry - Specification for radiation thermometers
http://www.vdi.de/vdi/vrp/richtliniendetails/index.php?ID=9175234
GermanEnglish
Specification of parameters charakterising radiation thermometrs
Radiation thermometry
Temperature measurement in industry - Maintenance of the specification for radiation thermometers
http://www.vdi.de/vdi/vrp/richtliniendetails/index.php?ID=9233138
GermanEnglish
Error sources in temperature measurement and how to avoid them. Maintenance and regular testing of radiation thermometers
Terminology Relating to Thermometry and Hygrometry
http://www.astm.org/cgi-bin/SoftCart.exe/DATABASE.CART/REDLINE_PAGES/E344.htm?U+mystore+tnfz
Standard Test Methods for Radiation Thermometers (Single Waveband Type)
http://www.astm.org/cgi-bin/SoftCart.exe/DATABASE.CART/REDLINE_PAGES/E1256.htm?U+mystore+tnfz5758
Standard Specification for Infrared Thermometers for Intermittent Determination of Patient Temperature
http://www.astm.org/cgi-bin/SoftCart.exe/DATABASE.CART/REDLINE_PAGES/E1965.htm?U+mystore+tnfz5758
Specification for chart ranges for temperature recording instruments
1952 / 1992
http://bsonline.techindex.co.uk/
Temperature-measuring instruments, Recording instruments (measurement), Chart recorders, Working range, Temperature, Standardized parameters
United Kingdom
Guide to selection and use of radiation pyrometers
General Rules for Expression of the Performance of Radiation Thermometers
Japanese Standards Association
Standard Guide for Examining Electrical and Mechanical Equipment with Infrared Thermography
http://www.astm.org/cgi-bin/SoftCart.exe/STORE/filtrexx40.cgi?U+mystore+tnfz5758+-L+E1934NOT:(STATUS:<NEAR/1>:REPLACED)+/usr6/htdocs/astm.org/DATABASE.CART/REDLINE_PAGES/E1934.htm
Standard Test Method for Measuring and Compensating for Emissivity Using Infrared Imaging Radiometers
http://www.astm.org/cgi-bin/SoftCart.exe/STORE/filtrexx40.cgi?U+mystore+tnfz5758+-L+E1933NOT:(STATUS:<NEAR/1>:REPLACED)+/usr6/htdocs/astm.org/DATABASE.CART/REDLINE_PAGES/E1933.htm
Standard Test Method for Measuring and Compensating for Reflected Temperature Using Infrared Imaging Radiometers
Standard Test Method for Noise Equivalent Temperature Difference of Thermal Imaging Systems (NETD)
Standard Test Method for Minimum Detectable Temperature Difference for Thermal Imaging Systems (MDTD)
Standard Test Method for Minimum Resolvable Temperature Difference for Thermal Imaging Systems (MRTD)
Standard Method for Measuring Total-Radiance Temperature of Heated Surfaces Using a Radiation Pyrometer
http://www.astm.org/cgi-bin/SoftCart.exe/STORE/filtrexx40.cgi?U+mystore+tnfz5758+-L+E639NOT:(STATUS:<NEAR/1>:REPLACED)+/usr6/htdocs/astm.org/DATABASE.CART/REDLINE_PAGES/E639.htm
Test Method for Normal Spectral Emittance at Elevated Temperatures
http://www.astm.org/cgi-bin/SoftCart.exe/STORE/filtrexx40.cgi?U+mystore+tnfz5758+-L+E307NOT:(STATUS:<NEAR/1>:REPLACED)+/usr6/htdocs/astm.org/DATABASE.CART/REDLINE_PAGES/E307.htm
Standard Practice for Location of Wet Insulation in Roofing Systems Using Infrared Imaging
http://www.astm.org/cgi-bin/SoftCart.exe/STORE/filtrexx40.cgi?U+mystore+tnfz5758+-L+E639NOT:(STATUS:<NEAR/1>:REPLACED)+/usr6/htdocs/astm.org/DATABASE.CART/REDLINE_PAGES/E639.htm
Guide to selection and use of radiation pyrometers
1989 updated 2000
General rules for expression of the performance of radiation thermometers
English & Japanese
All of the information on this page is for the FREE siteNon-contact thermometryTerminology & units
Term Unit Identifier Title Definition Source Date Website Language Notes
ASTM E 344-02 2002 English USA
Photonics Dictionary English all
English all
Raytek English all
Industry sector
Terminology Relating to Thermometry and Hygrometry
ASTM E 344-02
http://www.astm.org/cgi-bin/SoftCart.exe/DATABASE.CART/REDLINE_PAGES/Laurin
Publishing Co., Inc
http://www.photonics.com/dictionary/XQ/ASP/QX/index.htm
The Photonics Dictionary contains more than 5800 industry-related terms, along with acronyms, abbreviations and illustrations.
ThermoSense - Encyclopedia
ThermoSense -
http://www.thermosense.org/modules.php?name=Encyclopedia
Definitions or Descriptions of Infrared Thermography and Materials Terms
Infrared technological terms
http://www.raytek-europe.com/tools/glossary/view.html?phase=show&id=10117243
All of the information on this page is for the FREE siteNon-contact thermometryTrade organisations
Identifier Title Subject Phone Fax Email Website Country NotesContact name
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
All of the information on this page is for the FREE siteNon-contact thermometryTraining (measurement design, practice, principles)
Identifier Title Date Type Supplier Contact name Phone Fax Email Website Country Language Cost Notes
By arrangement Sonnik Clausen +45 46774523 Denmark English All 399 DK-4000 Denmark
Radiation thermometry By arrangement CNR-IMGC Mauro Battuello Italy All CNR-IMGC 73 Torino 10135 Italy
usually in May EMIT-LAS Italy Italian All EMIT-LAS 10 Milano 20123 Italy
Radiation thermometry (01246) 417691 English All S18 1DJ
June 2005 NIST 301/975-2322 USA English All $ 1600 100 Gaithersburg MD 20899-8441 USA
TBA 2005 NPL Karen Day 44 20 8943 6185 UK English All For contact and non-contact thermometry Karen Day NPL Teddington Middlesex TW11 0LW
Industry sector
Address name 1
Address name 2
Address 1 (no./name)
Address 2 (road/street)
Address 3 (town/city)
Address 4 (county/state)
Address 5 (post/zip code)
Address 6 (country)
Infrared temperature measurement
theory, principles, applications and practice
Risø National Laboratory
+45 46774566
[email protected], Phone: +45 46774523, fax +45 46774565www.risoe.dk Specific training courses on demand of customers. The courses are typical 1 - 2 days and activated on request. The participants are typically encouraged to come up with problems or applications relevant for their work.
Risø National Laboratory
OPL-128, P.O. 49
Frederiksborgvej
Roskilde
principles & practice, measurement design
+39 011 3977338
+39 011 3977347
http://www.imgc.cnr.it
English or Italian
IMGC provides radiation thermometry training courses on demand. Lessons on theoretical aspects of the thermal radiation, ITS-90 realisation and radiation techniques are included. Both lesson and laboratory training are included. Courses in both English or Italian languages may be arranged.
strada delle Cacce
Metrologia industriale - Misure di temperatura
principles & practice, measurement design
Francesco Ballabio
++39 02 8323290 - 58101806
++39 02 8360393
http://www.emit.polimi.it
EMIT-LAS activates, in agreement with IMGC and IEN, regular training courses in Industrial Metrology. A specific module in Temperature Metrology is provided. The courses, both theoretical and with laboratory exercises, are mainly intended to the formation of technicians for calibration laboratories and industry.
piazzale Cantore
principles & practice, measurement design
Land Instruments International
United Kingdom
Land have established a full training facility in the UK which is dedicated to passing on its expertise. The training covers not only infrared technology itself, but also the application of infrared thermometers to a wide range of industries and manufacturing processes. The courses are aimed at end users of infrared radiation thermometers, distributors and re-sellers of
Land Instruments International
Dronfield
United Kingdom
Radiation Thermometry Short Course
lectures and skill-building, problem-solving laboratory experiments
Carol Johnson 301/869-5700
[email protected] <[email protected]>
http://physics.nist.gov/Divisions/Div844/
The course will consist of lectures and skill-building, problem-solving laboratory experiments. The lecture covers the fundamentals of radiometric physics and instrumentation associated with determining temperature from observations of thermal radiation from materials. The exercises will provide experience in performing radiometric analyses to internalize key concepts
NIST Bureau Drive, Stop 8441
Temperature Measurement and Calibration
measurement practice and principles
44 20 8943 6662
[email protected]://www.npl.co.uk/thermal Queens Road
United Kingdom